The Unified Theory of Physics

DingYuChung 1 P.O. Box 180661, Utica, Michigan 48318, USA The unified theory of physics unifies various phenomena in our observableuniverseandotheruniverses.Theunifiedtheoryisbasedonthe zeroenergyuniverseandthespaceobjectstructures.Differentuniversesin different developmental stages are the different expressions of the space objectstructures.Theunifiedtheory isdivided intofiveparts:thespace objectstructures,cosmology,theperiodictableofelementaryparticles,the galaxyformation,andtheextremeforcefield.Thespaceobjectstructures explainquantummechanics,relativity,andtheevolutionoftheuniverses. From the zeroenergy universe, our universe starts with the 11D (dimensional) membrane dual universe followed by the 10D string dual universe and then by the 10D particle dual universe, and ends with the asymmetrical lightdark dual universe. This 4stage process goes on in repetitive cycles. Such 4stage cosmology accounts for the origins of the four force fields. The theoretical calculated percentages of dark energy, darkmatter,andbaryonicmatterare72.8.22.7,and4.53,respectively,in agreement with observed value. According to the calculation, dark energy startedin4.47billionyearsagoinagreementwiththeobserved4.71 ±0.98 billionyearsago.Theunifiedtheoryplacesallelementaryparticlesinthe periodic table of elementary particles with the calculated masses in good agreementwiththeobservedvalues,includingthemassoftheHiggsboson. Itexplainstheinflation,theBigBang,andtheformationofvariousshapes of galaxies. It gives the structure for the extreme force fields, including superconductivity,blackhole,andsupernova.

1electronicmailaddress: [email protected] Contents Introduction 5 1. The Space-Object structures 8 Introduction 8 1.1 TheSpaceStructure 8 1.2 TheObjectStructure 11 1.3 Summary 13 2. Cosmology 14 2.1.TheStrongUniverse 14 2.2.TheGravitationalUniverse 14 2.3.TheChargedUniverse 15 2.4.TheCurrentUniverse 17 2.5.Summary 28 3. The Periodic Table of Elementary Particles 29 3.1.TheCPAsymmetry 29 3.2.TheBosonMassFormula 30 3.3.TheMassCompositesofLeptonsandQuarks 32 3.4.TheLeptonMassFormula 33 3.5.TheQuarkMassFormula 35 3.6.TheLHCHiggsBoson 35 3.7.Summary 39 4. The Galaxy Formation 40 TheSeparationbetweenBaryonicMatterandDarkMatter 40 2.6.TheFormationoftheInhomogeneousStructures 43 2.7.Summary 49 5. Extreme Force Field 51 5.1.Thequantumspacephasetransitionsforforcefields 51 5.2.SuperconductorandtheFractionalQuantumHallEffect 52 5.3.GravastarandSupernova 57 5.4.Summary 58 6. Summary 59 Reference 60

2 1.TheSpaceObjectStructures The Space Structure Higgs Bosons (1) (0) n n combination (1) + (0 ) n n (10) ,(1+ 0) , or (1) (0 ) n n n n The Object Structure 3 , 2 ,1 ,04 11 11 10 4to 10 to 2 2(D−4) E=Mc /α

2.Cosmology zeroenergyuniverse

+11Dmembraneuniverse −11Dantimembraneuniverse

+10Dstringuniverse −10Dantistringuniverse

+10Dparticleuniverse −10Dparticleuniverse

+4D −variable>4D observable +4D −variable>4D hidden universe observable hiddenuniverse universe universe +4Duniversewithdark energyas −4Duniverse +=positiveenergy, −=negativeenergy

3.ThePeriodicTableofElementaryParticles

νe e ν l lepton ντ 9 l10 τ 7 7 8 d= 5 6 7 8 9 10 11 a = 0 1 2 3 4 5 0 1 2

d7 s7 c7 b7 t7 b8 t8 u7 quark u5 d6 3 ′ q9 q10 3 TheLHCHiggsBoson

H(hiddenleptoncondensate) γγ

H(SM) γγ

H(SM) ZZ

H(SM) WW

H(SM) b b

H(SM) ττ

4.TheGalaxyFormation

baryonic thefirst clusterswith cosmic thesecond droplets Big generation merge baryonic generation merge galaxies superclusters matter r galaxies r expansion free baryonic Eruption IGM ICM matter beginnin g pregalactic galaxy cluster

5.ExtremeForceField k ( 1 ) + ∑ (( 0 )( 1 )) 4 m 4 4 n, k extreme condition k = 1  → particle gauge boson field in binary lattice space

k ()()()1 + ∑ 0 1 4 m 4 n,k 4 n,k k = 1 extreme particle extremeboson field in binary partition space

4 Introduction The unified theory of physics is the theory of everything to explain fully cosmology,darkenergy,darkmatter,baryonicmatter,quantummechanics,elementary particles,forcefields,galaxyformation,andunusualextremeforces.Theunifiedtheory ofphysicsisbythemeansofthezeroenergyuniverseandthespaceobjectstructures. Inthezeroenergyuniversehypothesis,thetotalamountofenergyintheuniverse isexactlyzero.Theconventionalzeroenergyuniversehypothesisisbasedonquantum fluctuation and the exact cancellation of positiveenergy matter by negativeenergy gravity through pseudotensor [1] or the inflation [2] before the Big Bang. Quantum fluctuation provides a natural explanation for how that energy may have come out of nothing.Throughouttheuniverse,fromnothing,symmetricalparticlesandantiparticles spontaneouslyformandquicklyannihilateeachotherwithoutviolatingthelawofenergy conservation. Throughout the multiverse, from the zeroenergy universe, symmetrical positiveenergyandnegativeenergyuniversesspontaneouslyformandquicklyannihilate each other. A negative universe becomes a negative energy gravitational field, and a positive energy universe becomes positiveenergy matter as described by Stephen HawkinginABriefHistoryofTime[3]:“Andinasensetheenergyoftheuniverseis constant;itisaconstantwhosevalueiszero.Thepositiveenergyofthematterisexactly balancedbythenegativeenergyofthegravitationalfield.Sotheuniversecanstartoff withzeroenergyandstillcreatematter.” Inthispaper,forouruniverse,thenegativeenergy universeisnotintheformof negativeenergy gravity that cancels outthepositiveenergy matter. The negativeenergy universeiseventuallyintheformofdarkenergythatacceleratesthecosmicexpansion.For ouruniverse,thezeroenergyuniverseproducedsymmetricalpositiveenergyandnegative energy universes, which then underwent a symmetry breaking through the Higgs mechanismtogenerateeventuallyourbaryonicdarkmatteranddarkenergy,respectively. TheHiggsbosoncanbemassremovingtoconvertmassiveparticleintomasslessparticle, ormassgivingtoconvertmasslessparticleintomassiveparticle.Beforeouruniverse,the symmetrical positiveenergy and negativeenergy universes coexisted. All particles were massive, the masses of all particles were equal, and our preuniverse was cold. At the beginningofouruniverse,themassremovingHiggsbosonconvertedmassiveparticlesin the positiveenergy universe into massless particles, resulting in the very hot universe to initiate the Big Bang. The massive particles in the negativeenergy universe remained massive.Afterward,themassgivingHiggsbosonconvertedsomemasslessparticlesinthe positiveenergyuniversebacktomassiveparticles.Thenegativeenergymassiveuniverse eventuallybecomesdarkenergyforthepositiveenergyuniverse. Differentuniversesindifferentdevelopmentalstagesarethedifferentexpressionsof thespaceobjectstructures.Withthezeroenergyuniverseandthespaceobjectstructures, theunifiedtheoryofphysicsistheunifiedtheoryofphysicsasthetheoryofeverythingto explain fully cosmology, dark energy, dark matter, baryonic matter, quantum mechanics, elementary particles, force fields, galaxy formation, and unusual extreme forces. The unifiedtheoryisdividedintofiveparts:(1)thespaceobjectstructures,(2)cosmology,(3) the periodic table of elementary particles, (4) the galaxy formation, and (5) the extreme forcefield.

5 Chapter1dealswiththespaceobjectstructuresintheunifiedtheory.Theunified theory of physics is derived from the spaceobject structures. Different universes in differentdevelopmentalstagesarethedifferentexpressionsofthespaceobjectstructures. Relatingtorestmass,attachmentspaceattachestoobjectpermanentlywithzerospeed. Relatingtokineticenergy,detachmentspacedetachesfromtheobjectatthespeedof light.Inourobservableuniverse,thespacestructureconsistsofthreedifferentcombinations ofattachmentspaceanddetachmentspace,describingthreedifferentphenomena:quantum mechanics,specialrelativity,andtheextremeforcefields.Theobjectstructureconsistsof 11Dmembrane(3 11 ),10Dstring(2 10 ),variableDparticle(1 ≤10 ),andemptyobject(0). Thetransformationamongtheobjectsisthroughthedimensionaloscillationthatinvolves theoscillationbetweenhighdimensionalspacetimewithhighvacuumenergyandlow dimensional spacetime with low vacuum energy. Our observable universe with 4D spacetimehaszerovacuumenergy. Chapter 2 deals with cosmology. There are three stages of preuniverses in chronological order: the strong preuniverse, the gravitational preuniverse, and the chargedpreuniverse.Thefirstuniversefromthezeroenergyuniverseinmultiverseis thestrongpreuniversewiththesimplestexpressionofthespaceobject structures. Its object structure is 11D positive and negative membrane and its space structure is attachment space only. The only force is the prestrong force without gravity. The transformationfrom11Dmembraneto10Dstringresultsinthegravitationalpreuniverse withbothprestrongforceandpregravity.Therepulsivepregravityandpreantigravity bringsaboutthedual10Dstringuniversewiththebulkspace.Thecoalescenceandthe separationofthedualuniverseresultinthedualchargeduniverseasdual10Dparticle universe with the prestrong, pregravity, and preelectromagnetic force fields. The asymmetrical dimensional oscillations and the asymmetrical addition of detachment spaceresultintheasymmetricaldualuniverse:thepositiveenergy4Dlightuniversewith light and kinetic energy and the negativeenergy oscillating 10D4D dark universe withoutlightandkineticenergy.Thelightuniverseisourobservableuniverse.Thedark universe is sometimes hidden, and is sometimes observable as dark energy. The dimensional oscillation for the dark universe is the slow dimensional oscillation from 10Dand4D.Thedimensionaloscillationforthelightuniverseinvolvestheimmediate transformationfrom10Dto4Dandtheintroduction ofdetachmentspace, resultingin lightandkineticenergy.Theasymmetricaldimensionaloscillationandtheasymmetrical additionofdetachmentspacearemanifestedastheasymmetricalweakforcefield.When thedarkuniversebecomesthe4Duniverse,thedarkuniverseturnsintodarkenergy. Chapter3dealswiththeperiodictableofelementaryparticles.Forbaryonicmatter, theincorporationofdetachmentspaceforbaryonicmatterbringsabout“thedimensional orbitals”asthebasefortheperiodictableofelementaryparticlesforallleptons,quarks, andgaugebosons.Themassesofgaugebosons,leptons,quarkscanbecalculatedusing only four known constants: the number of the extra spatial dimensions in the eleven dimensionalmembrane,themassofelectron,themassofZ°,andthefinestructureconstant. Thecalculatedvaluesareingoodagreementwiththeobservedvalues.Thedifferencesin dimensionalorbitalsresultinincompatibledarkmatterandbaryonicmatter.Theobserved newLHCHiggsBosonconsistsoftheSM(StandardModel)Higgsbosonandthehidden leptoncondensatethatisintheforbiddenleptonfamilyoutsideofthestandardthreelepton familiesintheStandardModel.Beingforbidden,asinglehiddenleptoncannotexistalone,

6 sothehiddenleptonsmustexistintheleptoncondensateasthecompositeoftheleptons antileptons as ’, ’, ’+, and ’ . The decay of the hidden lepton condensate into diphotonaccountsfortheobservedexcessdiphotondeviatedfromtheStandardModel. OtherdecaymodesoftheLHCHiggsbosonfollowtheStandardModel.Thecalculated massesofthehiddenleptonsof ’± and ’,are120.7GeVand136.9GeV,respectively, withtheaverageas128.8GeVforthehiddenleptoncondensateingoodagreementswith theobserved125or126GeV.TheLHCHiggsbosonacquiresthemassofthehiddenlepton condensate. Chapter 4 deals with the formation of galaxies. The separation of dark matter without electromagnetism and baryonic matter with electromagnetism involves MOND (modifiedNewtoniandynamics).ItisproposedthattheMONDforceisintheinterface betweenthebaryonicmatterregionandthedarkmatterregion.Intheinterface,thesame matter materials attract as the conventional attractive MOND force, and the different mattermaterialsrepulseastherepulsiveMONDforcebetweenbaryonicmatteranddark matter. The source of the repulsive MOND force fieldistheincompatibilitybetween baryonicmatteranddarkmatter,likewaterandoil.Theincompatibilitydoesnotallow the direct detection of dark matter. Typically, dark matter halo surrounds baryonic galaxy.TherepulsiveMONDforcebetweenbaryonicmatteranddarkmatterenhances the attractive MOND force of baryonic matter in the interface toward the center of gravityofbaryonicmatter.Theenhancementofthelowaccelerationintheinterfaceis bytheaccelerationconstant,a 0,whichdefinestheborderoftheinterfaceandthefactorof theenhancement.Theenhancementofthelowgravityintheinterfaceisbythedecrease ofgravitywiththedistantratherthanthesquareofdistanceasinthenormalNewtonian gravity.TherepulsiveMONDforceisthedifference between the attractive MOND forceandthenonexistinginterfacialNewtonianforce.TherepulsiveMONDforcefield resultsintheseparationandtherepulsiveforcebetweenbaryonicmatteranddarkmatter. TherepulsiveMONDforcefieldexplainstheevolutionoftheinhomogeneousbaryonic structuresintheuniverse. Bothbaryonicmatterand dark matter are compatible with cosmicradiation,sointheearlyuniverse,theincompatibilitybetweenbaryonicmatter anddarkmatterincreaseswithdecreasingcosmicradiationandtheincreasingageofthe universeuntilreachingthemaximumincompatibility.Thefivestagesoftheformationof inhomogeneousstructuresarefreebaryonicmatter,baryonicdroplets,thefirstgeneration galaxiesbytheBigEruption,cluster,andsupercluster. Chapter5dealswiththeextremeforcefield.Underextremeconditions,suchas thezerotemperatureandextremelyhighpressuretemperature,theextremeforcefieldsas extremebosonforcefieldsform.Theformationoftheextrememolecule(theCooperpair) and the extreme lattice provides the mechanism for the phase transition to superconductivity, while the formation of extreme atom with electronextreme boson providesthemechanismforthephasetransitionto the fractional quantum Hall effect. Theformationofthestellarextremeforcefieldinacollapsingstarpreventssingularityas inblackhole, resulting intheformationof gravastar without singularity and with the leptonpairsstellarextremeforcefieldcore.

7 1. The Space-Object Structures

Theunifiedtheoryofphysicsunifiesvariousphenomenainourobservableuniverse and other universes. The unified theory of physics is derived from the spaceobject structures[4][5].Alluniversesaregovernedbythespaceobjectstructures.Different universesarethedifferentexpressionsofthespaceobjectstructures. 1.1. The Space Structure The space structure [6] [7] consists of attachment space (denoted as 1) and detachmentspace(denotedas0).Attachmentspaceattachestoobjectpermanentlywith zerospeed.Detachmentspacedetachesfromtheobjectatthespeedoflight.Attachment spacerelatestorestmass,whiledetachmentspacerelatestokineticenergy.Differentstages ofouruniversehavedifferentspacestructures. Thetransformationbetweenmass(massiveparticle)inattachmentspaceandkinetic energy (massless particle) in detachment space is through the scalar Higgs boson. For example,massiveparticleswithnunitsofattachmentspace,denotedas(1) n,areconverted into massless particles with n units of detachment space, denoted as (0) n through the Higgsbosons. Higgs Bosons massive particles in )1( n ← → massless particles in )0( n (1) TheHiggsbosoncanbemassremovingtoconvertmassiveparticleintomassless particle,ormassgivingtoconvertmasslessparticleintomassiveparticle.TheHiggsboson itself is the scalar gauge boson with zero massenergy. The virtual Higgs boson is a propertyofspacethatcanturnonthetransformationbetweenthemassiveparticle(mass potentialenergy)andmasslessparticle(kineticenergy).Afterthetransformation,theHiggs boson remains dormant. With zero massenergy, the Higgs boson avoids the severe problem of the huge energy (cosmological constant) from the gravityHiggs boson interaction.TheobservedHiggsbosonattheLHCisaremnantoftheHiggsboson,notthe Higgsbosonitselfasdescribedlater. Our universe has both attachment space and detachment space. Before our observableuniverse,allparticlesweremassive,themassesofallparticleswereequal,and ourpreuniversewascold.Atthebeginningofourobservableuniverse,themassremoving Higgsbosonconvertedmassiveparticlesintomasslessparticles,resultingintheveryhot universetoinitiatetheBigBang.Afterward,themassgivingHiggsbosonconvertedsome masslessparticlesbacktomassiveparticles. The combination of attachment space (1) and detachment space (0) brings about three different space structures: miscible space, binary partition space, and binary lattice spaceforfourdimensionalspacetimeasbelow. combination )1( attachment space + )0( det achment space  → n n (2) 1( )0 binary lattice space 1(, + )0 miscible space, or )1( )0( binary partition space n n n n

8 Binarylatticespace,(10) n,consistsofrepetitiveunitsofalternativeattachment spaceanddetachmentspace.Thus,binarylatticespaceconsistsofmultiplequantized unitsofattachmentspaceseparatedfromoneanotherbydetachmentspace.Inmiscible space,attachmentspaceismiscibletodetachmentspace,andthereisnoseparationof attachmentspaceanddetachmentspace.Binarypartitionspace,(1) n(0) n,consistsof separatedcontinuousphasesofattachmentspaceanddetachmentspace. Binarylatticespaceconsistsofmultiplequantizedunitsofattachmentspace separatedfromoneanotherbydetachmentspace.Anobjectexistsinmultiplequantum statesseparatedfromoneanotherbydetachmentspace.Binarylatticespaceisthespace forwavefunction.Inwavefunction, n Ψ = ∑ c φ , (3) i i i =1

Eachindividualbasiselement, φi〉,attachestoattachmentspace,andseparatesfromthe adjacent basis element by detachment space. Detachment space detaches from object. Binarylatticespacewithnunitsoffourdimensional,(01) n,containsnunitsofbasis elements. Neither attachment space nor detachment space is zero in binary lattice space. The measurement in the uncertainty principle in quantum mechanics is essentially the measurement of attachment space and momentum in binary lattice space: large momentumhassmallnonzeroattachmentspace,whilelargeattachmentspacehaslow nonzeromomentum.Inbinarylatticespace,anentityisbothinconstantmotionsas wave for detachment space and in stationary state as a particle for attachment space, resultinginthewaveparticleduality. Detachment space contains no object that carries information. Without information, detachment space is outside of the realm of causality. Without causality, distance(space)andtimedonotmattertodetachmentspace,resultinginnonlocalizable and noncountable spacetime. The requirement for the system (binary lattice space) containing nonlocalizable and noncountable detachment space is the absence of net informationbyanychangeinthespacetimeofdetachmentspace.Allchangeshaveto becoordinatedtoresultinzeronetinformation.Thiscoordinatednonlocalizedbinary latticespace correspondstonilpotentspace.Allchanges in energy, momentum, mass, time,spacehavetoresultinzeroasdefinedbythegeneralizednilpotentDiracequation byB.M.DiazandP.Rowlands[8]. (mk∂ / ∂t ± i∇ + jm () ±ikE ± ip + jm)expi( − Et +p.r) =0 , (4) where E, p,m,tand rarerespectivelyenergy,momentum,mass,time,space and the symbols±1,± i ,± i,± j,± k,± i,± j,± k,areusedtorepresenttherespectiveunits required by the scalar, pseudoscalar, quaternion and multivariate vector groups. The changes involve the sequential iterative path from nothing (nilpotent) through conjugation,complexification,anddimensionalization.Thenonlocalpropertyofbinary latticespaceforwavefunctionprovidestheviolationofBellinequalities[9]inquantum

9 mechanics in terms of fasterthanlight influence and indefinite property before measurement.ThenonlocalityinBellinequalitiesdoesnotresultinnetnewinformation. In binary lattice space, for every detachment space, there is its corresponding adjacentattachmentspace.Thus,nopartoftheobjectcanbeirreversiblyseparatedfrom binarylatticespace,andnopartofadifferentobjectcanbeincorporatedinbinarylattice space.Binarylatticespacerepresentscoherenceaswavefunction.Binarylatticespaceis for coherent system. Any destruction of the coherence by the addition of a different objecttotheobjectcausesthecollapseofbinarylatticespaceintomisciblespace.The collapseisaphasetransitionfrombinarylatticespacetomisciblespace. collapse (( 0) ( 1 ))n (0 +1 )n  → (5) binary lattice space miscible space Another way to convert binary lattice space into miscible space is gravity. Penrose[10]pointedoutthatthegravityofasmallobjectisnotstrongenoughtopull differentstatesintoonelocation.Ontheotherhand,the gravityoflargeobjectpulls differentquantumstatesintoonelocationtobecomemisciblespace.Therefore,asmall objectwithoutoutsideinterferenceisalwaysinbinarylatticespace,whilealargeobject isneverinbinarylatticespace. The information in miscible space is contributed by the combination of both attachmentspaceanddetachmentspace,soinformationcannolongerbenonlocalize. Anyvalueinmisciblespaceisdefinite.Allobservationsintermsofmeasurementsbring aboutthecollapseofwavefunction,resultinginmisciblespacethatleadstoeigenvalueas definitequantizedvalue.Suchcollapsecorrespondstotheappearanceofeigenvalue,E, byameasurementoperator,H,onawavefunction, Ψ. H Ψ = E Ψ , (6) Inmisciblespace,attachmentspaceismiscibletodetachmentspace,andthereis noseparationofattachmentspaceanddetachmentspace. In miscible space, attachment space contributes zero speed, while detachment space contributes the speed of light. A masslessparticle,suchasphoton,isondetachmentspacecontinuously,anddetachesfrom itsownspacecontinuously.Foramovingmassiveparticleconsistingofarestmassivepart and a massless part, themassive part with restmass, m0,is in attachmentspace, andthe massless part with kinetic energy, K, is in detachment space. The combination of the massivepartinattachmentspaceandmasslesspartindetachmentleadstothepropagation speedinbetweenzeroandthespeedoflight. Tomaintainthespeedoflightconstantforamovingparticle,thetime(t)inmoving particlehastobedilated,andthelength(L)hastobecontractedrelativetotherestframe. t = =t 1−υ 2 / c2 = t γ , 0 0

L = L0 / γ , (7) E = K + m c2 =γ m c2 0 0

10 where γ = /1 1−υ 2 / c2 istheLorentzfactorfortimedilationandlengthcontraction, Eis thetotalenergyand Kisthekineticenergy. Binary partition space, (1) n(0) n, consists of separated continuous phases of attachment space and detachment space. It is for extreme force fields under extreme conditionssuchasneartheabsolutezerotemperatureorextremelyhighpressure.Itwill be discussed later to explain extreme phenomena such as superconductivity and black hole. 1.2. The Object Structure Thesecondpartofthephysicalstructuresisthe object structure. The object structureconsistsof11Dmembrane(3 11 ),10Dstring(2 10 ),variableDparticle(1 4to10 ), andemptyobject(0 4to11 ).Differentuniversesanddifferentstagesofauniversecanhave different expressions of the object structure. For an example, the four stages in the evolutionofouruniversearethe11Dmembraneuniverse(thestronguniverse),thedual 10Dstringuniverse(thegravitationalpreuniverse),thedual10Dparticleuniverse(the charged preuniverse), and the dual 4D/variable D particle universe (the current universe). Thetransformationamongtheobjectsisthroughthedimensionaloscillation[5] thatinvolvestheoscillationbetweenhighdimensionalspacetimeandlowdimensional spacetime.ThevacuumenergyofthemultiversebackgroundisaboutthePlanckenergy. Vacuumenergydecreaseswithdecreasingdimensionnumber.Thevacuumenergyof4D spacetime is zero. With such vacuum energy differences, the local dimensional oscillation between high and low spacetime dimensions results in local eternal expansioncontraction[11].Eternalexpansioncontractionislikeharmonicoscillator, oscillatingbetweenthePlanckvacuumenergyandthelowervacuumenergy. Forthedimensionaloscillation,contractionoccursattheendofexpansion.Each localregionintheuniversefollowsaparticularpathofthedimensionaloscillation.Each pathismarkedbyparticularsetofforcefields.Thepathforouruniverseismarkedby thestrongforce,gravityantigravity,chargedelectromagnetism,andasymmetricalweak force,correspondingtothefourstagesofthecosmicevolution. The vacuum energy differences among spacetime dimensionsarebasedonthe varyingspeedoflight.Varyingspeedoflighthasbeenproposedtoexplainthehorizon problemofcosmology[12][13].Theproposalisthatlighttraveledmuchfasterinthe distant past to allow distant regions of the expanding universe to interact since the beginning of the universe. Therefore, it was proposed as an alternative to cosmic inflation.J.D.Barrow[14]proposesthatthetimedependentspeedoflightvariesas somepoweroftheexpansionscalefactor ainsuchwaythat n c(t) = c0 a (8)

wherec0 > 0and nareconstants.Theincreaseofspeedoflightiscontinuous. In this paper, varying dimension number (VDN) relates to quantized varying speed of light (QVSL), where the speed of light is invariant in a constant spacetime

11 dimension number, and the speed of light varies with varying spacetime dimension numberfrom4to11. D − 4 cD = c /α , (9) where c isthe observedspeed of lightinthe4Dspacetime, cD isthequantizedvarying speedoflightinspacetimedimensionnumber,D,from4to11,and α isthefinestructure constantforelectromagnetism.Eachdimensionalspacetimehasaspecificspeedoflight. (Sincefromthebeginningofourobservableuniverse,thespacetimedimensionhasalways beenfour,thereisnoobservablevaryingspeedoflightinourobservableuniverse.)The speedoflightincreaseswiththeincreasingspacetimedimensionnumberD. 2 Inspecialrelativity, E = M 0 c modifiedbyEq.(9)isexpressedas 2 2 (D − )4 E = M 0 ⋅(c /α ) (10a) 2 ( d − )4 2 = (M 0 /α ) ⋅c . (10b) Eq. (10a) means that a particle in the D dimensional spacetime can have the superluminalspeed c /α D−4 ,whichishigherthantheobservedspeedoflightc,andhasthe rest mass M 0 . Eq. (10b) means that the same particle in the 4D spacetime with the d(2 − )4 observedspeedoflightacquires M 0 /α astherestmass,whered=D.DinEq.(10a) isthespacetimedimensionnumberdefiningthevaryingspeedoflight.InEq.(10b),dfrom 4to11is“massdimensionnumber”definingvaryingmass.Forexample,forD=11,Eq. (10a)showsasuperluminalparticleinelevendimensionalspacetime,whileEq.(10b) showsthatthespeedoflightofthesameparticleistheobservedspeedoflightwiththe 4Dspacetime,andthemassdimensioniseleven.Inotherwords,11D spacetime can transforminto4Dspacetimewith11dmassdimension.11D4dinEq. (10a)becomes 4D11d in Eq. (10b) through QVSL. QVSL in terms of varying spacetime dimension number,D,bringsaboutvaryingmassintermsofvaryingmassdimensionnumber,d. TheQVSLtransformationtransformsbothspacetimedimensionnumberandmass dimensionnumber.IntheQVSLtransformation,thedecreaseinthespeedoflightleadsto the decrease in spacetime dimension number and the increase of mass in terms of increasingmassdimensionnumberfrom4to11, 2 n cD = cD − n /α , (11a) 2 n M ,0 D d, = M ,0 D − n, d + nα , (11b) QVSL ,D d  →(D m n), d( ± n ) (11c) where D isthe spacetime dimensionnumber from 4 to 11 anddisthemassdimension numberfrom4to11.Forexample,intheQVSLtransformation,aparticlewith11D4dis transformedtoaparticlewith4D11d.Intermsofrestmass,11Dspacetimehas4dwiththe lowestrestmass,and4Dspacetimehas11dwiththehighestrestmass. Restmassdecreaseswithincreasingspacetimedimensionnumber.Thedecrease in rest mass means the increase in vacuum energy, so vacuum energy increases with

12 increasing spacetime dimension number. The vacuum energy of 4D particle is zero, while11DmembranehasthePlanckvacuumenergy. Sincethespeedoflightfor>4Dparticleisgreaterthanthespeedoflightfor4D particle,theobservationof>4Dparticlesby4Dparticlesviolatescasualty.Thus,>4D particlesarehiddenparticleswithrespectto4Dparticles.Particleswithdifferentspace time dimensions are transparent and oblivious to one another, and separate from one anotherifpossible. 1.3. Summary Theunifiedtheoryofphysicsisderivedfromthespaceobjectstructures.Different universesindifferentdevelopmentalstagesarethedifferentexpressionsofthespaceobject structures.Relatingtorestmass,attachmentspaceattachestoobjectpermanentlywith zerospeed.Relatingtokineticenergy,detachmentspacedetachesfromtheobjectatthe speed of light. In our observable universe, the space structure consists of three different combinations of attachment space and detachment space, describing three different phenomena:quantummechanics,specialrelativity,andtheextremeforcefields.Theobject structureconsistsof11Dmembrane(3 11 ),10Dstring(2 10 ),variableDparticle(1 ≤10 ),and empty object (0). The transformation among the objects is through the dimensional oscillationthatinvolvestheoscillationbetweenhighdimensionalspacetimewithhigh vacuum energy and low dimensional spacetime with low vacuum energy. Our observableuniversewith4Dspacetimehaszerovacuumenergy.

13 2. Cosmology

Before the current universe, the preuniverse is in the three different stages in chronologicalorder:thestrongpreuniverse,thegravitationalpreuniverse,andthecharged preuniverse. The strong preuniverse has only one force: the strong force. The gravitational preuniverse has two forces: the strong and the gravitational forces. The chargedpreuniversehasthreeforces:thestrong,thegravitational,andtheelectromagnetic forces.Allthreeforcesinthepreuniversesareintheirprimitiveformsunlikethefinished forms in our observable universe. The asymmetrical weak interaction comes from the formation of the current asymmetrical dual universe. Such 4stage cosmology for our universeexplainstheoriginofthefourforcefieldsinourobservableuniverse. 2.1. The Strong Pre-Universe

Dualuniverse Objectstructure Spacestructure Force dual 11Dmembrane attachmentspace prestrong Themultiversestartswiththezeroenergyuniverse,whichproducesthepositive energy11D(spacetimedimensional)membraneuniverseandthenegativeenergy11D membraneuniversedenotedas3 11 3 11 ,asproposedbyMongan[15].Theonlyforce amongthemembranesistheprestrongforce,s,asthepredecessorofthestrongforce.It isfromthequantizedvibrationofthemembranestogeneratethereversibleprocessofthe absorptionemission of the particles among the membranes. The prestrong force mediatesthereversibleabsorptionemissionintheflatspace.Theprestrongforceisthe sameforallmembranes,soitisnotdefinedbypositiveornegativesign.Itdoesnothave gravity that causes instability and singularity [16 ], so the initial universe remains homogeneous, flat, and static. This initial universe provides the globally stable static backgroundstateforaninhomogeneouseternaluniverseinwhichlocalregionsundergo expansioncontraction[16]. 2.2.The Gravitational Pre-Universe

Dualuniverse Objectstructure Spacestructure Forces dual 10Dstring attachmentspace prestrong,pregravity Incertainregionsofthe11Dmembraneuniverse,thelocalexpansiontakesplace bythetransformationfrom11Dmembraneinto10Dstring.Theexpansionistheresult of the vacuum energy difference between 11D membrane and 10D string. With the emergenceofemptyobject(0 11 ),11Dmembranetransformsinto10Dstringwarpedwith virtueparticleaspregravity. + 311 s + 011 ← → 210 s11 = 210 s g (12) where3 11 isthe11Dmembrane,sistheprestrongforce,0 11 isthe11Demptyobject,2 10 is 10D string, 1 1 is one dimensional virtue particle as g, pregravity. Empty object

14 correspondstotheantiDeSitterbulkspaceintheRandallSundrummodel[17].Inthe sameway,thesurroundingobjectcanextendintoemptyobjectbythedecompositionof space dimension as described by Bounias and Krasnoholovets [18], equivalent to the RandallSundrum model. The g is in the bulk space, which is the warped space (transverseradialspace)around2 10 .AsintheAdS/CFTduality[19][20][21],thepre strongforcehas10Ddimension,onedimensionlowerthanthe11Dmembrane,andisthe conformalforcedefinedontheconformalboundaryofthebulkspace.Theprestrong forcemediatesthereversibleabsorptionemissionprocessofmembrane(string)unitsin the flat space, while pregravity mediates the reversible condensationdecomposition processofmassenergyinthebulkspace.

Throughsymmetry,antistringsform10Dantibraneswithantipregravityas 2−10 g ,whereg isantipregravity. − 3−11 s + 0 −11 ← → 2 −10 s 1−1 = 2 −10 s g (13) Pregravity can be attractive or repulsive to antipregravity. If it is attractive, the universeremainshomogeneous.Ifitisrepulsive,nunitsof(2 10 )nandnunitsof(2 10 )nare separatedfromeachother. + − (( s 2 ) g ) ( g ( s 2 )) (14) 10 n −10 n Thedual10Dstringuniverseconsistsoftwoparalleluniverseswithoppositeenergies:10D stringswithpositiveenergyand10Dantistringswithnegativeenergy.Thetwouniverses areseparatedbythebulkspace,consistingofpregravityandantipregravity.Therearefour equal regions: positive energy string universe,pregravity bulk space, antipregravity bulk space,andnegativeenergyantistringuniverse.Suchdualuniverseseparatedbybulkspace appearsintheekpyroticuniversemodel[22][23]. 2.3. The Charged Pre-Universe

Dualuniverse Objectstructure Spacestructure Forces dual 10Dparticle attachmentspace prestrong,pregravity,pre electromagnetic

Whenthelocalexpansionstops,throughthedimensionaloscillation,the10Ddual universe returns to the 11D positive and negative universes, which coalesce to undergo annihilation and to return to the zeroenergy universe. The 10D positive and negative universecanalsocoalescetoundergoannihilationandtoreturntothezeroenergyuniverse. Thefirstpathofsuchcoalescenceistheannihilation,resultingindisappearanceofthedual universeandthereturntothezeroenergyuniverse. Thesecondpathallowsthecontinuationofthedual universe in another form without the mixing of positive energy and negative energy. Such dual universe is possiblebytheemergenceoftheprechargeforce,thepredecessorofelectromagnetism withpositiveandnegativecharges.Themixingbecomesthemixingofpositivechargeand negativechargeinsteadofpositiveenergyandnegativeenergy,resultinginthepreservation

15 ofthedualuniversewiththepositiveenergyandthenegativeenergy.Ouruniversefollows thesecondpathasdescribedbelowindetails. Duringthecoalescenceforthesecondpath,thetwouniversescoexistinthesame spacetime,whichispredictedbytheSantilliisodual theory [24]. Antiparticle for our positiveenergyuniverseisdescribedbySantilliasfollows,“thisidentityisatthefoundation oftheperceptionthatantiparticles“appear”toexistinourspace,whileinrealitytheybelong toastructurallydifferentspacecoexistingwithinourown,thussettingthefoundationsofa “multidimensionaluniverse”coexistinginthesamespaceofoursensoryperception”(Ref. [24],p.94).Antiparticlesinthepositiveenergyuniverseactuallycomefromthecoexisting negativeenergyuniverse. Themixingprocessfollowstheisodualholetheorythatisthecombinationofthe Santilli isodual theory and the Dirac hole theory. In the Dirac hole theory that is not symmetrical,thepositiveenergyobservableuniversehasanunobservableinfinitiveseaof negative energy. A hole in the unobservable infinitive sea of negative energy is the observablepositiveenergyantiparticle. In the dual 10D string universe, one universe has positive energy strings with pregravity,andoneuniversehasnegativeenergyantistringswithantipregravity.Forthe mixingofthetwouniversesduringthecoalescence,anewforce,theprechargedforce, emerges to provide the additional distinction between string and antistring. The pre charged force is the predecessor of electromagnetism. Before the mixing, the positive energystringhaspositiveprecharge(e +),whilethenegativeenergyantistringhasnegative precharge(e ).Duringthemixingwhentwo10Dstringuniversescoexist,ahalfofpositive energy strings in the positive energy universe move to the negative energy universe, and leavetheDiracholesinthepositiveenergyuniverse.Thenegativeenergyantistringsthat move to fill the holes become positive energy antistrings with negative precharge inthe positiveenergyuniverse.IntermsoftheDiracholetheory,theunobservableinfinitivesea ofnegativeenergyisinthenegativeenergyuniversefromtheperspectiveofthepositive energy universe before the mixing. The hole is due to the move of the negative energy antistring to the positive energy universe from the perspective of the positive energy universe during the mixing, resulting in the positive energy antistring with negative pre chargeinthepositiveenergyuniverse. In the same way, a half of negative energy antistrings in the negative energy universemovestothepositiveenergyuniverse,andleavetheholesinthenegativeenergy universe.Thepositiveenergystringsthatmovetofilltheholesbecomenegativeenergy stringswithpositiveprechargeinthenegativeenergyuniverse.Theresultofthemixingis thatbothpositiveenergyuniverseandthenegativeenergyuniversehavestringsantistrings. Theexistenceoftheprechargeprovidesthedistinctionbetweenstringandantistringinthe stringantistring. At that time, the space (detachment space) for radiation has not appeared in the universe, so the stringantistring annihilation does not result in radiation. The string antistringannihilationresultsinthereplacementofthestringantistringasthe10Dstring antistring, (2 10 2 10 ) by the 10D particleantiparticle (1 10 1 10 ). The 10D particles antiparticles have the multiple dimensional KaluzaKlein structure with variable space dimensionnumberwithouttherequirementforafixedspacedimensionnumberforstring antistring. After the mixing, the dual 10D particleantiparticle universe separated by pregravityandantipregravityappearsasbelow.

16 + _ + − + _ ((s1 e e 1 s) g ) (g (s1 e e 1 s )) , (15) 10 −10 n 10 −10 n where s and e are the prestrong force and the precharged force in the flat space, g is pregravityinthebulkspace,and1 10 1 10 istheparticleantiparticle. Thedual10Dparticleuniverseconsistsoftwoparallelparticleantiparticleuniverses withoppositeenergiesandthebulkspaceseparatingthetwouniverses.Therearefourequal regions: the positive energy particleantiparticle space region, the pregravity bulk space region,thenegativeenergyparticleantiparticlespaceregion,andtheantipregravitybulk spaceregion. 2.4. The Current Universe

Objectstructure Spacestructure Forces Thelight 4Dparticle attachmentspaceand strong,gravity, universe detachmentspace electromagnetic,and weak Thedark variableDbetween4and attachmentspace prestrong,gravity,pre universe 10particle electromagnetic

Theformationofourcurrentuniversefollowsimmediatelyaftertheformationof the charged preuniverse through the asymmetrical dimensional oscillations and the asymmetricaladditionofdetachmentspace,leadingtotheasymmetricaldualuniverse. Theasymmetricaldimensionaloscillationinvolvedtheimmediatetransformationofthe positiveenergyuniversefrom10Dto4Dandtheslowreversibletransformationofthe negativeenergy universe between 10D and 4D. In the asymmetrical addition of detachment space, the massremoving Higgs boson converted massive particles in the positiveenergyuniverseintomasslessparticles,andthemassiveparticlesinthenegative energy universe remained massive. Afterward, the massgiving Higgs boson converted some massless particles in the positiveenergy universe back to massive particles due to mainly the CP asymmetry (particleantiparticle asymmetry). The result was the asymmetrical dual universe consisting of the positiveenergy 4D light universe with kinetic energy and light and the negativeenergy oscillating 10D4D dark universe withoutkineticenergyandlight.Thelightuniversecontainsbothattachmentspaceand detachmentspace. The four equal parts in the dual universe include the positive energy particle universe, the gravity bulk space, the antigravity bulk space, and the negative energy particleuniverse.Thedarkuniverseincludesthenegativeenergyparticleuniverse,the antigravity bulk space, and the gravity bulk space. The light universe includes the positiveenergyparticleuniverse.Therefore,thedarkuniversecontains75%ofthetotal dual universe, while the light universe contains 25% of the total dual universe. The percentage (75%) of the dark universe later becomes the maximum percentage of the darkenergy. The asymmetrical dual universe is manifested as the asymmetry in the weak interactioninourobservableuniverseasfollows.

17 + + − _ + − + + − _ ((s14 e w e w 1−4 s) g ) n (g (s1≤10 e w e w 1≥−10 s )) n (16) wheres,g,e,andwarethestrongforce,gravity,electromagnetism,andweakinteraction, respectively for the observable universe, and where 1 414 and 1 ≤10 1≥10 are 4D particle antiparticleforthelightuniverseandvariableDparticleantiparticleforthedarkuniverse, respectively. Insummary,thewholeprocessofthelocaldimensionaloscillationsleadingtoour observableuniverseisillustratedasfollows.

betwwen 11D and 10D coalescenc e, annihilation dual membrane universe ← → dual string universe ← → + − 3 ss 3 (( s 2 ) g ) ( g ( s 2 )) 11 −11 10 n −10 n

between 10D and 4D dual 10D particle universe ← → dual 4D / var ible D particle universe + _ + − + _ + + − _ + − + + − _ ((s110 e e 1−10 s) g ) n (g (s110 e e 1−10 s )) n ((s14 e w e w 1−4 s) g ) n (g (s1≤10 e w e w 1≥−10 s )) n wheres,e,andwareintheflatspace,andgisinthebulkspace.Eachstagegenerates oneforce,sothefourstagesproducethefourdifferentforces:thestrongforce,gravity, electromagnetism, and the weak interaction, sequentially. Gravity appears in the first dimensionaloscillationbetweenthe11dimensionalmembraneandthe10dimensional string. The asymmetrical weak force appears in the asymmetrical second dimensional oscillation between the ten dimensional particle and the four dimensional particle. Chargedelectromagnetismappearsastheforceinthetransitionbetweenthefirstandthe seconddimensionaloscillations.Thecosmologyexplainstheoriginsofthefourforces. To prevent the charged preuniverse to reverse back to the previous preuniverse, the chargepreuniverseandthecurrentuniverseoverlaptoacertaindegreeasshowninthe overlappingbetweentheelectromagneticinteractionandtheweakinteractiontoformthe electroweakinteraction. Four-Stage Universe Object Structure Space Structure Force Universe Strong Pre- dual 11Dmembrane attachmentspace prestrong Universe Gravitational dual 10Dstring attachmentspace prestrong,pregravity Pre-Universe Charged Pre- dual 10Dparticle attachmentspace prestrong,pregravity, Universe preelectromagnetic Current Universe dual lightuniverse 4Dparticle attachmentspace strong,gravity, anddetachment electromagnetic,andweak space darkuniverse variableD attachmentspace prestrong,gravity,pre between4and10 electromagnetic,andweak particle The formation of the dark universe involves the slow dimensional oscillation between10Dand4D.Thedimensionaloscillationfortheformationofthedarkuniverse involvesthestepwisetwosteptransformation:theQVSLtransformationandthevarying

18 supersymmetry transformation. In the normal supersymmetry transformation, the repeated application of the fermionboson transformation carries over a boson (or fermion)fromonepointtothesameboson (or fermion) at another point at the same mass. In the “varying supersymmetry transformation”, the repeated application of the fermionbosontransformationcarriesoverabosonfromonepointtothebosonatanother point at different mass dimension number in the same spacetime number. The repeated varying supersymmetry transformation carries over a boson B d into a fermion F d and a fermionF dtoabosonB d1,whichcanbeexpressedasfollows

M d, F = M d, B αd, B , (17a)

M d− ,1 B = M d, F αd, F , (17b) where Md,B and Md,F arethemassesforabosonandafermion,respectively,disthemass dimensionnumber,and α d, B or αd, F isthefinestructureconstantthatistheratiobetween the masses of a boson and its fermionic partner. Assuming α d, B or αd, F , the relation betweenthebosonsintheadjacentdimensionsorndimensionsapart(assuming α’sarethe same)thencanbeexpressedas 2 M d, B = M d + ,1 B αd +1 . (17c) 2n M ,d B = M d + ,n B α d + n . (17d) 2 N d-1 = N d /α . (17e) Eq.(18)showthatitispossibletodescribemassdimensions>4inthefollowing way

F5 B5 F6 B6 F7 B7 F8 B8 F9 B9 F10 B10 F11 B11 , (18) wheretheenergyofB 11 isthePlanckenergy.Eachmassdimensionbetween4dand11d consistsofabosonandafermion.Eq.(19)showastepwisetransformationthatconverts aparticlewithdmassdimensiontod ±1massdimension. stepwise varying supersymmetry D, d← → d(,D ± )1 (19)

Thetransformationfromahighermassdimensionalparticletotheadjacentlowermass dimensional particle is the fractionalization of the higher dimensional particle to the many lower dimensional particles in such way that the number of lower dimensional 2 . particlesbecomes N d-1 = N d /α Thetransformationfromlowerdimensionalparticlesto higher dimensional particle is a condensation. Both the fractionalization and the condensation are stepwise. For example, a particle with 4D (spacetime) 10d (mass dimension) can transform stepwise into 4D9d particles. Since the supersymmetry transformationinvolvestranslation,thisstepwisevaryingsupersymmetrytransformation leads to a translational fractionalization and translational condensation, resulting in expansionandcontraction.

19 Fortheformationofthedarkuniversefromthechargedpreuniverse,thenegative energyuniversehasthe10D4dparticles,whichisconvertedeventuallyinto4D4dstepwise and slowly. It involves the stepwise twostep varying transformation: first the QVSL transformation,andthen,thevaryingsupersymmetrytransformationasfollows. stepwise two stepvaryingtransform ation QVSL (1)D, d ← → (D m1), (d ±1) (20) varying supersymme try (2)D, d ← → D, (d ±1) Therepetitivestepwisetwosteptransformationsfrom10D4dto4D4dareasfollows.

The Hidden Dark Universe and theObservable Dark Universe with Dark Energy

10D4d → 9D5d → 9D4d → 8D5d → 8D4d → 7D5d → • • •• → 5D4d → 4D5d → 4D4d a the hidden dark universe ←a dark energy ← Thedarkuniverseconsistsoftwoperiods:thehiddendarkuniverseandthedark energyuniverse.Thehiddendarkuniversecomposesofthe>4Dparticles.Asmentioned before, particles with different spacetime dimensions are transparent and oblivious to oneanother,andseparatefromoneanotherifpossible.Thus,>4Dparticlesarehidden andseparatedparticleswithrespectto4Dparticlesinthelightuniverse(ourobservable universe).Theuniversewith>4Dparticlesisthehiddendarkuniverse.The4Dparticles transformedfromhidden>4Dparticlesinthedarkuniverseareobservabledarkenergy forthelightuniverse,resultingintheaccelerated expanding universe. The accelerated expanding universe consists of the positive energy 4D particlesantiparticles and dark energythatincludesthenegativeenergy4Dparticlesantiparticles and the antigravity. Sincethedarkuniversedoesnothavedetachmentspace,thepresenceofdarkenergyis notdifferentfromthepresenceofthenonzerovacuumenergy.Intermsofquintessence, suchdarkenergycanbeconsideredthetrackingquintessence[25]fromthedarkuniverse with the spacetime dimension as the tracker. The tracking quintessence consists of the hiddenquintessenceandtheobservablequintessence.Thehiddenquintessenceisfromthe hidden>4Ddarkuniverse.Theobservablequintessenceisfromtheobservable4Ddark universewith4Dspacetime. Fortheformationofthelightuniverse,thedimensionaloscillationforthepositive energy universe transforms 10D to 4D immediately. It involves the leaping twostep varyingtransformation,resultinginthelightuniversewithkineticenergy.Thefirststep isthespacetimedimensionaloscillationthroughQVSL.Thesecondstepisthemass dimensionaloscillationthroughslicingfusion. leaping two − step varying transformation QVSL (1)D, d ← →(D m n), d( ± n) (21) slicing fusion (2)D, d ← → d(,D ± n) + (11−d + n)DO s'

20 The Light Universe quick QVSL transforma tion slicing with det achment space , inf lation 10D4d  → 4D10d → dark matter 4( D9d + 4D8d + 4D7d + 4D6d + 4D5d) + baryonic matter 4( D4d) + cosmic radiation → thermal cosmic expansion (the Big Bang ) In the charged preuniverse, the positive energy universe has 10D4d, which is transformedinto4D10dinthefirststepthroughtheQVSLtransformation.Thesecond step of the leaping varying transformation involves the slicingfusion of particle. Bounias andKrasnoholovets[26]proposeanotherexplanationofthereductionof>4D spacetimeinto4Dspacetimebyslicing>4Dspacetimeintoinfinitelymany4Dquantized unitssurroundingthe4Dcoreparticle.Suchslicingof>4Dspacetimeislikeslicing3 spaceDobjectinto2spaceDobjectinthewaystatedbyMichelBouniasasfollows:“You cannot put a pot into a sheet without changing the shape of the 2D sheet into a 3D dimensionalpacket.Onlya2Dsliceofthepotcouldbeapartofsheet”. Theslicingisbydetachmentspace,asapartofthespacestructure,whichconsists of attachment space (denoted as 1) and detachment space (denoted as 0) as described earlier.Attachmentspaceattachestoobjectpermanentlywithzerospeed.Detachment spacedetachesfromtheobjectatthespeedoflight.Attachmentspacerelatestorestmass, whiledetachmentspacerelatestokineticenergy.Thecosmicoriginofdetachmentspace is the cosmic radiation from the particleantiparticle annihilation that initiates the transformation.Thecosmicradiationcannotpermanentlyattachtoaspace. Theslicingofdimensionsistheslicingofmassdimensions.4D10dparticleissliced intosixparticles:4D9d,4D8d,4D7d,4D6d,4D5d,and4D4dequallybymass.Baryonic matteris4D4d, whiledarkmatterconsistsoftheother five types of particles (4D9d, 4D8d, 4D7d, 4D6d, and 4D5d) as described later. The mass ratio of dark matter to baryonicmatteris5to1inagreementwiththeobservation[27]showingtheuniverse consistsof22.7%darkmatter,4.56%baryonicmatter,and72.8%darkenergy. Detachmentspace(0)involvesintheslicingofmassdimensions.Attachmentspace is denoted as 1. For example, the slicing of 4D10d particles into 4D4d particles is as follows. 6 (1 ) slicing ( 1 ) + ∑ (( 0 )( 1 )) 4 + 6 i  → 4 i 4 4 j 6, 1 > 4d attachment space 4d core attachment space 6 types of 4d units (22)

The two products of the slicing are the 4dcore attachment space and 6 types of 4d quantizedunits.The4dcoreattachmentspacesurroundedby6typesofmany(j)4D4d quantizedunitscorrespondstothecoreparticlesurroundedby6typesofmanysmall4d particles. Therefore,thetransformationfromdtod– ninvolvestheslicingofaparticle withdmassdimensionintotwoparts:thecoreparticlewithd–ndimensionandthe n dimensionsthatareseparablefromthecoreparticle.Such ndimensionsaredenotedas n “dimensionalorbitals”,whichbecomegaugeforcefieldsasdescribedlater.Thesumof thenumberofmassdimensionsforaparticleandthe number of dimensional orbitals (DO’s) is equal to 11 (including gravity) for all particles with mass dimensions. Therefore,

21 Fd = Fd−n + (11− d + n) DO s' (23) where11–d+ nisthenumberofdimensionalorbitals(DO’s)forFdn.Thus,4D10d particlescantransformedinto4D9d,4D8d,4D7d,4D6d,4D5d,and4D4dcoreparticles, whichhave2,3,4,5,6,and7separabledimensionalorbitals,respectively.4D4dhas gravityandsixotherdimensionalorbitalsasgaugeforcefieldsasbelow. Thesix>4dmassdimensions(dimensionalorbitals)forthegaugeforcefieldsand theonemassdimensionforgravityareasinFigure1.

Figure1. Thesevenforcefieldsas>4dmassdimensions(dimensionalorbitals). Thedimensionalorbitalsofbaryonicmatterprovidethebasefortheperiodictable ofelementaryparticlestocalculateaccuratelythemassesofall4Delementaryparticles, includingquarks,leptons,andgaugebosonsasdescribedlater. Thelowestdimensionalorbitalisforelectromagnetism.Baryonicmatteristhe only one with the lowest dimensional orbital for electromagnetism. With higher dimensionalorbitals,darkmatterdoesnothavethislowestdimensionalorbital.Without electromagnetism,darkmattercannotemitlight,andisincompatibletobaryonicmatter,like theincompatibilitybetweenoilandwater.Theincompatibilitybetweendarkmatterand baryonicmatterleadstotheinhomogeneity(likeemulsion),resultingintheformationof galaxies,clusters,andsuperclustersasdescribedlater.Darkmatterhasnotbeenfound bydirectdetectionbecauseoftheincompatibility. Inthelightuniverse,theinflationistheleapingvaryingtransformationthatisthe twostepinflation.Thefirststepistoincrease the rest mass as potential from higher spacetimedimensiontolowerspacetimedimensionasexpressedbyEq.(24a)fromEq. (11b). QVSL D, d  →(D m n), d( ± n) 2 n V D d, = VD − n, d + n α ϕ = collective n's − 2 ϕ V (ϕ) = V4D10dα , whereϕ ≤0 from − 6 to 0 (24a) where αisthefinestructureconstantforelectromagnetism.Theratioofthepotential energiesof4D10dtothatof10D4dis1/ α12 . ϕisthescalarfieldforQVSL,andisequal tocollectiven’sasthechangesinspacetimedimensionnumberformanyparticles.The increaseinthechangeofspacetimedimensionsfrom4Ddecreasesthepotentialasthe restmass.TheregionforQVSLis ϕ ≤0from6to0.TheQVSLregionisforthe conversionofthevacuumenergyintotherestmassasthepotential. Thesecondstepistheslicingthatoccurssimultaneouslywiththeappearanceof detachmentspacethatisthespace forcosmic radiation (photon). Potential energy as

22 massive4D10dparticlesisconvertedintokineticenergyascosmicradiationandmassive matterparticles(from10dto4d).Itrelatestotheratiobetweenphotonandmatterin termsoftheCPasymmetrybetweenparticleandantiparticle.Theslightexcessparticle over antiparticle results in matter particle. The equation for the potential (V) and the scalarfield( φ)isasEq.(24b)fromEq.(35)thatexpressestheratiobetweenphotonand matter. slicing D, d  → d(,D − n) (24b) 2 φ V (φ) = V4D10dα , where φ ≥ 0 from 0to 2 Theratiois α4,accordingtoEq.(35).Theregionfortheslicingis φ≥0from0to2.The slicingregionisfortheconversionofthepotentialenergyintothekineticenergy. ThecombinationofEq.(24a)andEq.(24b)isasEq.(24c). V (ϕ ,φ ) = V (α − 2ϕ + α 2φ ), 4D10d (24c) where ϕ ≤0 and φ ≥ 0 ThegraphforthetwostepinflationisasFigure2.

V V4D10d ϕ φ Figure2.thetwostepinflation Atthetransition(V 4D10d )betweenthefirststep(QVSL)andthesecondstep(slicing),the scalarfieldreversesitssignanddirection.Inthefirststep,theuniverseinflatesbythe decreaseinvacuumenergy.Inthesecondstep,thepotentialenergyisconvertedinto kinetic energy as cosmic radiation. The resulting kinetic energy starts the Big Bang, resultingintheexpandinguniverse. Towardthe endofthe cosmiccontractionafterthe big crunch, the deflation occurs as the opposite of the inflation. The kinetic energy from cosmic radiation decreases,asthefusionoccurstoeliminatedetachmentspace,resultingintheincreaseof potential energy. At the end of the fusion, the force fields except gravity disappear, 4D10dparticles appear, and then the scalar field reverses its sign and direction. The vacuumenergyincreasesasthepotentialastherestmassdecreasesfortheappearanceof 10D4dparticles,resultingintheendofadimensionaloscillationasFigure3forthetwo stepdeflation. V V4D10d

ϕ φ Figure3.thetwostepdeflation

23

Theendofthetwostepdeflationis10D4d,whichisfollowedimmediatelybythe dimensionaloscillationtoreturnto4D10dasthe“dimensionalbounce”asshowninFigure 4,whichdescribesthedimensionaloscillationfromthelefttotheright:thebeginning (inflationas10D4dthrough4D10dto4D4d),thecosmicexpansioncontraction,theend (deflationas4D4dthrough4D10dto10D4d),thebeginning(inflation),thecosmic expansioncontraction,andtheend(deflation). . V

time inflation expansion deflation inflation expansion deflation contraction contraction dimensionalbounce Figure4. thecyclicobservableuniversebythedimensionaloscillation The twostep inflation corresponds to the quintom inflation. The symmetry breakingforthelightuniversecanbedescribedbyquintom.Quintom[28][29][30]is thecombinationofquintessenceandphantom.Quintessence describes a timevarying equationofstateparameter, w,theratioofitspressuretoenergydensityand w >−1. 1 L = (∂ φ )2 −V (φ) (25) quint essnec 2 . φ 2 −2V (φ) w = . φ 2 + 2V (φ) (26) −1≤ w≤+1 Quintomincludesphantomwith w<−1.Ithasoppositesignofkineticenergy. −1 L = (∂ ϕ )2 −V (ϕ) (27) phantom 2 . −ϕ 2 −2V (ϕ) w = . −ϕ 2 + 2V (ϕ) (28) −1≥ w AsthecombinationofquintessenceandphantomfromEqs.(24),(25),(26),and (27),quintomisasfollows. 1 1 L = (∂ φ )2 − (∂ ϕ )2 − V (φ) −V (ϕ) (29) quint essnec 2 2

24 . . 2 2 φ −ϕ − 2V (φ)− 2V (ϕ) w = . . (30) φ 2 −ϕ 2 + 2V (φ)+ 2V (ϕ) Phantomrepresentsthescalarfield ϕinthespacetimedimensionaloscillationin QVSL, while quintessence represents the scalar field φ in the mass dimensional oscillation in the slicingfusion. Since QVSL does not involve kinetic energy, the physical source of the negative kinetic energy for phantom is the increase in vacuum energy, resulting in the decrease in energy density and pressure with respect to the observablepotential,V( ϕ).CombiningEqs.(24c)and(30),quintomisasfollows. . . φ 2 −ϕ 2 − 2V (φ)− 2V (ϕ) w = . . φ 2 −ϕ 2 + 2V (φ)+ 2V (ϕ) . . 2 2 − 2 ϕ 2 φ φ −ϕ − 2V4D10d (α + α ) (31) = . . 2 2 − 2 ϕ 2 φ φ −ϕ + 2V4D10d (α + α ) where ϕ ≤0 and φ ≥ 0

Figure5showstheplotoftheevolutionoftheequationofstate wforthequintom inflation. w -1 t Figure5.the w ofquintomforthequintominflation Figure6showstheplotoftheevolutionoftheequationofstate wforthecyclic universeasFigure4. w -1 tt QuintomBounce Figure6.thecyclicuniversebythedimensionalos cillationasFigure4 InthedimensionalbounceinthemiddleofFigure6,theequationofstatecrosses w=1 twiceasalsoshownintherecentdevelopmentofthequintommodel[31][32]inwhich,for the Quintom Bounce, the equation of state crosses the cosmological constant boundary twicearoundthebouncepointtostartanothercycleofthedualuniverse. ThehiddendarkuniversewithD>4andtheobservableuniversewithD=4are the “parallel universes” separated from each other bythebulkspace.Whentheslow QVSL transformation transforms gradually 5D hidden particles in the hidden universe intoobservable4Dparticles,andtheobservable4Dparticlesbecomethedarkenergyfor

25 theobservableuniversestartingfromabout5billion years ago (more precisely 4.71 ± 0.98billionyearsagoatz=0.46 ±0.13)[33].Atacertaintime,thehiddenuniverse disappears,andbecomescompletelyobservableasdarkenergy.Themaximumconnection of the two universes includes the positive energy particleantiparticle space region, the gravitybulkspaceregion,thenegativeenergyparticleantiparticlespaceregion,andthe antigravity bulk space region. Through the symmetry among the space regions, all regionsexpandsynchronicallyandequally.(Thesymmetryisnecessaryfortheultimate reversibilityofallcosmicprocesses.) Thelightuniverseincludesthepositiveenergyparticleantiparticleuniverse,and the dark universe includes the negativeenergy particleantiparticle universe, the anti gravitybulkspace,andthegravitybulkspace.Thelightuniverseoccupies25%ofthe total universe, while the dark universe occupies 75% of the total universe, so the maximumdarkenergyfromthedarkuniverseis75%.Thepresentobservableuniverse aboutreachesthemaximum(75%)attheobserved72.8%darkenergy[27].At72.8% darkenergy,thecalculatedvaluesforbaryonicmatteranddarkmatter(withthe1:5ratio) are4.53%(=(100–72.8)/6)and22.7%(=4.53x5),respectively,inexcellentagreement withobserved4.56%and22.7%,respectively[27].Ouruniverseis13.7billionyearold. Darkenergyasthetransformationfrom5Dto4Dstartedinabout4.71 ± 0.98 billion yearsago[33].TheratioofthetimeperiodsforthetransformationsfromD →D1is proportional to ln of the total number of particles (Eqs. (11b) and (17e)) to be transformedfromD →D–1fortheexponentialgrowthwithtime. The Percentages of the Periods in the Dark Universe 10D 9D 8D 7D 6D 5D →9D →8D →7D →6D →5D →4D ratiooftotalnumbersofparticles 1 α2 α4 α6 α8 α10 ratioofln(totalnumberofparticles) 0 2α 4α 6α 8α 10 α ratioofperiods ∼0 1 2 3 4 5 percentagesofperiods ∼0 6.7 13.3 20 26.7 33.3 αisthefinestructureconstantforelectromagnetismfromEq.(11b) Theperiodofthe5D→4Dis(0.333)(13.7)/((0.333)(72.8/75)+0.667)=4.61billion years,anddarkenergyasthe5D→4Dstartedin(4.61)(72.8/75)=4.47billonyearsago thatisinagreementwiththeobservedvalueof4.71 ±0.98billionyearsago[33]. Afterthemaximallyconnecteduniverse,4Ddarkenergytransformsbackto>4D particlesthatarenotobservable.Theremovalofdarkenergyintheobservableuniverse resultsinthestopofacceleratedexpansionandthestartofcontractionoftheobservable universe. Theendofdark energystartsanother “parallel universe period”. Both hidden universe and observable universe contract synchronically and equally. Eventually, gravitycausestheobservableuniversetocrushtoloseallcosmicradiation,resultingin thereturnto4D10dparticlesunderthedeflation.Theincreaseinvacuumenergyallows 4D10d particles to become positive energy 10D4d particlesantiparticle. Meanwhile, hidden>4Dparticlesantiparticlesinthehiddenuniversetransformintonegativeenergy 10D4dparticlesantiparticles.Thedualuniversecanundergoanothercycleofthedual universe with the dark and light universes. On the other hand, both universes can

26 undergo transformation by the reverse isodual hole theory to become dual 10D string universe,whichinturncanreturntothe11Dmembraneuniversethatinturncanreturn tothezeroenergyuniverseasfollows. zeroenergyuniverse +11Dmembraneuniverse −11Dantimembraneuniverse +10Dstringuniverse −10Dantistringuniverse

+10Dparticleuniverse −10Dparticleuniverse

+4D −variable>4D observable +4D −variable>4D hidden universe observable hiddenuniverse universe universe +4Duniversewithdark energyas −4Duniverse +=positiveenergy, − =negativeenergy

Figure 7. Cosmology

2.5. Summary There are three stages of preuniverses in chronological order: the strong pre universe,thegravitationalpreuniverse,andthechargedpreuniverse.Thefirstuniverse fromthezeroenergyuniverseinmultiverseisthestrongpreuniversewiththesimplest expression of the spaceobject structures. Its object structure is 11D positive and negativemembraneanditsspacestructureisattachmentspaceonly.Theonlyforceis the prestrong force without gravity. The transformationfrom11Dmembraneto10D stringresultsinthegravitationalpreuniversewithbothprestrongforceandpregravity. Therepulsivepregravityandpreantigravitybringsaboutthedual10Dstringuniverse withthebulkspace.Thecoalescenceandtheseparationofthedualuniverseresultinthe dualchargeduniverseasdual10Dparticleuniversewiththeprestrong,pregravity,and preelectromagneticforcefields. The asymmetrical dimensional oscillations and the asymmetrical addition of detachmentspaceresultintheasymmetricaldualuniverse:thepositiveenergy4Dlight universewithlightandkineticenergyandthenegativeenergyoscillating10D4Ddark universewithoutlightandkineticenergy.Thelightuniverseisourobservableuniverse. Thedarkuniverseissometimeshidden,andissometimesobservableasdarkenergy.The dimensional oscillation for the dark universe is the slow dimensional oscillation from 10Dand4D.Thedimensionaloscillationforthelightuniverseinvolvestheimmediate transformationfrom10Dto4Dandtheintroduction ofdetachmentspace, resultingin lightandkineticenergy.Theasymmetricaldimensionaloscillationandtheasymmetrical

27 additionofdetachmentspacearemanifestedastheasymmetricalweakforcefield.When thedarkuniversebecomesthe4Duniverse,thedarkuniverseturnsintodarkenergy.The calculatedpercentagesofdarkenergy,darkmatter,andbaryonicmatter72.8,22.7,and 4.53, respectively, in nearly complete agreement with observed 72.8, 22.7, and 4.56, respectively.Accordingtothecalculation,darkenergystartedin4.47billionyearsagoin agreementwiththeobserved4.71 ±0.98billionyearsago.

28 3. The Periodic Table of Elementary Particles 3.1. The CP Asymmetry In the light universe, cosmic radiation is the result of the annihilation of the CP symmetricalparticleantiparticle.However,thereistheCPasymmetry,resultinginexcess ofmatter.MatterresultsfromthecombinationoftheCPasymmetricalparticleantiparticle. A baryonic matter particle (4d) has seven dimensional orbitals. The CP asymmetrical particleantiparticle particle means the combination of two asymmetrical sets of seven from particle and antiparticle, resulting in the combination of the seven “principal dimensional orbitals” and the seven “auxiliary dimensional orbitals”. The auxiliary orbitalsaredependentontheprincipalorbitals,soabaryonicmatterparticleappearsto haveonlyonesetofdimensionalorbitals.Forbaryonicmatter,theprincipaldimensional orbitals are for leptons and gauge bosons, and the auxiliary dimensional orbitals are mainlyforindividualquarks.Becauseofthedependenceoftheauxiliarydimensional orbitals,individualquarksarehidden.Inotherwords,thereisasymmetrybetweenlepton andquark,resultinginthesurvivalofmatterwithoutannihilation.Theconfigurationof dimensionalorbitalsandtheperiodicaltableofelementaryparticles[34]areshownin Fig.8andTable1. Lepton νee ν ντl 9 l10 7 τ7 8 d=56 7891011 a = 0 1 2 3 4 5 0 1 2 d 7 s7 c7 b 7 t 7 b 8 t8 u7 u 5d 63 ′ q 9 q 10 Quark

Fig. 8: leptonsandquarksintheprincipalandauxiliarydimensionalorbitalsd= principaldimensionalorbital(solidline)number,a=auxiliarydimensionalorbital(dot line)number

29

Table 1. ThePeriodicTableofElementaryParticles d=principaldimensionalorbitalnumber,a=auxiliarydimensionalorbitalnumber D a=0 1 2 a=0 1 2 3 4 5 Lepton Quark Boson 5 L5= νe q5=u=3 νe B5=A 6 L6=e q6=d=3e B6= π1/2 0 7 L7= ν 7 τ7 q7=3 u7/d 7 s7 c7 b7 t7 B7=Z L 8 L8= ντ 8 q8= ' b8 t8 B8=X R (empty) (empty) 9 L9 q9 B9=X L 0 10 B10 =Z R 11 B11 InFig.8andTable1,distheprincipaldimensionalorbitalnumber,andaisthe auxiliarydimensionalorbitalnumber.(NotethatF dhaslowerenergythanB d.) 3.2. The Boson Mass Formula Theprincipaldimensionalorbitalsareforgaugebosonsoftheforcefields.Forthe gaugebosons,thesevenorbitalsofprincipaldimensionalorbitalarearrangedasF 5B 5F 6 B6F 7B 7F 8B 8F 9B 9F 10 B 10 F 11 B 11 ,whereBandFarebosonandfermionineachorbital. The mass dimension in Eq. (17) becomes the orbitals in dimensional orbital with the sameequations.

M d, F = M d, B αd, B , (32a)

M d− ,1 B = M d, F αd, F , (32b) 2 M d 1, B = M ,d B αd . (32c) whereDisthedimensionalorbitalnumberfrom6to11.E 5,B andE 11,B aretheenergiesfor the5ddimensionalorbitalandthe11ddimensionalorbital,respectively.Thelowestenergy istheCoulombicfield,

E ,5 B = α E ,6 F = α M e . (33) ThebosonsgeneratedarethedimensionalorbitalbosonsorB D.Usingonly αe,the 0 massofelectron(M e),themassofZ ,andthenumber(seven)ofdimensionalorbitals,the massesofB DasthegaugebosoncanbecalculatedasshowninTable2.

30 Table 2. TheMassesofthedimensionalorbitalbosons: α= αe,d=dimensionalorbitalnumber Bd Md GeV Gauge Interaction,symmetry Predecessor (calculated) boson 6 B5 Meα 3.7x10 A Electromagnetic,U(1) Precharged 2 B6 Me/α 7x10 π1/2 Strong,SU(3) Prestrong 2 0 B7 M6/αw cos θw 91.177(given) ZL weak(left),SU(2) L Fractionalization (slicing) 2 6 B8 M7/α 1.7x10 XR CP(right)nonconservation CPasymmetry 2 10 B9 M8/α 3.2x10 XL CP(left)nonconservation CPasymmetry 2 14 0 B10 M9/α 6.0x10 ZR weak(right) Fractionalization (slicing) 2 19 B11 M10 /α 1.1x10 G Gravity Pregravity InTable2, α= αe(thefinestructureconstantforelectromagneticfield),and αw= 2 α/sin θw. αwisnotsameas αoftherest,becauseasshownlater,thereisamixingbetween B5andB 7asthesymmetrymixingbetweenU(1)andSU(2)inthestandardtheoryofthe electroweakinteraction,andsin θwisnotequalto1.(Thesymmetricalchargeddualpre universeoverlapswiththecurrentasymmetricaluniversefortheweakinteractionasshown earlier.)Asshownlater,B 5,B 6,B 7,B 8,B 9,andB 10 areA(masslessphoton), π1/2 (halfof 0 0 pion), Z L , X R, X L, and Z R , respectively, responsible for the electromagnetic field, the stronginteraction,theweak(lefthanded)interaction,theCP(righthanded)nonconservation, the CP (left handed) nonconservation, and the P (right handed) nonconservation, 0 respectively.Thecalculatedvaluefor αwis0.2973,and θwis29.69 ingoodagreement 0 19 with29.31 fortheobservedvalueof θw[35].ThecalculatedenergyforB 11 is1.1x10 GeV in good agreement with the Planck mass, 1.2x10 19 GeV. The strong interaction, representingby π1/2 (halfofpion),isfortheinteractionsamongquarks,andforthehidingof 0 individualquarksintheauxiliaryorbital.Theweakinteraction,representingbyZ L ,isfor theinteractioninvolvingchangingflavors(decompositionandcondensation)amongquarks andleptons. Therearedualitiesbetweendimensionalorbitalsandthecosmicevolutionprocess. Theprechargedforce,theprestrongforce,thefractionalization,theCPasymmetry,andthe pregravity are the predecessors of electromagnetic force, the strong force, the weak interaction,theCPnonconservation,andgravity,respectively.Theseforcesaremanifested inthedimensionalorbitalswithvariousspacetimesymmetriesandgaugesymmetries.The strengthsoftheseforcesaredifferentthantheirpredecessors,andarearrangedaccordingto thedimensionalorbitals.Onlythe4dparticle(baryonicmatter)hastheB 5,sowithoutB 5, dark matter consists of permanently neutral higher dimensional particles. It cannot emit light,cannotformatoms,andexistsasneutralgas. Theprincipaldimensionalboson,B 8,isaCPviolatingboson,becauseB 8isassumed tohavetheCPviolatingU(1) Rsymmetry.TheratiooftheforceconstantsbetweentheCP invariantW LinB 8andtheCPviolatingX RinB 8is

31 2 2 G8 α E7 cos ΘW = 2 G7 αW E 8 (34) = 5.3 X 10-10 , whichisinthesameorderastheratiooftheforceconstantsbetweentheCPinvariantweak interactionandtheCPviolatinginteractionwith S=2. Theprincipaldimensionalboson,B 9(X L),hastheCPviolatingU(1) Lsymmetry.B 9 generatesmatter.TheratioofforceconstantsbetweenX RwithCPconservationandX L withCPnonconservationis α 2 G9 = E8 2 G8 α E9 = α 4 (35) = 2.8 X 10 9- , whichistheratioofthenumbersbetweenmatter(darkandbaryonic)andphotonsinthe universe.Itisclosetotheratioofthenumbersbetweenbaryonicmatterandphotonsabout 5x10 –10 obtainedbytheBigBangnucleosynthesis. Auxiliarydimensionalorbitalisderivedfromprincipaldimensionalorbital.Itisfor highmass leptons and individual quarks. The combination of dimensional auxiliary dimensionalorbitalsconstitutestheperiodictableforelementaryparticlesasshowninFig.8 andTable1. Therearetwotypesoffermionsintheperiodictableofelementaryparticles:low massleptonsandhighmassleptonsandquarks.Lowmassleptonsinclude νe,e, ν,and ντ, which are in principal dimensional orbital, not in auxiliary dimensional orbital. l d is denotedasleptonwithprincipaldimensionnumber,d.l 5,l 6,l 7,andl 8are νe,e, ν,and ντ,respectively.Allneutrinoshavezeromassbecauseofchiralsymmetry(permanentchiral symmetry). 3.3. The Mass Composites of Leptons and Quarks Highmass leptons and quarks include , τ, u, d, s, c, b, and t, which are the combinationsofbothprincipaldimensionalfermionsandauxiliarydimensionalfermions. Eachfermioncanbedefinedbyprincipaldimensionalorbitalnumbers(d's)andauxiliary dimensionalorbitalnumbers(a's)asd ainTable3.Forexamples,eis6 0thatmeansithasd (principaldimensionalorbitalnumber)=6anda(auxiliarydimensionalorbitalnumber)=0, soeisaprincipaldimensionalfermion. Highmassleptons, and τ,arethecombinationsofprincipaldimensionalfermions, eand ν,,andauxiliarydimensionalfermions.Forexample, isthecombinationofe, ν,, and 7,whichis7 1thathasd=7anda=1. Quarks are the combination of principal dimensional quarks (q d) and auxiliary dimensionalquarks.Theprincipaldimensionalfermionforquarkisderivedfromprincipal dimensional lepton. To generate a principal dimensional quark in principal dimensional orbitalfromaleptoninthesameprincipaldimensionalorbitalistoaddtheleptontothe bosonfromthecombinedleptonantilepton.Thus,themassofthequarkisthreetimesof

32 themassofthecorrespondingleptoninthesamedimension.Theequationforthemassof principaldimensionalfermionforquarkis M = 3M (36) qd ld Forprincipaldimensionalquarks,q 5(5 0)andq 6(6 0)are3 νeand3e,respectively.Sincel 7 is massless ν, νisreplacedby ,andq 7is3 .Quarksarethecombinationsofprincipal dimensional quarks, q d, and auxiliary dimensional quarks. For example, s quark is the combinationofq 6(3e),q 7(3 )ands 7(auxiliarydimensionalquark=7 2). Each fermion can be defined by principal dimensional orbital numbers (d's) and auxiliarydimensionalorbitalnumbers(a's).Allleptonsandquarkswithd’s,a’sandthe calculatedmassesarelistedinTable3. Table 3. TheCompositionsandtheConstituentMassesofLeptonsandQuarks d=principaldimensionalorbitalnumberanda=auxiliarydimensionalorbitalnumber

da Composition CalculatedMass Leptons daforleptons νe 50 νe 0 e 60 e 0.51MeV (given) ν 70 ν 0 ντ 80 ντ 0 60+7 0+7 1 e+ ν+ 7 105.6MeV τ 60+7 0+7 2 e+ ν + τ7 1786MeV ' 60+7 0+7 2+8 0+8 1 e+ ν+ 7+ ντ+ 8(3/2Z°) 136.9GeV ± ± ± ± ' 60+7 0+7 2+8 0+8 1 e+ ν+ 7+ ντ+ 8 (3/2W ) 120.7GeV Quarks daforquarks u 50+7 0+7 1 q5+q 7+u 7 330.8MeV d 60 +7 0+7 1 q6+q 7+d 7 332.3MeV s 60 +7 0+7 2 q6+q 7+s 7 558MeV c 50+7 0+7 3 q5+q 7+c 7 1701MeV b 60 +7 0+7 4 q6+q 7+b 7 5318MeV t 50+7 0+7 5+8 0+8 2 q5+q 7+t 7+q 8+t 8 176.5GeV 3.4. The Lepton Formula Theprincipaldimensionalfermionforheavyleptons( and τ)iseand νe.Auxiliary dimensionalfermionisderivedfromprincipaldimensionalbosoninthesamewayasEq. (32)torelatetheenergiesforfermionandboson.Forthemassofauxiliarydimensional fermion(AF)fromprincipaldimensionalboson(B),theequationisEq.(37). M a M = Bd− 0,1 a4 , (37) AFd ,a ∑ αa a=0

33 where αa = auxiliary dimensional fine structure constant, and a = auxiliary dimension

M B number = 0 or integer. The first term, D−1 0, , of the mass formula (Eq.(37)) for the α a auxiliarydimensionalfermionsisderivedfromthemassequation,Eq.(32),fortheprincipal a dimensional fermions and bosons. The second term, ∑a 4 , of the mass formula is for a=0 BohrSommerfeld quantization for a charge dipole interaction in a circular orbit as describedbyA.Barut[36].AsinBarutleptonmassformula,1/ αais3/2.Thecoefficient, 3/2, is to convert the principal dimensional boson mass to the mass of the auxiliary dimensionalfermioninthehigherdimensionbyaddingthebosonmasstoitsfermionmass whichisonehalfofthebosonmass.UsingEq.(32),Eq.(37)becomestheformulaforthe massofauxiliarydimensionalfermions(AF). 3M a = = Bd − 0,1 4 M AF d,a ∑ a 2 a=0 a 3M F = d − 0,1 ∑ a4 (38) 2αd −1 a=0 3 a = M α a4 Fd 0, d ∑ 2 a=0 Themassofthisauxiliarydimensionalfermionisaddedtothesumofmassesfrom thecorrespondingprincipaldimensionalfermions(F’s)withthesameelectricchargeorthe samedimension.Thecorrespondingprincipaldimensionalleptonsforu(2/3charge)andd (1/3charge)are νe(0charge)ande(1charge),respectively,byadding–2/3chargetothe chargesofuandd[37].Thefermionmassformulaforheavyleptonsisderivedasfollows. M = M + M Fd ,a ∑ F AFd ,a 3M a Bd − 0,1 4 (39a) = ∑M F + ∑a 2 a=0

3M a Fd − 0,1 4 = ∑M F + ∑a 2α d −1 a=0 (39b)

3 a = M + M α a 4 (39c) ∑ F Fd 0, d ∑ 2 a=0 Eq.(39b)isforthecalculationsofthemassesofleptons.Theprincipaldimensionalfermion inthefirsttermise.Eq.(39b)canberewrittenasEq.(40).

34 3M a M = M + e a4 , (40) a e ∑ 2α a = 0 a=0,1,and2arefore, ,and τ,respectively.ItisidenticaltotheBarutleptonmass formula. 3.5. The Quark Mass Formula Theauxiliarydimensionalquarksexceptapartoftquarkareq 7’s.Eq.(39c)isusedto calculatethemassesofquarks.Theprincipaldimensionalquarksinclude3 ν,3e,and3 ., α7= αw, andq 7=3 .Eq.(39c)canberewrittenasthequarkmassformula. 3α M w 3 a M = M + a4 , (41) q ∑ F ∑ 2 a = 0 wherea=1,2,3,4,and5foru/d,s,c,b,andapartoft,respectively. Tomatchl 8( ντ),quarksincludeq 8asapartoftquark.Inthesamewaythatq 7= 3,q 8involves ’. ‘isthesumofe, ,and 8 (auxiliarydimensionallepton).UsingEq. 0 (39a),themassof 8isequalto3/2ofthemassofB 7,whichisZ .Becausethereareonly threefamiliesforleptons, 'istheextralepton,whichis"hidden". 'canappearonlyas + photon.Theprincipaldimensionalquarkq 8= 'insteadof3 ',because 'ishidden,andq 8 doesnotneedtobe3 'tobedifferent.UsingtheequationsimilartoEq.(41),thecalculation fortquarkinvolves α8= α, 'insteadof3 forprincipalfermion,anda=1and2forb 8 andt 8,respectively.Thehidingof 'forleptonsisbalancedbythehidingofb 8forquarks. Thecalculatedmassesareingoodagreementwiththeobservedconstituentmasses ofleptonsandquarks[38].Themassofthetopquark[39]is174.3±5.1GeVinagood agreementwiththecalculatedvalue,176.5GeV.Allelementaryparticles(gaugebosons, leptons,andquarks)areintheperiodicsystemofelementaryparticleswiththecalculated massesingoodagreementwiththeobservedvaluesbyusingonlyfourknownconstants:the numberoftheextraspatialdimensionsintheelevendimensionalmembrane,themassof electron,themassofZboson,andthefinestructureconstant. Withthemassesofquarkscalculatedbytheperiodictableofelementaryparticles, themassesofallhardronscanbecalculated[33]asthecomposesofquarks,asmolecules are the composes of atoms. The calculated values are in good agreement with the observed values. For examples, the calculated masses of neutron and pion are 939.54MeV,and135.01MeVinexcellentagreementwiththeobservedmasses,939.57 MeVand134.98MeV,respectively.Atdifferenttemperatures,thestrongforce(QCD) amongquarksinhadronsbehavesdifferentlytofollowdifferentdimensionalorbitals[33]. 3.6. The LHC Higgs Boson

TheATLASandCMSexperimentsofCERNexperimentsobserveanewparticlein the mass region around 125126 GeV with a high degree of certainty [40]. The decay modesandthespinofthenewparticlepointtoaHiggsboson.

35 AdeviationfromtheStandardModelistheexcessdecayratetodiphotonthatwas observedbybothATLASandCMSaswellastheFermilabTevatron[41].Thedecayrate ofdiphotonisnearlytwiceaslargeasexpectedbytheStandardModel.Thesignificanceof thediscrepancywiththeStandardModelisabout2.5sigma.Aslongasthisexcesspersists, itcanbefittedbyanonstandard(possiblynegative)YukawacouplingsoftheHiggsboson tothetopquark,orexplainedbynewchargedbosoncontributionstothelooplevelprocess h→ γγ.Ifthatbosonexists,itmusthaveamasslargerthantheW;otherwise,theHiggs woulddecaytothisparticleinpairs.Furtherworkondiphotonisneeded. Iftheexcessdiphotonpersists,itcanbeexplainedbytheLHCHiggsboson.The LHC Higgs boson is the Higgs boson consisting of theSM Higgs bosonand thehidden leptoncondensate,similartothetopquarkcondensate[42]thatisanalternativetotheHiggs boson.Thetopquarkcondensateisacompositefieldcomposedofthetopquarkandits antiquark.Thetopquarkcondenseswithitsmeasuredmass(173GeV)comparabletothe massoftheWandZBosons,soVladimirMiransky,MasaharuTanabashi,andKoichi YamawakiproposedthatthetopquarkcondensateisresponsibleforthemassoftheWand Zbosons.(Asdescribedlater,thehiddenleptonsderivedbytheWbosonandZbosonare partlyresponsibletothehighmassoftopquark.)Thetopquarkcondensateisanalogousto Cooper pairs in a BCS superconductor and nucleons in the NambuJonaLasinio model. Anna Hasenfratz and Peter Hasenfratz et al. claimed that the top quark condensate is approximately equivalent to a Higgs scalar field. S. F. King proposed a tau lepton condensatetofeedthetaumasstomuonandelectron[43]. Like the top quark condensate, the hidden lepton condensate is a composite field composedofthehiddenleptonsanditsantileptonsas ’, ’, ’+,and ’ .Likethatthe observedtopquarkisabarequarkwiththeobservedmassofabout173GeVinsteadof about346GeVfort t,theobservedhiddenleptonisabareaveragehiddenleptoninsteadof ’’ and ’+ ’ . However, unlike the top quark condensate, the hidden lepton condensate is outside of the standard three leptonquark families in the Standard Model. Beingforbidden,asinglehiddenleptoncannotexistalone,sothehiddenleptonsmustexist intheleptoncondensateasthecompositeoftheleptonsantileptonsas ’, ’, ’+,and ’ . Beingoutsideofthestandardmodelfamily,thehidden lepton condensate decays into diphotoninsteadofleptonsandquarksinsidethestandardmodelfamily. TheLHCHiggsbosonconsistsofboththeHiggsbosonoftheStandardModel andtheadoptedhiddenleptoncondensate.WhentheLHCHiggsbosondecays,itdecays astheHiggsbosonoftheStandardModelexceptthepartoftheadoptedhiddenlepton

36 condensatethatdecaysintodiphoton,resultinginthedeviationintherateofdiphoton from the standard model. Other decay modes of the LHC Higgs boson follow the StandardModel(SM)asfollowsforthesixdecaymodesoftheLHCHiggsbosons. The Decay Modes of the LHC Higgs boson H(hiddenleptoncondensate) γγ H(SM) γγ

H(SM) ZZ

H(SM) WW

H(SM) b b

H(SM) ττ Thehiddenleptonsarederivedfromtheperiodictableofelementaryparticlesthat includes all elementary particles. Like the top quark condensate, the hidden lepton condensateisacompositefieldcomposedofthehiddenleptonsanditsantileptonsas ’, + ’, ’ ,and ’ asinTable3.Tomatchl 8( ντ),quarksincludeq 8asapartoftquark.In the same way that q 7 = 3 , q 8 involves ’. ‘ is the sum of e, , and 8 (auxiliary dimensionallepton). Using Eq. (39a),the mass of8 is equal to 3/2 ofthe mass of B 7, 0 ± ± ± whichisZ ,andthemassof 8 isequalto3/2ofthemassofB 7 ,whichisW . 3 = Z 0 8 2

' = 60 + 7 0 + 7 2 + 8 0 + 8 1 = e +ν +7 +ντ + 8 3 ± = W ± 8 2 ± ± ± '' = 60 + 7 0 + 7 2 + 8 0 + 8 1 = e +ν +7 +ν τ + 8 Thecalculatedmassesofthehiddenleptonare120.7GeV(forthemassof ’±)and136.9 GeV(forthemassof ’)withtheaverageas128.8GeVforthehiddenleptoncondensatein goodagreementswiththeresultsfromLHC(125GeVor126GeV).TheLHCHiggsboson acquiresthemassofthehiddenleptoncondensate. TheHiggsbosonisthescalargaugebosontomediatethetransformationbetween massive particle (mass) and massless particle (kinetic energy). The Higgs boson can be massgivingormassremoving.Beforeouruniverse,allparticlesweremassive,themasses ofallparticleswereequal,andourpreuniversewascold.Atthebeginningofouruniverse, the massremoving Higgs boson converted massive particles into massless particles, resultingintheveryhotuniversetoinitiatetheBigBang.Afterward,themassgivingHiggs boson converted some massless particles back to massive particles to differentiate dark matterandbaryonicmatterandtodifferentiatebaryonicparticlesandforceswithvarious

37 differentmasses.Withoutmasslessphoton,darkmatterisdarkwithoutelectromagnetism, and incompatible (repulsive) to baryonic matter. The interactions of incompatible dark matter and baryonic matter generated the different shapes of galaxies. The baryonic particlesandforcesformtheperiodictableofelementaryparticlestocalculatethemassesof allelementaryparticles.DarkenergycomesfromthedarkuniversewithouttheHiggs boson. TheHiggsbosonitselfisthegaugebosonwithzeromassenergy.ThevirtualHiggs bosonisapropertyofspacethatcanturnonthetransformationbetweenthemassiveparticle (masspotential energy) and masslessparticle (kinetic energy). (As described earlier, the transformation for different amounts of massenergy is through another mechanism: the dimensional oscillation of object.) After the transformation, the Higgs boson remains dormant.Withzeromassenergy,theHiggsbosonavoidsthesevereproblemofthehuge energy(cosmologicalconstant)fromthegravityHiggsbosoninteraction. The observed LHC Higgs boson is a remnant of the Higgs boson, not the Higgs bosonitself.TheLHCHiggsbosonisderivedfromtheasymmetry(symmetrybreaking)in theelectroweakforceconsistingoftheelectromagneticforcewiththemasslessgaugeboson (photon) and the weak force with the massive gauge bosons (W+, W−, and Z). At the beginning of our universe, the coupling of the Higgs field and the electroweak force involvedthefourmassgivingHiggsbosonsandthefourgaugebosons(W+,W−,Z,and photon)intheelectroweakforce.ThethreeHiggsbosonscoupledwiththethreemassless weakbosons(W+,W−,andZ),andwereonlyobservableasspincomponentsoftheseweak bosons,whichbecamemassive;whiletheoneremaininguncoupledHiggsbosonbecame theresidualunusedHiggsbosonafterthetransformationoftheelectroweakforce.Sincethe transformationhadfinished,theresidualunusedHiggsbosoncouldnotremainzeromass energyastheoriginalHiggsboson,soithadtoadoptamass.TheresidualHiggsboson couldnotadoptanymassthatalreadyrepresentedanindependentelementaryparticle.The only available mass came from the hidden lepton in the form of the hidden lepton condensate.Theelectroweak,strong,andgravitationalforcesareseparatedforces,sothere isnoremnantoftheHiggsbosonfromthem.

3.7. Summary Forbaryonicmatter,theincorporationofdetachment space for baryonic matter bringsabout“thedimensionalorbitals”asthebasefortheperiodictableofelementary particlesforallleptons,quarks,andgaugebosons.Themassesofgaugebosons,leptons, quarkscanbecalculatedusingonlyfourknownconstants:thenumberoftheextraspatial dimensionsintheelevendimensionalmembrane,themassofelectron,themassofZ°,and thefinestructureconstant.Thecalculatedvaluesareingoodagreementwiththeobserved values. The differences in dimensional orbitals resultinincompatibledarkmatterand baryonicmatter.TheobservednewLHCHiggsBosonconsistsoftheSM(StandardModel) Higgsbosonandthehiddenleptoncondensatethatisintheforbiddenleptonfamilyoutside of the standard three lepton families in the Standard Model. Being forbidden, a single hiddenleptoncannotexistalone,sothehiddenleptonsmustexistintheleptoncondensate as the composite of the leptonsantileptons as ’, ’, ’+, and ’ . The decay of the hidden lepton condensate into diphoton accounts for the observed excess diphoton deviatedfromtheStandardModel.OtherdecaymodesoftheLHCHiggsbosonfollow

38 theStandardModel.Thecalculatedmassesofthehiddenleptonsof ’± and ’,are120.7 GeV and 136.9 GeV, respectively, with the average as 128.8 GeV for the hidden lepton condensateingoodagreementswiththeobserved125or126GeV.TheLHCHiggsboson acquiresthemassofthehiddenleptoncondensate.

39 4. The Galaxy Formation

Introduction

The current observable universe contains dark energy, dark matter, and baryonic matter. As mentioned in the previous section, dark energy is from the dark universe to accelerate the expansion of the observable universe. Dark matter have different mass dimension from the baryonic matter. We live in the world of baryonic matter. The separationofbaryonicmatteranddarkmatterresultsinthegalaxyformation. 4.1. The Separation of Baryonic Matter and Dark Matter Darkmatterhasbeendetectedonlyindirectlybymeansofitsgravitationaleffects astronomically.Darkmatterasweaklyinteractingmassiveparticles(WIMPs)hasnotbeen detecteddirectlyontheearth[44].Theprevioussectionproposesthattheabsenceofthe directdetectionofdarkmatterontheearthisduetotheincompatibilitybetweenbaryonic matteranddarkmatter,analogoustoincompatiblewaterandoil.Chapter2providesthe reasonsfortheincompatibilityandthemassratio(5to1)ofdarkmattertobaryonicmatter. Basically, duringtheinflation before the Big Bang, darkmatter,baryonic matter, cosmic radiation,andthegaugeforcefieldsaregenerated.Therearefivetypesofdarkmatterwith the“massdimensions’from5to9,whilebaryonicmatterhasthemassdimensionof4.As aresult,themassratiois5to1asobserved. Without electromagnetism, dark matter cannot emit light, and is incompatible to baryonic matter. Like oil, dark matter is completelynonpolar.Thecommonlinkbetweenbaryonicmatteranddarkmatteristhe cosmicradiationresultedfromtheannihilationofmatterandantimatterfrombothbaryonic matter and dark matter. The cosmic radiation is coupled strongly to baryonic matter throughtheelectromagnetism,andweaklytodarkmatterwithoutelectromagnetism.With thehighconcentrationofcosmicradiationatthebeginningoftheBigBang,baryonicmatter and dark matter are completely compatible. As the universe ages and expands, the concentrationofcosmicconcentrationdecreases,resultingintheincreasingincompatibility betweenbaryonicmatteranddarkmatteruntiltheincompatibilityreachestothemaximum valuewithlowconcentrationofcosmicradiation. The incompatibility is expressed in the form of the repulsive MOND (modified Newtoniandynamics)forcefield.MOND[45]proposesthedeviationfromtheNewtonian dynamics in the low acceleration region in the outer region of a galaxy. This paper proposestheMONDforcesintheinterfacebetweenthebaryonicmatterregionandthe dark matter region [46]. In the interface, the same matter materials attract as the conventional attractive MOND force, and the different matter materials repulse as the repulsiveMONDforcebetweenbaryonicmatteranddarkmatter.

40 Baryonicmatterregion(Newtonian regime) a>>a ,a=a Interface(MONDregime) 1/2 ai<<a 0,a i=(a Na0) Darkmatterregion(Newtonianregime) Figure9:theinterfacialregionbetweenthebaryonicandthedarkmatterregions InFigure9,theinnerpartisthebaryonicmatter region,themiddlepartisthe interface,andtheouterpartisthedarkmatterregion.TheMONDforcesintheinterface are the interfacial attractive force (conventional MOND force), F iA, among the same matter materials and the interfacial repulsive force (repulsive MOND force), F iR, between baryonic matter material and dark matter material. The interfacial repulsive forceenhancestheinterfacialattractiveforcetowardthecenterofgravityintermsofthe interfacialacceleration,a i. Theborderbetweenthebaryonicmatterregionandtheinterfaceisdefinedbythe accelerationconstant,a 0.Theinterfacialaccelerationislessthana 0.Theenhancement isexpressedasthesquarerootoftheproductofaianda 0.Inthebaryonicmatterregion, abisgreaterthana 0,andisequaltonormalNewtonianaccelerationasEq.(42).

a0 << ab, ab = aN in the baryonic matter region (42) a0 >> ai, ai = aN a0 in the int erfacial region

Theinterfacialattractiveforceintheinterfacewiththebaryonicmatterregionis expressedasEq.(43)wheremisthemassofbaryonicmaterialintheinterface.

Ｆ i− A = maN ａ ２ (43) = ｍ i , ａ０

The comparison of the interfacial attractive force, F iA, and the nonexisting interfacialNewtonianattractiveforce,F iNewton intheinterfaceisasEqs.(44),(45),and (46),whereGisthegravitationconstant,Misthemassofthebaryonicmaterial,andrthe distancebetweenthegravitationalcenterandthematerialintheinfacialregion.

41 GMm Ｆ = i− A r 2 ａ ２ = ｍ , ａ０ (44) GMm Ｆ = i− Newton r 2 = ｍ a

GMa0 ai = r (45) GM a = , i−Newron r 2

m GMa0 Fi−A = r (46) mGM F = , i−Newron r 2

The interfacial attractive force decays with r, while the interfacial Newtonian 2 forcedecayswithr .Therefore,intheinterfacewhena 0>>a i,withsufficientdarkmatter, the interfacial repulsive force, F iR, is the difference between the interfacial attractive forceandtheinterfacialNewtonianforceasEq.(47).

a0 >> ai , in the int erfacial region

Fi−R = Fi−A − Fi−Newton (47) GMa GM = m( 0 − ) r r 2 Thesameinterfacialattractiveforceandtheinterfacialrepulsiveforcealsooccur fordarkmatterintheoppositedirection.Thus,therepulsiveMONDforcefiledresults intheseparationofbaryonicmatteranddarkmatter. Theaccelerationconstant,a 0,representsthemaximumaccelerationconstantfor themaximumincompatibilitybetweenbaryonic matter and dark matter. The common link between baryonic matter and dark matter is cosmic radiation resulted from the annihilationofmatterandantimatterfrombothbaryonicmatteranddarkmatter.Withthe highconcentrationofcosmicradiationattheBigBang,baryonicmatteranddarkmatterare completely compatible. As the universe ages and expands, the concentration of cosmic concentrationdecreases,resultingintheincreasingincompatibilitybetweenbaryonicmatter anddarkmatter.Theincompatibilityreachesmaximumwhentheconcentrationofcosmic radiationbecomesistoolowforthecompatibilitybetweenbaryonicmatteranddarkmatter. Therefore,fortheearlyuniversebeforetheformationofgalaxywhentheconcentrationof cosmicradiationisstillhigh,thetimedependentEq.(42)isasEq.(48).

42

aN a0t ai = for t0 ≥ t , (48) t0 wheretistheageoftheuniverse,andt 0istheageoftheuniversetoreachthemaximum incompatibilitybetweenbaryonicmatteranddarkmatter. Thedistance,r 0,fromthecentertotheborderoftheinterfaceisasEq.(49).

0r = GM/a 0 (49)

Intheearlyuniverse,r 0decreaseswiththeageoftheuniverseasEq.(50).

GMt0 0r = (50) a 0t

Thedecreasesinr 0leadstotheincreaseintheinterfacewheretheinterfacialforcesexist. Theinterfacialforcesalsoincreasewithtime.

a0 >> ai , in the int erfacial region

Fi−R = Fi−A − Fi−Newton (51) GMa t / t GM = m( 0 0 − ) r r 2 To minimize the interface and the interfacial forces, the same matter materials increasingly come together to form the matter droplets separating from the different matter materials. The increasing formation of the matter droplets with increasing incompatibility is similar to the increasing formation of oil droplets with increasing incompatibilitybetweenoilandwater.Sincetherearemoredarkmattermaterialsthan baryonicmattermaterials,mostofthematterdropletsarebaryonicdropletssurrounded bydarkmattermaterials.Theearlyuniverseischaracterizedbytheincreasesinthesize and the number of the matter droplets due to the increasing incompatibility between baryonicmatteranddarkmatter. 4.2. The Formation of the Inhomogeneous Structures The Inflationary Universe scenario [47] provides possible solutions of the horizon,flatnessandformationofstructureproblems.Inthestandardinflationtheory, quantum fluctuations during the inflation are stretched exponentially so that they can become the seeds for the formation of inhomogeneous structure such as galaxies and galaxyclusters. This paper posits that the inhomogeneous structure comes from both quantum fluctuationduringtheinflationandtherepulsiveMONDforcebetweenbaryonicmatter

43 anddarkmatteraftertheinflation.Asmentionedintheprevioussection,theincreasing repulsive MOND force field with the increasing incompatibility in the early universe resultsintheincreaseinthesizeandnumberofthematterdroplets. For the first few hundred thousand years after the Big Bang (which took place about13.7billionyearsago),theuniversewasahot,murkymess,withnolightradiating out.Becausethereisnoresiduallightfromthatearlyepoch,scientistscan'tobserveany tracesofit.Butabout400,000yearsaftertheBigBang,temperaturesintheuniverse cooled,electronsandprotonsjoinedtoformneutralhydrogenastherecombination.The inhomogeneous structure as the baryonic droplets by the incompatibility between baryonic matter and dark matter is observed [48] as anisotropies in CMB (cosmic microwavebackground). Astheuniverseexpandedafterthetimeofrecombination,thedensityofcosmic radiationdecreases,andthesizeofthebaryonicdropletsincreasedwiththeincreasing incompatibility between baryonic matter and dark matter. The growth of the baryonic dropletbytheincreasingincompatibilityfromthecosmicexpansioncoincidedwiththe growthofthebaryonic dropletby gravitational instability from the cosmic expansion. Theformationofgalaxiesisthroughbothgravitationalinstabilityandtheincompatibility betweenbaryonicmatteranddarkmatter. Thepregalacticuniverseconsistedofthegrowingbaryonicdropletssurrounded bythedarkmatterhalos,whichconnectedamongoneanotherintheformoffilaments and voids. These dark matter domains later became the dark matter halos, and the baryonicdropletsbecamegalaxies,clusters,andsuperclusters. Whenthereweremanybaryonicdroplets,themergeramongthebaryonicdroplets becameanothermechanismtoincreasethedropletsizeandmass.Whenthreeormore homogeneousbaryonicdropletsmergedtogether,darkmatterwaslikelytrappedinthe mergeddroplet(C,D,E,andFinFig.10).Thedropletwithtrappeddarkmatterinsideis theheterogeneousbaryonicdroplet,whilethedropletwithouttrappeddarkmatterinside isthehomogeneousbaryonicdroplet. A B C D E F

Fig. 10 :thehomogeneousbaryonicdroplets(A,andB),andtheheterogeneousbaryonic droplets(C,D,E,andF) IntheheterogeneousdropletsC,D,E,andF,darkmatterwastrappedinthecoresof the baryonic droplets. Because of the prevalence of dark matter, almost all baryonic dropletsweretheheterogeneousdroplets.Therewerethedarkmattercore,thebaryonic mattershell,andthedarkmatterhaloaroundthebaryonicdroplet,resultingintworepulsive forces as the pressures between the dark matter core and the baryonic matter shell and betweenthebaryonicshellandthedarkmatterhalo.Intheequilibriumstate,theinternal pressure between the dark matter core and the baryonic matter shell was same as the externalpressurebetweenthebaryonicshellandthedarkmatterhalo.

44 Whenthetemperaturedroppedto~1000°K,somehydrogenatomsinthedroplet paired up to create the primordial molecular layers. Molecular hydrogen cooled the primordial molecular layers by emitting infrared radiation after collision with atomic hydrogen.Eventually,thetemperatureofthemolecularlayersdroppedtoaround200to 300°K,reducingthegaspressureandallowingthemolecularlayerstocontinuecontracting into gravitationally bound dense primordial molecular clouds. The diameters of the primordialcouldbeupto100lightyearswiththemassesofupto6millionsolarmasses. Mostofbaryonicdropletscontainedthousandsoftheprimordialmolecularclouds. Theformationoftheprimordialmolecularcloudscreatedthegapinthebaryonic matter shell. The gap allowed the dark matter in the dark matter core to leak out, resultinginatunnelbetweenthedarkmattercoreandtheexternaldarkmatterhalo.The continuous leaking of the dark matter expanded the tunnel. Consequently, the dark matterinthedarkmattercorerushedoutofthedarkmattercore,resultinginthe“Big Eruption”.Theejectionofthedarkmatterfromthedarkmattercorereducedtheinternal pressure between the dark matter core and the baryonic matter shell. The external pressurebetweenthebaryonicmattershellandthedarkmatterhalocausedthecollapse ofthebaryonicdroplet.Thecollapseofthebaryonicdropletislikethecollapseofa balloonastheair(asdarkmatter)movesouttheballoon. The collapse of the baryonic droplet forced the headon collisions of the primordialmolecularcloudsinthebaryonicmattershell.Inthecenterofthecollapsed baryonicdroplet,theheadoncollisionsoftheprimordialmolecularcloudsgeneratedthe shock wave as the turbulence in the collided primordial molecular clouds. The turbulence triggered the collapse of the core of the primordial cloud. The core fragmentedintomultiplestellarembryos,ineachaprotostarnucleatedandpulledingas. Withouttheheavyelementstodissipateheat,themassoftheprimordialprotostarwas 500 to 1,000 solar masses at about 200°K. The primordial protostar shrank in size, increasedindensity,andbecametheprimordialmassivestarwhennuclearfusionbegan initscore.Themassiveprimordialstarformationisasfollows. combinatio n incompatib le dark matter andbaryonic matter → homogeneou s baryonic droplets   →heterogene ous the cooling eruption , collapse , and collision baryonic droplet   → molecular clouds in baryonic matter shell    → nuclear fusion protostar   → massive primordial star The intense UV radiation from the high surface temperature of the massive primordial stars started the reionization effectively, and also triggered further star formation.Themassiveprimordialstarswereshortlived(fewmillionyearsold).The explosion of the massive primordial stars was the massive supernova that caused reionization and triggered star formation. The heavy elements generated during the primordial star formation scattered throughout the space. The dissipation of heat by heavyelementsallowedthenormalratherthanmassivestarformation.Withmanyways totriggerstarformation,therateofstarformationincreasedrapidly.TheBigEruption that initiated the star formation started to occur about 400 million years after the Big Bang,andthereionizationstartedtooccursoonafter.Therateofstarformationpeaked about2billionyearsaftertheBigBang[49]. Sincetheheadoncollisionofthemolecularcloudstookplaceatthecenterofthe collapsed baryonic droplet, the star formation started in the center of the collapsed

45 baryonic droplet. With other ways to trigger star formation, the star formation propagatedawayfromthecenter.Thestarformationstartedfromthecenterfromwhich thestarformationpropagated,sotheprimordialgalaxiesappearedtobesmallsurrounded bythelargehydrogenblobs.Thesurroundinglargehydrogenblobscorrespondstothe observedLymanalphablobsofLymanalpha(Lya)emissionbyhydrogen,whichhave been discovered in the vicinity of galaxies at early cosmic times. The amount of hydrogen in the blobs was also increased by the incoming abundant intergalactic hydrogen. The repulsive dark matter halos prevented the hydrogen gas inside from escapingfromthegalaxies.DijkstraandLoeb[50]positedthattheearlygalaxiesgrew quicklybythecoldaccretionmodefromtheobservedLymanalphablobs.Thegrowth bythemergerofgalaxieswastooslowfortheobservedfastgrowthoftheearlygalaxies. Iftherewassmalldarkmattercoreasintheheterogeneousbaryonicdroplet(Cin Figure 10), the Big Eruption took relatively short time to cause the collapse of the baryonicdroplet.Thechangeintheshapeofthebaryonicdropletafterthecollapsewas relativelyminor.Thecollapseresultsinelliptical shape in E 0 to E 7 elliptical galaxies, whoselengthsofmajoraxesareproportionaltotherelativesizesofthedarkmattercore. Becauseoftheshorttimeforthecollapseofthebaryonicdroplet,thestarformationby thecollapseoccurredquicklyatthecenter. ejectionofdarkmatter collapse Mostoftheprimordialstarsmergedtoformthesupermassivecenter,resultingin thequasargalaxies.Suchfirstquasargalaxiesthatoccurredasearlyasz=6.28were observedtohaveaboutthesamesizesastheMilkyWay[51].Thisformationofgalaxy follows the monolithic collapse model in which baryonic gas in galaxies collapses to formstarswithinaveryshortperiod,sotherearesmallnumbersofobservedyoungstars inellipticalgalaxies.Ellipticalgalaxiescontinuetogrowslowlyastheuniverseexpands. Ifthesizeofthedarkmattercoreismedium(DinFig.10),thecollapseofthe baryonicdropletcausedalargechangeinshape,resultingintherapidlyrotatingdiskas spiralgalaxy.The rapidly rotating disk underwent differential rotation with the increasingangularspeedstowardthecenter.Afterfewrotations,thestructureconsisted ofabunglewasformedandtheattachedspiralarmsasspiralgalaxyasFig.11. ejectionofdarkmatter collapse differentialrotation

Fig. 11: theformationofspiralgalaxy

46 Thespiralgalaxytooklongertimetoeruptandcollapsethantheellipticalgalaxy, sothestarformationwaslaterthanellipticalgalaxy.Becauseofthelargesizeofthedark matter core, the density of the primordial molecular clouds was lower than elliptical galaxy, so the rate of star formation in spiral galaxy is slower than elliptical galaxy. Duringthecollapseofthebaryonicdroplet,someprimordial molecular clouds moved awaytoformglobularclustersnearthemaingroupoftheprimordialmolecularclouds. Mostoftheprimordialmassivestarsmergedtoformthesupermassivecenter.Themerge ofspiralgalaxieswithcomparablesizesdestroysthediskshape,somostspiralgalaxies arenotmergedgalaxies. Whentwodarkmattercoresinsidefarapartfromeach other (E in Fig. 10) generatedtwoopeningsinoppositesidesofthedroplet,thedarkmattercouldejectfrom both openings. The two opening is equivalent to the overlapping of two ellipses, resultinginthethickmiddlepart,resultinginthestarformationinthethickmiddlepart andtheformationofbarredspiralgalaxy.Thedifferentialrotationissimilartothatof spiralgalaxyasFig.12. ejectionofdark matter collapse differentialrotation

Fig. 12 :theformationofbarredspiralgalaxy Asinnormalspiralgalaxy,thelengthofthespiralarmdependsonthesizeofthe darkmattercore.ThesmallestdarkmattercoreforbarredspiralgalaxybringsaboutSBa, andthelargestdarkmattercorebringsaboutSBd. Thestarsforminthelowdensity spiralarmsmuchlaterthaninthenucleus,sotheyaremanyyoungstarsinthespiralarms. In barred spiral galaxy, because of the larger dark matter core area than normal spiral galaxy,thestarformationoccurredlaterthannormalspiralgalaxy,andtherateofstar formationwasslowerthannormalspiralgalaxy. Ifthesizeofthedarkmattercorewaslarge(FinFig.10),theeruptionofthedark matterinthedarkmattercoreoccurredeasilyinmultipleplaces.Thebaryonicmatter shellbecamefragmented,resultinginirregulargalaxy.Theturbulencefromthecollapse ofthebaryonicdropletwasweak,andthedensityoftheprimordialmolecularcloudswas low,sotherateofstarformationwasslow.Thestarformationcontinuesinaslowrateup tothepresenttime. AttheendoftheBigEruption,vastmajorityofbaryonicmatterwasprimordial freebaryonicmatterresidedindarkmatteroutsideofthegalaxiesfromtheBigEruption. This free baryonic matter constituted the intergalactic medium (IGM). Stellar winds, supernovawinds,andquasarsprovideheatandheavyelementstotheIGMasionized baryonicatoms.TheheatpreventedtheformationofthebaryonicdropletintheIGM. Galaxiesmergedintonewlargegalaxies,suchasgiantellipticalgalaxyandcD galaxy(z>12).SimilartothetransientmolecularcloudformationfromtheISM(inter stellar medium) through turbulence, the tidal debris and turbulence from the mergers generatedthenumeroustransientmolecularregions,whichlocatedinabroadarea[52].

47 Theincompatibilitybetweenbaryonicmatteranddarkmattertransformedthesetransient molecularregionsintothestablesecondgenerationbaryonicdropletssurroundedbythe dark matter halos. The baryonic droplets had much higher fraction of hydrogen molecules, much lower fraction of dark matter, higher density, and lower temperature, andlowerentropythanthesurrounding. Duringthisperiod,theaccelerationconstantreachedtothemaximumvaluewith themaximumincompatibilitybetweenbaryonicmatteranddarkmatter.Thegrowthof thebaryonicdropletsdidnotdependontheincreasingincompatibility.Thegrowthof the baryonic droplets depended on the turbulences that carried IGM to the baryonic droplets. The rapid growth of the baryonic droplets drew large amount of the surroundingIGMinward,generatingtheIGMflowshownasthecoolingflow.TheIGM flowinducedthegalaxyflow.TheIGMflowandthe galaxy flow moved toward the mergedgalaxies,resultingintheprotocluster(z~0.5)withthemergedgalaxiesasthe clustercenter. Beforetheprotoclusterstage,spiralsgrewnormallyandpassivelybyabsorbing gasfromtheIGMastheuniverseexpanded.Duringtheprotoculsterstage(z~0.5),the massiveIGMflowinjectedalargeamountofgasintothespiralsthatjoinedinthegalaxy flow. Most of the injected hot gas passed through the spiral arms and settled in the bunglepartsofthespirals.SuchsurgesofgasabsorptionfromtheIGMflowresultedin majorstarbursts(z~0.4)[53].Meanwhile,thenearbybaryonicdropletscontinuedto drawtheIGM,andtheIGMflowandthegalaxyflowcontinued.Theresultswerethe formationofhighdensityregion,wherethegalaxiesandthebaryonicdropletscompeted fortheIGMasthegasreservoir.Eventually,thematurityofthebaryonicdropletscaused adecreaseindrawingtheIGMinward,resultingintheslowIGMflow.Subsequently, thedepletedgasreservoircouldnotsupportthemajorstarbursts(z~0.3).Thegalaxy harassment and the mergers in this highdensity region disrupted the spiral arms of spirals, resulting in S0 galaxies with indistinct spiral arms (z ~ 0.1 – 0.25). The transformationprocessofspiralsintoS0galaxiesstartedatthecorefirst,andmovedto theoutsideofthecore.Thus,thefractionofspiralsdecreaseswithdecreasingdistance fromtheclustercenter. The static and slowmoving secondgeneration baryonic droplets turned into dwarf elliptical galaxies and globular clusters. The fast moving secondgeneration baryonic droplets formed the secondgeneration baryonic stream, which underwent a differentialrotationtominimizetheinterfacialareabetweenthebaryonicmatteranddark matter.Theresultistheformationofbluecompactdwarfgalaxies(BCD),suchasNGC 2915withveryextendedspiralarms.Sincethestarformationissteadyandslow,sothe starsformedinBCDarenew. Thegalaxiesformedduringz<0.10.2aremostlymetalrichtidaldwarfgalaxies (TDG)fromtidaltailstornoutfrominteractinggalaxies.Insomecases,thetidaltailand thebaryonicdropletmergetogeneratethestarbursts with higher fraction of molecule thantheTDGformedbytidaltailalone[54]. When the interactions among large galaxies were mild, the mild turbulence causedtheformationoffewmolecularregions,whichlocatedinnarrowareaclosetothe largegalaxies.Suchfewmolecularregionsresultedinfewbaryonicdroplets,producing weakIGMflowandgalaxyflow.Theresultistheformationofgalaxygroup,suchasthe LocalGroup,whichhasfewerdwarfgalaxiesandlowerdensityenvironmentthancluster.

48 Clustersmergedtogeneratetidaldebrisandturbulence,producingthebaryonic droplets,theICM(intraclustermedium)flow,andtheclusterflow.TheICMflowand theclusterflowdirectedtowardthemergerareasamongclustersandparticularlytherich clusterswithhighnumbersofgalaxies.TheICMflowisshownasthewarmfilaments outsideofcluster[55].Thedominantstructuralelementsinsuperclustersaresingleor multibranchingfilaments[56].Theclusterflowisshownbythetendencyofthemajor axesofclusterstopointtowardneighboringclusters [57]. Eventually, the observable expandinguniversewillconsistofgiantvoidsandsuperclusterssurroundedbythedark matterhalos. Insummary,thewholeobservableexpandinguniverseisasoneunitofemulsion with incompatibility between baryonic matter and dark matter. The five periods of baryonic structure development are the free baryonic matter, the baryonic droplet, the galaxy,cluster,andthesuperclusterperiodsasFig.13.Thefirstgenerationgalaxiesare elliptical, normal spiral, barred spiral, and irregular galaxies. The secondgeneration galaxies are giant ellipticals, cD, evolved S0, dwarf ellipticals, BCD, and TDG. The universenowisintheearlypartofthesuperclusterperiod. clusterswith baryonic thefirst thesecond merge cosmic droplets Big generation merge baryonic generation galaxies r superclusters matter galaxies expansion free Eruption baryonic IGM ICM matter beginning pregalactic galaxy cluster superclusters

Fig. 13 :thefivelevelsofbaryonicstructureintheuniverse 4.3. Summary Theseparationofdarkmatterwithoutelectromagnetismandbaryonicmatterwith electromagnetisminvolvesMOND(modifiedNewtoniandynamics).Itisproposedthat the MOND force is in the interface between the baryonic matter region and the dark matter region. In the interface, the same matter materials attract as the conventional attractive MOND force, and the different matter materials repulse as the repulsive MOND force between baryonic matter and dark matter. The source of the repulsive MONDforcefieldistheincompatibilitybetweenbaryonicmatteranddarkmatter,like waterandoil.Theincompatibilitydoesnotallowthedirectdetectionofdarkmatter. Typically, dark matter halo surrounds baryonic galaxy. The repulsive MOND force between baryonic matter and dark matter enhances the attractive MOND force of baryonic matter in the interface toward the centerof gravity of baryonic matter. The enhancementofthelowaccelerationintheinterfaceisbytheaccelerationconstant,a 0, which defines the border of the interface and the factor of the enhancement. The enhancementofthelowgravityintheinterfaceis by the decrease of gravity with the distant rather than the square of distance as in the normal Newtonian gravity. The repulsiveMONDforceisthedifferencebetweentheattractiveMONDforceandthenon

49 existing interfacial Newtonian force. The repulsive MOND force field results in the separationandtherepulsiveforcebetweenbaryonicmatteranddarkmatter. TherepulsiveMONDforcefieldexplainstheevolution of the inhomogeneous baryonicstructuresintheuniverse.Bothbaryonicmatteranddarkmatterarecompatible with cosmic radiation, so in the early universe, the incompatibility between baryonic matteranddarkmatterincreaseswithdecreasingcosmicradiationandtheincreasingage oftheuniverseuntilreachingthemaximumincompatibility.TherepulsiveMONDforce field with the increasing incompatibility results in the growth of the baryonic matter droplets. The five stages of the formation of inhomogeneous structures are baryonic matter, baryonic droplets, the first generation galaxies by the Big Eruption, cluster, and supercluster. Thethreeperiodsforthebaryonicstructuredevelopmentintheearlyuniverseare thefreebaryonicmatter,thebaryonicdroplet, and the galaxy formation from the Big Eruption. The transition to the baryonic droplet generates density perturbation in the CMB. In the galaxy period, the firstgeneration galaxies including elliptical, normal spiral,barredspiral,andirregulargalaxiesweretheresultoftheBigEruptionfromthe inhomogeneousbaryonicdroplets. Afterreachingthemaximumincompatibility,thegrowthofthebaryonicdroplets dependsontheturbulence,resultinginthebaryonicstructuredevelopmentofthecluster and the supercluster. In the cluster period, the secondgeneration galaxies include modifiedgiantellipticals,cD,evolvedS0,dwarfelliptical,BCD,andtidaldwarfgalaxies. The whole observable expanding universe behaves as one unit of emulsion with incompatibilitybetweenbaryonicmatteranddarkmatterthroughtherepulsiveMOND forcefield.

50

5. The Extreme Force Field

5.1. The quantum space phase transitions for force fields

Underextremeconditionssuchastheabsolutezerotemperatureorextremelyhigh pressure, binary lattice space for a gauge force field undergoes a phase transition to becomebinarypartitionspacefortheextremeforcefields[5][7]. Atzerotemperatureorextremelyhighpressure,binarylatticespaceforagauge forcefieldundergoesaquantumspacephasetransitiontobecomebinarypartitionspace. In binary partition space, detachment space and attachment space are in two separate continuousregionsasfollows. k k ( 1 ) + ∑ (( 0 )( 1 )) ( 1 ) + ∑ ( 0 ) ( 1 ) 4 m 4 4 n, k 4 m 4 n,k 4 n,k k = 1  → k = 1 particle boson field extreme particle extreme boson field (52) in binary lattice space in binary partition space Theforcefieldinbinarylatticespaceisgaugebosonforcefield,theforcefieldin binarypartitionspaceisdenotedas“extremebosonforcefield”.Thedetachmentspace inextremebosonfieldisthevacuumcore,whileextremebosonsattachedtoattachment spaceformtheextremebosonshell.Gaugebosonforcefieldhasnoboundary,whilethe attachmentspaceinthebinarypartitionspaceactsastheboundaryfor extremeboson force field. Extreme boson field is like a bubble with core vacuum surrounded by membranewhereextremebosonslocate. The overlapping (connection) of two extreme bosons from two different sites resultsin“extremebond”.Theproductis“extrememolecule”.Anexampleofextreme moleculeisCooperpair,consistingoftwoelectronslinkedbyextremebond.Another exampleissuperfluid,consistingofmoleculeslinkedbyextremebonds.Extremebonds canbealsoformedamongthesitesinalattice,resulting in extreme lattice. Extreme lattice is superconductor. Extreme boson force is incompatible to gauge boson force field. The incompatibility of extreme boson force field and gauge boson force field manifestsintheMeissnereffect,wheresuperconductor(extremelattice)repelsexternal magnetism.Theenergy(stiffness)ofextremebosonforcefieldcanbedeterminedbythe penetration of boson force field into extreme boson force field as expressed by the LondonequationfortheMeissnereffect. ∇2H = − λ− 2H , (53) whereHisanexternalbosonfieldandλisthedepthofthepenetrationofmagnetisminto extreme boson shell. This equation indicates that the external boson field decays exponentiallyasitpenetrateintoextremebosonforcefield.

5.2. Superconductor and the Fractional Quantum Hall Eff ect

51 Extremebosonexistsonlyattheabsolutezerotemperature.However,quantum fluctuationatatemperatureclosetozerotemperatureallowstheformationofanextreme boson.Thetemperatureisthecriticaltemperature(T c).Suchtemperatureconstitutesthe quantum critical point (QCP) [ 58 ]. Extreme boson at QCP is the base of superconductivity. ThestandardtheoryfortheconventionallowtemperatureconductivityistheBCS theory. According to the theory, as one negatively charged electron passes by the positivelychargedionsinthelatticeofthesuperconductor,thelatticedistorts.Thisin turncausesphononstobeemittedwhichformsachannelofpositivechargesaroundthe electron.Thesecondelectronisdrawnintothechannel.Twoelectronslinkuptoform the"Cooperpair”withoutthenormalrepulsion. IntheextremebosonmodeloftheBCStheory,anextremebosoninsteadofa positivechargedphononisthelinkfortheCooperpair.Accordingtheextremeboson model,asanelectronpassesthelatticeofsuperconductor,latticeatomabsorbstheenergy ofthepassingelectrontocausealatticebondtostretchortocontract.Whenthelattice bondrecoilstonormalposition,thelatticeatomemitsaphonon,whichisabsorbedbythe electron.Theelectronthenemitsthephonon,whichisabsorbedbythenextlatticeatom tocauseitsbondtostretch.Whenthelatticebondrecoilstonormalposition,thelattice atomemitsaphonon,whichisabsorbedbytheelectron.Theresultisthecontinuous latticevibrationbytheexchangesofphononsbetween the electrons in electric current andthelatticeatomsinlattice. At the temperature close to the absolute zero temperature, the lattice vibration continuouslyproducesphonons,andthroughquantumfluctuation,acertainproportionof phononsconvertstoextremebosons.Extremebondsareformedamongextremebosons, resultinginextremelattice.Atthesametime,theelectronsinvolvedinlatticevibration formextrememoleculesasCooperpairslinkedbyextremebonds.Suchextremebond excludes electromagnetism, including the Coulomb repulsive force, between the two electrons. When Cooper pairs travel along the uninterrupted extreme bonds of an extremelattice,Cooperpairsexperiencenoresistancebyelectromagnetism,resultingin zero electric resistance. Extreme lattice repels external magnetism as in the Meissner effect. Theextremebosonsinvolvedintheformationoftheextremelatticebondsand theextrememolecularbondshavetheenergy,sotheextremebondenergy(E l) forthe extremelatticeissameastheextremebondenergy(E c)forCooperpair. E = E l c (54) = 2 0 Theextremebondenergycorrespondstotwotimestheenergygap tatzerotemperature intheBCStheory.Theenergygapisthesuperconductingenergythatanelectronhas. t approachestozerocontinuously astemperature approaches to T c. The elimination of superconductivityistobreaktheextremebondsoftheextremelatticeandCooperpairs. Extremebosonforceisaconfinedshortdistantforce,sotheneighboringextreme bosonshavetobeclosetogether.Tohaveacontinuousextremelatticewithoutgaps,itis necessarytohavesufficientdensityofthevibratinglatticeatoms.Thus,thereiscritical

52 density,D c,ofvibratinglatticeatoms.BelowD c,noextremelatticecanbeformed.Ina good conductor, an electron hardly interacts with lattice atoms to generate lattice vibration for extreme boson, so a good conductor whose density for vibrating lattice atoms below D cdoesnotbecome asuperconductor.T cisdirectly proportionaltothe densityofvibratinglatticeatomsandthefrequencyofthevibration(relatedtotheisotope mass). The“gap”inextremelatticeistheareawithoutvibratinglatticeatoms.Thegap allows electric resistance. Superconductor has “perfect extreme lattice” without significant gap, while “imperfect extreme lattice” has significant gap to prevent the occurrenceofsuperconductivity. Hightemperaturesuperconductorhasamuchhigher T c than low temperature superconductor described by the BCS theory. All high temperature superconductors involvetheparticulartypeofinsulatorwithvariouskindsofdopants.Atypicalinsulator isMottinsulator,suchascopperoxides,CuO 2. CuO 2formsatwodimensionallayer, withtheCuatomsformingasquarelatticeandOatomsbetweeneachnearestneighbor pairofCuatoms.IntheundopedCuO 2,alloftheplanarcoppersareintheCu2+state, withoneunpairedelectronpersite.Twoneighboringunpairedelectronswithantiparallel spinshavelowergroundenergythantwoneighboring unpaired electrons with parallel spins. Two neighboring unpaired electrons with antiparallel spins constitute the antiparallelspinpair,whichhaslower groundstate energy than the parallel spin pair. Consequently, CuO 2 layer consists of the antiparallel spin pairs, resulting in antiferromagnetism. The insulating character of this state is thought to result, not from the antiferromagnetismdirectly,butfromthestrongonsiteCoulombrepulsion,whichisthe energy cost of putting an extra electron on a Cu atom to make Cu 1+ . This Coulomb energyfordoubleoccupancysuppressesconduction. La xSr xCu 2O 4 isanexampleofhightemperatureconductor.Thekeyingredient consistsofCuO 2layers.ThedopingofSrprovideschemicalenvironmenttoshiftthe charge away from the CuO 2 layers, leaving “doping holes” in the CuO 2 layers. The shiftingofelectronsallowstheoccurrenceofelectriccurrent.InthetJmodelofhigh temperature superconductor, an electron in electric current is fractionalized into two fractionalelectronstocarryspinquantumnumberintandtocarrychargeinJ[59]. n n ~+ ~  r r i j  H = −t ∑c c + J ∑ S • S − , (55) ij iσ jσ  i j 4  ijσ ij Intheextremebosonmodel,tcorrespondstothespincurrent(spinon)togenerate spinfluctuationinthemetaloxidelayer,whileJcorresponds to the directional charge current(phononasintheBCStheory)alongthemetaloxidelayers.Extremebosonforce fieldisaconfinedforcefield.Aslongaselectronsareintheconfinedextremeboson force field, it is possible to have fractioanlized electrons, similar to the fractionalized chargesofquarksinthegluonforcefield. Thespinfluctuationgeneratedbythespincurrentinthelayercomesfromdoping holesinCuO 2layer.Whenanantiparallelspinpairlosesanelectronbydoping,adoping

53 holeisinthespinpair.Theadjacentelectronoutsideofthepairfillsinthehole.The filledinelectronhasaparallelspinastheelectronintheoriginalpair.Parallelspinpair hashighergroundstateenergythanantiparallelpair,sothefilledinelectronabsorbsa spinontogainenoughenergytoundergoaspinchange.Theresultistheformationofan antiparallelspinpair.Theantiparallelspinpairhaslowergroundstateenergythanan antiparallelspinpair,soitemitsaspinon.Aftertheelectronfillsthehole,theholepasses tothenextadjacentpair.Thenextadjacentpairthenbecomesthenextadjacentnewly formed parallel pair, which then absorbed the emitted spinon undergo spin change to formanantiparallelspinpair.Thecontinuouspassingofholesconstitutesthelayerspin current.ThelayerspincurrentthroughouttheCuO2layergeneratesthecontinuousspin fluctuation[60]withcontinuousemissionandabsorptionofspinons. At a low temperature, the spin fluctuation continuously produces spinons, and throughquantumfluctuation,acertainproportionofspinonsconvertstoextremebosons. Extremebondsareformedamongextremebosons.Theextremebondsaretheparallel extremebondsparalleltoCuO 2layer.Theparallelextremebondresultsfromthespin current. The extreme bonds connecting CuO 2 layers are the perpendicular bonds perpendicular to CuO 2 layers through dwave by the lattice vibration, like the lattice vibrationinthelowtemperaturesuperconductor.Theperpendicularbondresultsfrom the charge current. The perpendicular extreme bond energy (E ⊥) is greater than the parallel extreme bond energy (E II ). Cooper pairs as the charge pairs travel along the perpendicularbonds.Thus,Cooperpairhasthesamebondastheperpendicularextreme bond. The extreme lattice consists of both parallel extreme bonds and perpendicular extremebonds. E < E II ⊥ E = E , (56) c ⊥ E = E l II , ⊥ Perfect extreme lattice without gap of extreme bonds consists of both perfect parallelextremelatticeandperfectperpendicularextremelatticewithoutgapsforparallel extreme bonds and perpendicular bonds, respectively. The T c of high temperature superconductorthetransitiontemperaturetotheperfectextremelattice,consistingofthe perfect parallel extreme lattice and the perfect perpendicular lattice. Because many extremebosonsaregeneratedfrommanyspinfluctuations,T cishigh. Having stronger extreme bond, the T c ⊥ for the perpendicular extreme lattice is higherthantheT cII fortheparallelextremelattice.Thus,T cfortheextremelatticeis essentiallytheT cII fortheparallelextremelattice. T < T c II c ⊥ T = T , (57) c c II

54 There are five different phases of metal oxide related to the presence or the absenceofperfectparallellattice,perfectperpendicularextremelattice,andCooperpairs asfollows. Table 4. ThePhasesofMetalOxides Phase/structure perfectparallel perfectperpendicular Cooperpair extremelatticefor extremelatticefor spinons phonons Insulator no no no Pseudogap no yes yes Superconductor yes yes yes nonfermiliquid no no yes normalconductor no no no . Withoutdoping,metaloxideisaninsulator.Thepseudogapphasehasacertain amountofdoping.Withacertainamountofdoping,theperfectperpendicularextreme latticecanbeestablishedwiththepseudogaptransition temperature, T p, equal to T c ⊥. However,theparallellatticeisimperfectwithgaps,soitisnotasuperconductor.The pseudogapphasecanalsobeachievedbytheincreaseintemperatureaboveT ctocreate gap in the parallel extreme lattice, resulting in imperfect parallel extreme lattice. Different points in the pseudogap phase represent different degrees of the imperfect parallel extreme lattice. With the optimal doping, the pseudogap phase becomes the superconductorphasebelowT c.Superconductorhasperfectparallelextremelatticeand perfectperpendicularextremelattice.Withexcessivedoping,thesuperconductorphase becomestheconductorphasewithoutsignificantspinfluctuationandlatticevibration.In thenonfermiliquidregion,theextremelatticeisimperfectbythecombinationofthe moderate increase in temperature above T c and the moderate increase in doping. However,nonfermiliquidphasestillhasCooperpairsthatdonotrequirethepresenceof perfect extreme lattice. In the nonfermi liquid phase, due to the breaking of Cooper pairswiththeincreaseintemperature,thetransportpropertiesaretemperaturedependent, unlikenormalconductor. Insummary,foralowtemperaturesuperconductor,extremebosonsaregenerated by the quantum fluctuation in lattice vibration by the absorption and the emission of phononsbetweenpassingelectronsandlatticeatoms.Theconnectionofextremebosons results in extreme lattice and Cooper pairs. For a hightemperature superconductor, extremebosonsaregeneratedbythequantumfluctuationinspinfluctuationandlattice vibrationbytheabsorptionandtheemissionofspinonsandphonons,respectively.The extreme lattice consists of the parallel extreme bonds and the perpendicular extreme bonds.Becausemanyextremebosonsaregeneratedfrommanyspinfluctuations,T cis high. TheextremebosoncanalsoexplainthefractionalquantumHalleffect(FQHE) [61] [62]. In the FQHE, electrons travel on a twodimensional plane. In two dimensional systems, the electrons in the direction of the Hall effect are completely separate,sotheextremebondcannotbe formedbetween the electrons. However, an individual electron can have n extreme bosons from the quantum fluctuation of the

55 magnetic flux at a very low temperature, resultinginextremeatomthatconsistsofan electronandnextremebosonswithnextremebosonforcefields. Extremebosonforcefieldconsistsofacorevacuum surrounded by only one extremebosonshell.Anelectroncanbeinn ≥1extremebosonforcefields.Ifn=1,an electroninaextremebosonforcefielddelocalizestotheextremebosonshell,resultingin theprobabilitydistributioninboththecenterandthebosonshelldenotedastheextreme atomic orbital. (Unlike extreme boson force field, gauge boson force field can have infinitivenumberoforbitals.)Theprobabilitydistributionfactionalizestheelectroninto onefractionalelectronatthecenterandthe2pfractionalelectronintheextremeatomic orbital. Thus, the extreme atom (n = p = 1) has three fractional electrons, and each fractionalelectronhas–1/3charge.Forn>1,themultipleextremeforcefieldsarelike multipleseparatebubbleswithonefractionalelectronatthecenter.Forp=1andn=3, thetotalnumberoffractionalelectronsis7,andeachfractionalelectronhas1/7charge asfollows. ↑ ↑ ↑ ↓ ↑ ↓ ↓ Theformulasforthenumberoffractionalelectronsandfractionalchargeareas follows. number of fractional electrons = 2 pn + 1 , (58) electric charg e = − 2(/1 pn + )1 wheren=theextremeatomicorbitalnumberand2p=numberoffractionalelectronsper orbital.Thewavefunctionoftheextremeatomisasfollows.    2 p  Ψ =Φ ∑ ∏( Z − Z )  , (59) n  j k  n  j < k n where Φisforthefractionalelectronatthecenter,z j=x j–iy j,n=numberofextreme atomic orbital, and 2p = number of fractional electrons per orbital. For the integer quantumHalleffect,p=n=0.Eq.(59)isanelectroninoneormultipleextremeboson forcefields.Theprobabilitydistributionfactionalizestheelectronsintothekfractional electronatthecenter( Φ)andthe2pjfractionalelectronsintheextremeatomicorbital. InEq.(59),thejfractionalelectronintheextremeatomicorbitaltakesalooparoundthe k fractional electron at the center. One extreme boson force field can have only one extremeatomicorbital.Whentheelectronisinmultiplenextremebosonforcefields, therearenseparateextremeatomicorbitalswithdifferentsizes. Thiswavefunctionissameassameasthewavefunctionofthecompositefermion, whichconsistsofanelectronand2pfluxquanta[63].Inthecompositefermion, Φisthe

56 noninteractingelectronand2pisthenumberoffluxquanta.Thecompositefermionis theboundstateofanelectronand2pquantumvortices.Inthesameway,theextreme atomistheboundstateofafractionalelectronand2pnfractionalelectronsintheextreme atomic orbitals. The extreme atomic orbital can be also described by the Laughlin Jastrowfactorbycountingthecenteredfractionalelectronasapartoftheextremeatomic orbitalelectrons,resultinginoddnumberofquasiparticles. The extreme atoms provide the ground state for the Laudau level. Within the ground state, the extreme atom with higher n and p has higher energy and lower probability.DuringthegenerationoftheLandaulevels,thefractionalelectronscomeoff theextremeatomicorbitals.Themostfavorablewayistoremoveonefractionalelectron perextremeatomicorbitaltoprovidemoreroomfortheotherfractionalelectroninthe sameextremeatomicorbital.Forn=1,one1/3chargedelectroncomesoff.Forn=2, two1/5chargedelectronscomeoff.Theformulaisn/(2n+1)electricchargeas observed:1/3,2/5,3/7…[64].Thesecondseriesistheleftoverofthefirstseries:2/3, 3/5,4/7… 5.3. Gravastar and Supernova Blackholehasbeenastandardmodelforthecollapse of a supermassive star. Twoalternatesforblackholearegravastar[65][66]anddarkenergystar[67].Gravastar isasphericalvoidasBoseEinsteincondensatesurroundedbyanextremelydurableform of matter. For dark energy star, the massenergy of the nucleons under gravitational collapsecanbeconvertedtovacuumenergy.Thenegative pressure associated with a largevacuumenergypreventstheformationofsingularityandresultsinanexplosion. Thispaperproposesgravastarbasedonthestellarextremeforcefieldinagravastar. Underhighpressuretemperature,masslessparticlessuchasphotonareconverted intomassiveleptonpairssuchasmassivee+epairsinsidethestellarextremeforcefield inagravastar.Itissimilartothemassivee+epairproductionfromphotonproposedby Rakavy,Shaviv,andBarkat[68] high pressure − temperature photons  → massive lepton pairs in stellar extreme force field (60) The exclusion of gravity by the stellar extreme force field as in the Meissner effect prevents the gravitational collapse into singularity.Thecoreof gravastaristhelepton pairsstellarextremeforcefieldastheLSC.Theminimummassofastartohaveenough pressuretemperaturetogeneratetheLSCisbetween24and40solarmasses. Massivestarswiththemassgreaterthan8solarmassescanundergocorecollapse whennuclearfusionsuddenlybecomesunabletosustainthecoreagainstitsowngravity. Thecollapsemaycauseviolentexpulsionoftheouterlayersofthestarresultingina supernova.Theremnantsofsupernovaemaybeneutronstarsoragravastarswiththe LSC. Theresultsofthecollapsesofmassivestarsdependontheirmasses[69].Forthe starswithmassesbetween8and25solarmasses,theremnantsofsupernovaeareneutron stars.Forthestarswithmassesbetween24and40solarmasses,theremnantscanbe neutronstarsorgravastarswiththeLSCdepending on the metallicity. Therefore, the

57 minimum mass of a star to have enough pressuretemperature to generate the LSC is between24and40solarmasses.Forthestarswiththemassesbetween40and100solar masses,theremnantsaregravastarswiththeLSC. For the stars with masses between 100 and 130 solar masses, there is enough pressureandtemperaturetoformtheLSCbeforethecollapse.TheformationoftheLSC withreducedvolumeandpressurethantheoriginalphotoncausedthepartialcollapseof thestar.Theresultispartialejectionsofpartsoftheouterlayersofthestaruntilits remainingcoreissmallenoughtocollapseinanormalsupernovawithgravastarsasthe remnants. Forthestarsbetween130and250solarmasses,theformationoftheLSCbefore thecollapseisstrongenoughintermsofreducedsizeandpressuretocauseaviolenttotal collapseofthestars,resultinginathermonuclearexplosionwithmuchgreaterbrightness thanthenormalsupernovae[70].Withmorethermal energy released than the stars' gravitational binding energy, the star is completely disrupted; no gravastar or other remnantisleftbehind.(TheouterlayeroutsideoftheLSCishigh,sothecollapsing energyfromthehighouterlayeroutsideoftheLSCisenoughtodestroytheLSC.) Forthestarsgreaterthan250solarmasses,theendothermic(energyabsorbing) reaction from extremely high gravity causes the stars to continue collapse into a gravastarswiththeLSCwithoutexplodingduetothermonuclearreactions. 5.4 Summary

Under extreme conditions, such as the zero temperature and extremely high pressure,theextremeforcefieldsasextremebosonforcefieldsform.Theformationof theextrememolecule(theCooperpair)andtheextremelatticeprovidesthemechanism forthephasetransitiontosuperconductivity,whiletheformationofextremeatomwith electronextremebosonprovidesthemechanismforthephasetransitiontothefractional quantumHalleffect.Theformationofthestellarextremeforcefieldinacollapsingstar prevents singularity as in black hole, resulting in the formation of gravastar without singularityandwiththeleptonpairsstellarextremeforcefieldcore.

58 6. Summary

Throughthezeroenergyuniverseandthespaceobjectstructures,theunifiedtheory ofphysicsisthetheoryofeverythingtoexplainfullycosmology,darkenergy,darkmatter, baryonicmatter,quantummechanics,elementaryparticles,forcefields,galaxyformation, and unusual extreme forces. In the unified theory, different universes (zero energy, membrane,string,>4Dparticle,and4Dparticleuniverses)indifferentdevelopmentalstages arethedifferentexpressionsofthespaceobjectstructures.Theunifiedtheoryisdivided into five parts: (1) the spaceobject structures, (2) cosmology, (3) the periodic table of elementaryparticles,(4)thegalaxyformation,and(5)theextremeforcefield. (1)Theunifiedtheoryisbasedonthespaceobjectstructures.Thespacestructure includesattachmentspaceanddetachmentspace.Relatingtorestmass,attachmentspace attachestoobjectpermanentlywithzerospeed.Relatingtokineticenergy,detachment space detaches from the object at the speed of light. The Higgs boson mediates the transformationbetweenthesetwospacestructures.Thecombinationofattachmentspace anddetachmentspacebringsaboutthreedifferentspacestructures:misciblespace,binary latticespace,andbinarypartitionspaceforspecialrelativity,quantummechanics,andthe extremeforcefields,respectively.Theobjectstructureconsistsof11Dmembrane(3 11 ), 10D string (2 10 ), variable D particle (1 4 to 10 ), and empty object (0 4 to 11 ). The transformationamongtheobjectsisthroughthedimensionaloscillationthatinvolvesthe oscillation between high dimensional spacetime with high vacuum energy and low dimensionalspacetimewithlowvacuumenergy.Ourobservableuniversewith4Dspace timehaszerovacuumenergy.Differentuniversesindifferentdevelopmentalstagesarethe differentexpressionsofthespaceobjectstructures.(2)Fromthezeroenergyuniverse,our universe starts with the 11dimensional membrane dual universe followed by the 10 dimensionalstringdualuniverseandthenbythe10dimensionalparticledualuniverse,and ends with the asymmetrical dual universe with variable dimensional particle and 4 dimensional particles. This 4stage process goes on in repetitive cycles. Such 4stage cosmology accounts for the origins of the four force fields. The theoretical calculated percentages of dark energy, dark matter, and baryonicmatterare72.8.22.7,and4.53, respectively, in agreement with observed value. According to the calculation, dark energy started in 4.47 billion years ago in agreement with the observed 4.71 ± 0.98 billionyearsago.(3)Theunifiedtheoryplacesallelementaryparticlesintheperiodictable of elementary particles with the calculated masses in good agreement with the observed valuesbyusingonlyfourknownconstants:thenumberoftheextraspatialdimensionsinthe elevendimensional membrane, the mass of electron, the mass of Z boson, and the fine structureconstant.TheLHCHiggsbosonistheSMHiggsbosonwiththehiddenlepton condensate. (4) The inhomogeneous structures, such as galaxy, are derived from the incompatibilitybetweenbaryonicmatteranddarkmatter,liketheinhomogeneousstructure formedbytheincompatibilitybetweenoilandwater.Cosmicradiationallowsdarkmatter andbaryonicmattertobecompatible.Astheuniverseexpanded,thedecreasingdensityof cosmic radiation increased the incompatibility, resulting in increasing inhomogeneous structures. The five stages of the formation of inhomogeneous structures are baryonic matter, baryonic droplets, the first generation galaxies by the Big Eruption, cluster, and supercluster.TheBigEruptionexplainstheoriginofdifferenttypesofgalaxies.(5)Under extremeconditions,suchasthezerotemperatureandextremelyhighpressuretemperature,

59 gaugebosonforcefieldundergoesthephasetransitiontoformextremeforcefield.Extreme force field explains unusual phenomena such as superconductor, fractional quantum Hall effect,supernova,andgravastar.

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