DOCSLIB.ORG

Subjectindex.Pdf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Subjectindex.Pdf Sub ject Index , 689 a meson, 563 0 , 775 a meson, two-photon width, 565 M 0 { plane, 724 accelerating waveguides, 809 M , 775 accelerators, future, 798, 806, 816 (QED coupling), 168, 369, 402 acoustic p eak in CMB anisotrophy sp ec- (QCD coupling), 167, 368, 484, 486, trum, 773 s 621, 623, 625 active galactic nuclei, 744, 749 , in hard di raction, 496 aerogel Cherenkov detector, 17 0 =, 104, 120, 126, 128, 132, 147, 178, AGASA, 747, 756 197, 198, 449, 855 age of the universe, 727 0 = theoretical predictions, 128 air shower detectors, 752, 756 , 178{180, 182, 186 ALEPH, 58, 59, 61, 70, 84, 98, 165{ K ! meson, 569 167, 307, 314, 320, 323, 355, 0 0 ! meson, decay to , 567 360, 420, 423, 424, 429, 433, 435, 542, 583 MS renormalization scheme, 398, 401, 404, 634 Alpha Magnetic Sp ectrometer, 755 0 meson, decay to , 565 Alternating GradientSynchrotron (AGS), 0 142, 391 meson, decay to , 562 + AMANDA, 758 meson, decay to , 563 0 0 Ambrosanio, S., 801 meson, decay to , 562 meson, decay to a , 558, 562 anomalous ionization tracks, 448 0 anomalous magnetic moment, 168 meson, decay to f , 558, 562 0 0 0 anomaly mediated sup ersymmetry break- meson, decay to , 567 ing, 447 parameter, 401 8 ANTARES, 758 B sp ectrum, 291 Arkani-Hamed, N., 789 e scattering, 539 + ASSET, 811 e e ! K K , 374 S L + + asymmetric B -factories, 12, 22, 855 e e ! , 375 + + asymptotic freedom, 167 e e ! ! , 375 + + e e ! , 375 ATF damping ring, 813 + + + e e ! , 373 ATLAS, 868 + + 0 atmospheric Cherenkov telescop es, 752 e e ! , 568 + + 0 0 atmospheric neutrinos, 201, 285, 698, e e ! ,373 2 ! 4tree amplitudes, 635 861 2-lo op virtual correction, 636 atmospheric neutrinos, avor ratio, 231 atmospheric neutrinos, zenith angle dis- 3-lo op, 634 tribution, 233, 236, 238 4-lo op order, 634 Auger Pro ject, 756, 871 4-quark mo del (q qqq ), 558, 565 917 b eam-driven plasma accelerators, 833 axial charge, 532 BELLE, 15 axions, 697 BEPC, 371 B Lifetime Working Group, 84 Bepp o/SAX satellite, 742 B meson, 657 BES, 378, 388 0 B meson, decay to K , 67 BES II, 371 + B meson, decay to ! , 67 BFKL equation, 495, 611, 642 B meson, decay to =` , 61 Bjorken sum rule, 531 + B meson, decay to , 63 blackholeentropy, 846 0 + B meson, decay to h , 65 black holes, 696, 845 B meson, decay to D ` ,59 Blair, G., 801 + 0 B meson, decay to h , 64 blazar, 744, 745 0 B meson, decay to J= K , 97 Bo omerang, 770 S 0 B meson, decay to J= K , 43 Bo oNE, 265, 266, 281 S + B meson, decay to K=K , 71 Borexino, 211, 223, 864 B meson, decay to K, 98 Bose-Einstein correlations, 360, 597 0 + B meson, decay to K h ,64 b ottom hadrons, lifetimes, 84 B meson, decay to K , 63 b ottom quark, decay to s ,62 B meson, decay to PV , 66 b ottom quark, fragmentation function, B meson, decay to X ,70 593 s + B meson, decay to , 98 b ottom quark, Higgs-strahlung, 432 B meson, hadropro duction, 619 b ottom quark, mass, 641 B meson, mixing, 44, 90{92, 175, 176, b ottom quark, Z asymmetry, 406 181, 184, 188, 194, 657 box diagrams, 86, 145 B meson, mixing, 49, 93, 182 s brane theory, 876 B meson, oscillation amplitude, 93 s Budker Institute, 388 B-factories, 3, 12, 22, 35, 449, 657 C parameter, 637 b-tagging, 430 C-band klystron, 811 BaBar detector, 25 Cabibb o-Kobayashi-Maskawa, 284 BAIKAL, 758 CANGAROO, 752 Baksan-USC-PNL, 702, 707 Carena, M., 800 ballo on-b orne sp ectrometer, 251 CAT, 752 Barger, V., 803 CCD detectors, 733, 742 baryogenesis, 183{185, 194, 196, 410, 442, 456 CDF, 43, 71, 84, 98, 335{343, 348, 349, 351, 419, 607, 608, 619 baryon X (2000), 571 CDF detector upgrade, 47 baryon density, 689 0 CDMS, 687, 704, 705 baryon yields, in Z decay, 584 CELESTE, 753 BATSE, 742 CERN SPS, 122 b eam crossing angle, 13 cesium dio dide calorimeter, 28 b eam instabilities, 12 918 CLIC, 788, 806, 819 CESR, 4 clover quark action, 663 charged current cross section, 344, 479 charged current scattering, 477 cluster mo del, 580 charged Higgs b oson, 434 CMB anisotropy sp ectrum, 765, 767 charged lepton asymmetry, 341 CMB p olarization, 772 charged massive particles, 696 CMD-2, 372, 376, 559, 562, 563 chargino, 420 CMS, 868 charm quark, multiplicity in B decay, COBE, 690 58 color reconnection, 360, 367 charm quark, photopro duction, 548 Compton Gamma Ray Observatory,742 charm quark, structure function, 482, con nement, 658 485 continuum limit, 658 charmless two-b o dy B decays, 62 cosmic microwavebackground, 690, 727, Cherenkov detector, 25, 32, 231 746, 765, 871 Cherenkov telescop es, 753 cosmic rays, 741 chiral p erturbation theory, 664 cosmic rays, atmospheric ux, 251 CHOOZ, 243, 249, 285, 862 cosmic rays, energy sp ectrum, 229, 251, CHORUS, 267{269, 271, 281 747 CKM exp eriment, 150 cosmic rays, extremely high energy, 746 CKM matrix, 98 cosmic strings, 750 CKM matrix V ,176 cosmological constant, 727, 844 CKM CKM matrix V , 176{180, 182, 184{ cosmological parameters, 770 CKM 188, 190, 194, 197 CP violation, 3, 12, 20, 35, 43, 96, 104, CKM matrix V , 53, 72, 145, 357, 120, 132, 177{179, 183{185, 187, CKM 657 188, 191, 195, 196, 657, 855 CKM parameter ,153 CP violation parameter sin 2 , 48 CKM parameter V , 58, 176, 180{182, CP violation parameter sin 2 , 43, 45, cb 187, 189, 191, 192, 194 98 CKM parameter V , 357 CP-PACS, 658 cs CKM parameter V , 145, 149 CPT violation, 132 td CKM parameter V ,145,149 crab cavity, 13 ts CKM parameter V , 60, 176{178, 181, Crab Nebula, 744, 748 ub 182, 187, 190{194, 196 CRESST, 704 CKM parameter V ,90 cryogenic WIMP detector, 703 td CKM unitarity,90 CsI calorimeter, 5, 18, 105 Cl-Ar Exp eriment, 287 cumulative instability,810 CLEO, 59, 61, 63, 65, 69, 70, 72, 73, current fragmentation in DIS, 593 89, 98, 165, 166 curvature of space, 728, 766 CLEO II, 54 cylindrical drift chamber, 137 CLEO I I.V, 54 D meson lifetimes, 80 CLEO III, 5 919 DONUT, 164, 244 D meson mixing, 88 double b eta decay, 297 D meson, semi-leptonic decays, 74 D-branes, 843 double p omeron exchange, 627 D0, 71, 607, 608, 619 doubly Cabibb o-suppressed decay, 88 D0 detector upgrade, 46 Dvali, G., 789 DANE, 133, 371 DW quark action, 663 DAMA, 687, 702 dynamic fo cusing, 820 DAMA mo dulation signal, 702, 705 E150, 834 dark energy, 734, 775 E154, 523 dark matter, 687 E155, 523 dark matter, at large scales, 688 E155x, 533 dark matter, baryonic, 687, 691 E157, 834 dark matter, in galaxies, 687 E687, 74 dark matter, in galaxy clusters, 688, E706, 616 690 E731, 128 dark matter, non-baryonic, 687, 690 E776, 285 Davis, R., 857 E787, 146, 149 decay constants, 657 E791, 74, 82, 89 deep inelastic scattering, 467, 473 E821, 390 deeply virtual Compton scattering, 512, E865, 141, 143 647 E866, 481 DELPHI, 57{59, 61, 307, 314, 320, 323, E871, 141, 147 355, 360, 423, 429, 433, 435, E926, 151 583, 587, 590, 597 E949, 150 density of the universe, , 774 earth core, 229, 249 DGLAP parton evolution, 579, 636, 643 earth mantle, 229, 250 di ractive parton distributions, 499 east-west anisotropy, 251 di ractive parton densities, 501 EDELWEISS, 704 di ractive scattering, 496 e ective eld theory, 175 di ractive structure function, 497 e ective Hamiltonian, 160 dijet cross section, 613 EGRET, 752 dijet pro duction, 608 electron-p ositron linear collider, 869 dimensional regularization, 634 electroweak p enguin decay, 62 Dimop oulos, S., 789 electroweak symmetry breaking, 335 DIRBE, 696 Ellis-Ja e sum rule, 532 direct CP violation, 64, 97, 104, 120, EROS, 694 140 event shap e variables, 637 direct observation of , 164 excited W b osons, 409 direct photon pro duction, 613 exclusive B decays, 647 direct pro cesses (in collisions), 539 exotic fermions, 417 DLDS, 812 920 Generalized Vector Meson Dominance, external W-emission, 63 471 external electroweak p enguin, 63 extra spatial dimensions, 428, 450, 789 GENIUS, 702 geomagnetic cuto , 229, 251 f meson coupling, 563 0 germanium WIMP detector, 701 f meson mass, 563 0 GF11, 658 f meson width, 563 0 GLAST, 754, 871 Feldman-Cousins metho d, 241 gluon, 657 Fermi coupling constant, 157 gluon jets, 587 Fermi-Dirac anticorrelation, 597 gluon jets, multiplicity,592 fermion mass matrices, 442 gluon parton distribution, 484, 608 fermion-pair pro duction, 353 gluonic p enguin, 63 fermiophobic Higgs b oson, 434 Go o d, M. L., 495 b er tracker, 46 Grand Uni ed Theories, 409, 750 Final Fo cus Test Beam, 813 gravitational lens, 688 reball mo del of gamma ray bursts, 743 gravitino, 425 rst level trigger, 39 graviton, 428 rst momentof g , 528 1 graviton pro duction, 457 at universe, 773 gravity mediated sup ersymmetry break- avor changing neutral currents, 407 ing, 444 avor changing neutrino interactions, 256 Greisen cuto , 746 avor symmetries, 455 Grib ov, V. N., 495 Fly's Eye, 747 gyromagnetic ratio, 386 FOCUS, 82 form factors, 657 H1, 344, 469, 473, 479, 483, 484, 546, four fermion contact interactions, 416 552, 593, 613, 620 fragmentation, 577 + hadron pro duction in e e , 368, 380 fragmentation function, 578 hadronization, 577 + fragmentation in W W events, 599 hard di raction, 627, 644 hard di ractiveDIS, 645 galactic rotation, 688 Hawking radiation, 750 GALLEX, 205, 287, 857 heavy avor pro duction, 619 gamma ray astronomy,744 Heavy Quark E ective Theory, 55 gamma ray bursts, 742 heavy quark limit, 648 gamma ray telescop es, 752 heavy quark symmetry, 672 gamma-gamma collider, 820 heavy-light mesons, 657 gas electron multiplier (GEM), 37 HEGRA, 752 gauge mediated sup ersymmetry break- Heidelb erg-Moscow group, 701 ing, 425, 445 Heisenb erg, W., 797 gauge-coupling uni cation, 455 helioseismology,202 Geer, S., 802 hep neutrinos, 290 general
Load more

Recommended publications
  • Gravitino Dark Matter
    GRAVITINO DARK MATTER Wilfried Buchm¨uller DESY, Hamburg LAUNCH09, Nov. 2009, MPK Heidelberg Why Gravitino Dark Matter? Supergravity predicts the gravitino, analog of W and Z bosons in electroweak theory; may be LSP, natural DM candidate: m < 1keV, hot DM, (Pagels, Primack ’81) • 3/2 1keV < m3/2 < 15keV, warm DM, (Gorbunov, Khmelnitsky, Rubakov ’08) • ∼ ∼ 100keV < m < 10MeV, cold DM, gauge mediation and thermal • 3/2 leptogenesis∼ (Fuji, Ibe,∼ Yanagida ’03); recently proven to be correct by F-theory (Heckman, Tavanfar, Vafa ’08) 10GeV < m < 1TeV, cold DM, gaugino/gravity mediation and • 3/2 thermal leptogenesis∼ ∼ (Bolz, WB, Pl¨umacher ’98) Baryogenesis, (gravitino) DM and primordial nucleosynthesis (BBN) strongly correlated in cosmological history. 1 Gravitino Problem Thermally produced gravitino number density grows with reheating temperature after inflation (Khlopov, Linde ’83; Ellis, Kim, Nanopoulos ’84;...), n3/2 α3 2 TR. nγ ∝ Mp For unstable gravitinos, nucleosynthesis implies stringent upper bound on reheating temperature TR (Kawasaki, Kohri, Moroi ’05; ...), T < (1) 105 GeV, R O × hence standard mSUGRA with neutralino LSP incompatible with baryogenesis via thermal leptogenesis where T 1010 GeV !! R ∼ Possible way out: Gravitino LSP, explains dark matter! 2 Gravitino Virtue Can one understand the amount of dark matter, ΩDM 0.23, with Ω = ρ /ρ , if gravitinos are dominant component, i.e. Ω≃ Ω ? DM DM c DM ≃ 3/2 Production mechanisms: (i) WIMP decays, i.e., ‘Super-WIMPs’ (Covi, Kim, Roszkowski ’99; Feng, Rajaraman, Takayama ’03), m3/2 Ω3/2 = ΩNLSP , mNLSP independent of initial temperature TR (!), but inconsistent with BBN constraints; (ii) Thermal production, from 2 2 QCD processes, → 2 TR 100GeV mg˜(µ) Ω3/2h 0.5 10 .
    [Show full text]
  • Super-Higgs in Superspace
    Article Super-Higgs in Superspace Gianni Tallarita 1,* and Moritz McGarrie 2 1 Departamento de Ciencias, Facultad de Artes Liberales, Universidad Adolfo Ibáñez, Santiago 7941169, Chile 2 Deutsches Elektronen-Synchrotron, DESY, Notkestrasse 85, 22607 Hamburg, Germany; [email protected] * Correspondence: [email protected] or [email protected] Received: 1 April 2019; Accepted: 10 June 2019; Published: 14 June 2019 Abstract: We determine the effective gravitational couplings in superspace whose components reproduce the supergravity Higgs effect for the constrained Goldstino multiplet. It reproduces the known Gravitino sector while constraining the off-shell completion. We show that these couplings arise by computing them as quantum corrections. This may be useful for phenomenological studies and model-building. We give an example of its application to multiple Goldstini. Keywords: supersymmetry; Goldstino; superspace 1. Introduction The spontaneous breakdown of global supersymmetry generates a massless Goldstino [1,2], which is well described by the Akulov-Volkov (A-V) effective action [3]. When supersymmetry is made local, the Gravitino “eats” the Goldstino of the A-V action to become massive: The super-Higgs mechanism [4,5]. In terms of superfields, the constrained Goldstino multiplet FNL [6–12] is equivalent to the A-V formulation (see also [13–17]). It is, therefore, natural to extend the description of supergravity with this multiplet, in superspace, to one that can reproduce the super-Higgs mechanism. In this paper we address two issues—first we demonstrate how the Gravitino, Goldstino, and multiple Goldstini obtain a mass. Secondly, by using the Spurion analysis, we write down the most minimal set of new terms in superspace that incorporate both supergravity and the Goldstino multiplet in order to reproduce the super-Higgs mechanism of [5,18] at lowest order in M¯ Pl.
    [Show full text]
  • Gravitino Dark Matter with Constraints from Higgs Boson Mass …
    Vol. 44 (2013) ACTA PHYSICA POLONICA B No 11 GRAVITINO DARK MATTER WITH CONSTRAINTS FROM HIGGS BOSON MASS AND SNEUTRINO DECAYS∗ L. Roszkowskiy, S. Trojanowski National Centre for Nuclear Research, Hoża 69, 00-681, Warszawa, Poland K. Turzyński Institute of Theoretical Physics, Faculty of Physics, University of Warsaw Hoża 69, 00-681, Warszawa, Poland K. Jedamzik Laboratoire de Physique Theorique et Astroparticules, UMR5207-CRNS Université Montpellier II, 34095 Montpellier, France (Received October 21, 2013) We investigate gravitino dark matter produced thermally at high tem- peratures and in decays of a long-lived sneutrino in the framework of the Non-Universal Higgs Model (NUHM). We apply relevant collider and cos- mological bounds. Generally, we find allowed values of the reheating tem- 9 perature TR below 10 GeV, i.e. somewhat smaller than the values needed for thermal leptogenesis, even with a conservative lower bound of 122 GeV on the Higgs boson mass. Requiring mass values closer to 126 GeV implies 7 TR below 10 GeV and the gravitino mass less than 10 GeV. DOI:10.5506/APhysPolB.44.2367 PACS numbers: 14.80.Ly, 14.80.Da, 95.35.+d, 26.35.+c Gravitino as the lightest supersymmetric particle is a well-motivated dark matter (DM) candidate. It is extremely weakly interacting and hence can escape detection in direct searches. Scenarios with gravitino DM can be, however, strongly constrained by the Big Bang Nucleosynthesis (BBN). ∗ Presented at the XXXVII International Conference of Theoretical Physics “Matter to the Deepest” Ustroń, Poland, September 1–6, 2013. y On leave of absence from the University of Sheffield, UK.
    [Show full text]
  • Elementary Particle Physics from Theory to Experiment
    Elementary Particle Physics From Theory to Experiment Carlos Wagner Physics Department, EFI and KICP, Univ. of Chicago HEP Division, Argonne National Laboratory Society of Physics Students, Univ. of Chicago, Nov. 10, 2014 Particle Physics studies the smallest pieces of matter, 1 1/10.000 1/100.000 1/100.000.000 and their interactions. Friday, November 2, 2012 Forces and Particles in Nature Gravitational Force Electromagnetic Force Attractive force between 2 massive objects: Attracts particles of opposite charge k e e F = 1 2 d2 1 G = 2 MPl Forces within atoms and between atoms Proportional to product of masses + and - charges bind together Strong Force and screen each other Assumes interaction over a distance d ==> comes from properties of spaceAtoms and timeare made fromElectrons protons, interact with protons via quantum neutrons and electrons. Strong nuclear forceof binds e.m. energy together : the photons protons and neutrons to form atoms nuclei Strong nuclear force binds! togethers! =1 m! = 0 protons and neutrons to form nuclei protonD. I. S. of uuelectronsd formedwith Modeled protons by threeor by neutrons a theoryquarks, based bound on together Is very weak unless one ofneutron theat masses high energies is huge,udd shows by thatthe U(1)gluons gauge of thesymmetry strong interactions like the earth protons and neutrons SU (3) c are not fundamental Friday,p November! u u d 2, 2012 formed by three quarks, bound together by n ! u d d the gluons of the strong interactions Modeled by a theory based on SU ( 3 ) C gauge symmetry we see no free quarks Very strong at large distances confinement " in nature ! Weak Force Force Mediating particle transformations Observation of Beta decay demands a novel interaction Weak Force Short range forces exist only inside the protons 2 and neutrons, with massive force carriers: gauge bosons ! W and Z " MW d FW ! e / d Similar transformations explain the non-observation of heavier elementary particles in our everyday experience.
    [Show full text]
  • Constraints on the Mass of the Superlight Gravitino from the Muon Anomaly
    CORE Metadata, citation and similar papers at core.ac.uk Provided by CERN Document Server UAB–FT–416 Constraints on the mass of the superlight gravitino from the muon anomaly F.Ferrer and J.A.Grifols Grup de F´ısica Te`orica and Institut de F´ısica d’Altes Energies, Universitat Aut`onoma de Barcelona, E–08193 Bellaterra, Barcelona, Spain (April 1997) Abstract We reexamine the limits on the gravitino mass supplied by the muon anomaly in the frame of supergravity models with a superlight gravitino and a su- perlight scalar S and a superlight pseudoscalar P . PACS number(s): 14.80.Ly, 13.40.Em, 04.65.+e, 12.60.Jv Typeset using REVTEX 1 In a wide class of supergravity models with SUSY breaking scale in the TeV range, 2 the gravitino can be very light (m3/2 ∼ MSUSY /MPl). In fact, its mass could lie anywhere between µeV and keV . Examples for this are those models where gauge interactions mediate the breakdown of supersymmetry [1] or models where an anomalous U(1) gauge symmetry induces SUSY breaking [2]. Also, no–scale models can accomodate superlight gravitinos [3]. Clearly, it is important to bound and eventually determine the mass of the gravitino. To mention only an instance where the gravitino mass is of great physical significance, let us recall that a mass on the order of a few keV can be relevant for the dark matter problem. The sources of direct (laboratory) information on the gravitino mass are rare [4–7] and perhaps the best one comes from the (g − 2)µ of the muon [6,7].
    [Show full text]
  • General Neutralino NLSP with Gravitino Dark Matter Vs. Big Bang Nucleosynthesis
    General Neutralino NLSP with Gravitino Dark Matter vs. Big Bang Nucleosynthesis II. Institut fur¨ Theoretische Physik, Universit¨at Hamburg Deutsches Elektronen-Synchrotron DESY, Theory Group Diplomarbeit zur Erlangung des akademischen Grades Diplom-Physiker (diploma thesis - with correction) Verfasser: Jasper Hasenkamp Matrikelnummer: 5662889 Studienrichtung: Physik Eingereicht am: 31.3.2009 Betreuer(in): Dr. Laura Covi, DESY Zweitgutachter: Prof. Dr. Gun¨ ter Sigl, Universit¨at Hamburg ii Abstract We study the scenario of gravitino dark matter with a general neutralino being the next- to-lightest supersymmetric particle (NLSP). Therefore, we compute analytically all 2- and 3-body decays of the neutralino NLSP to determine the lifetime and the electro- magnetic and hadronic branching ratio of the neutralino decaying into the gravitino and Standard Model particles. We constrain the gravitino and neutralino NLSP mass via big bang nucleosynthesis and see how those bounds are relaxed for a Higgsino or a wino NLSP in comparison to the bino neutralino case. At neutralino masses & 1 TeV, a wino NLSP is favoured, since it decays rapidly via a newly found 4-vertex. The Higgsino component becomes important, when resonant annihilation via heavy Higgses can occur. We provide the full analytic results for the decay widths and the complete set of Feyn- man rules necessary for these computations. This thesis closes any gap in the study of gravitino dark matter scenarios with neutralino NLSP coming from approximations in the calculation of the neutralino decay rates and its hadronic branching ratio. Zusammenfassung Diese Diplomarbeit befasst sich mit dem Gravitino als Dunkler Materie, wobei ein allge- meines Neutralino das n¨achstleichteste supersymmetrische Teilchen (NLSP) ist.
    [Show full text]
  • Supergravities
    Chapter 10 Supergravities. When we constructed the spectrum of the closed spinning string, we found in the 3 1 massless sector states with spin 2 , in addition to states with spin 2 and other states i ~j NS ⊗ NS : b 1 j0; piL ⊗ b 1 j0; piR with i; j = 1; 8 yields gij(x) with spin 2 − 2 − 2 (10.1) i 3 NS ⊗ R : b− 1 j0; piL ⊗ j0; p; αiR with i; α = 1; 8 yields χi,α(x) with spin 2 2 The massless states with spin 2 correspond to a gauge field theory: Einstein's theory 3 of General Relativity, but in 9 + 1 dimensions. The massless states with spin 2 are part of another gauge theory, an extension of Einstein gravity, called supergravity. That theory was first discovered in 1976 in d = 3 + 1 dimensions, but supergravity theories also exist in higher dimensions, through (up to and including) eleven dimensions. In this chapter we discuss supergravity theories. They are important in string theory because they are the low-energy limit of string theories. We do not assume that the reader has any familiarity with supergravity. We begin with the N = 1 theory in 3 + 1 dimensions, m also called simple supergravity, which has one gravitational vielbein field eµ , and one m α fermionic partner of eµ , called the gravitino field µ with spinor index α = 1; ··· ; 4 A ¯ _ (or two 2-component gravitinos µ and µ,A_ with A; A = 1; 2) and µ = 0; 1; 2; 3. This theory has one real local supersymmetry with a real (Majorana) 4-component spinorial α A ∗ _ parameter (or two 2-component parameters and ¯A_ = (A) with A; A = 1; 2).
    [Show full text]
  • Gamma Ray Spectrum from Gravitino Dark Matter Decay
    DESY 07-158 Gamma Ray Spectrum from Gravitino Dark Matter Decay Alejandro Ibarra* and David Tran^ Gravitiuos arc very promising candidates for the cold dark matter of the Universe. Interestingly, to achieve a sufficiently long gravitino lifetime, A-parity conservation is not required, thus preventing any dangerous cosmological influence of the ncxt-to-lightcst supersymmetric particle. When Im­ parity is violated, gravitiuos decay into photons and other particles with a lifetime much longer than the age of the Universe, producing a diffuse gamma ray flux with a characteristic spectrum that could be measured in future experiments, like GLAST, AMS-02 or Cherenkov telescopes. In this letter we compute the energy spectrum of photons from gravitino decay and discuss its main qualitative features. 1'ACS numbers: 95.35.+R, 11.30.1'b, 93.T0.Rz 2007 There is mounting evidence that dark matter is ubiq­ of the standard nucleosynthesis scenario. In nrost supcr­ uitous in our Universe [1]. Since the necessity of dark synmrctric scenarios, the NLSP is either- a ncutralino or matter was realized, many different particle physics can ­ a stair. On one hand, if the NLSP is a ncutralino, its Sep didates have been proposed. Among the most interesting late decay into hadrons can dissociate the primordial el­ candidates stands the gravitino [2], the supersymmetric ements [G]. On the other hand, if the NLSP is a stau, 28 counterpart of the gr aviton, which arises when global su­ it can form a borrnd state with ^He, catalyzing the pro­ persymmetry is promoted to a local symmetry. If the duction of ^Li [7].
    [Show full text]
  • Probing Gravitational Interactions of Elementary Particles
    UCI-TR-2004-17 hep-ph/0405248 Probing Gravitational Interactions of Elementary Particles Jonathan L. Feng∗,1 Arvind Rajaraman†,1 and Fumihiro Takayama‡1 1Department of Physics and Astronomy, University of California, Irvine, CA 92697, USA Summary The gravitational interactions of elementary particles are suppressed by the Planck scale M∗ ∼ 1018 GeV and are typically expected to be far too weak to be probed by experiments. We show that, contrary to conventional wisdom, such interactions may be studied by particle physics experiments in the next few years. As an example, we consider conventional supergravity with a stable gravitino arXiv:hep-th/0405248v1 26 May 2004 as the lightest supersymmetric particle. The next-lightest supersymmetric particle (NLSP) decays to the gravitino through gravitational interactions after about a year. This lifetime can be measured by stopping NLSPs at colliders and observing their decays. Such studies will yield a measurement of Newton’s gravitational constant on unprecedentedly small scales, shed light on dark matter, and provide a window on the early universe. This essay was awarded second prize in the 2004 essay competition of the Gravity Research Foundation. ∗ [email protected][email protected][email protected] 1 As a force between elementary particles, gravity is extremely weak. Relative to the electromagnetic, weak, and strong interactions, gravitational interactions are suppressed −1/2 by E/M∗, where E is the typical energy scale of the process, and M∗ = (8πGN ) ≃ 2.4 × 1018 GeV is the reduced Planck mass. Given the energies E ∼< TeV accessible now and for the foreseeable future, this is an enormous suppression.
    [Show full text]
  • Unstable Gravitino Dark Matter with Observa- Tions of Indirect Dark Matter Detection Experiments in All Possible Cosmic-Ray Channels
    DESY-THESIS-2011-039 November 2011 Unstable Gravitino Dark Matter Prospects for Indirect and Direct Detection Dissertation zur Erlangung des Doktorgrades des Departments Physik der Universit¨at Hamburg vorgelegt von Michael Grefe arXiv:1111.6779v1 [hep-ph] 29 Nov 2011 aus L¨uneburg Hamburg 2011 Gutachter der Dissertation: Prof. Dr. Laura Covi Prof. Dr. Jan Louis Prof. Dr. Piero Ullio Gutachter der Disputation: Prof. Dr. Laura Covi Prof. Dr. Wilfried Buchm¨uller Datum der Disputation: 6. Juli 2011 Vorsitzender des Pr¨ufungsausschusses: Prof. Dr. G¨unter H. W. Sigl Vorsitzender des Promotionsausschusses: Prof. Dr. Peter H. Hauschildt Dekan der Fakult¨at f¨ur Mathematik, Informatik und Naturwissenschaften: Prof. Dr. Heinrich Graener Abstract We confront the signals expected from unstable gravitino dark matter with observa- tions of indirect dark matter detection experiments in all possible cosmic-ray channels. For this purpose we calculate in detail the gravitino decay widths in theories with bilin- ear violation of R parity, particularly focusing on decay channels with three particles in the final state. Based on these calculations we predict the fluxes of gamma rays, charged cosmic rays and neutrinos expected from decays of gravitino dark matter. Although the predicted spectra could in principal explain the anomalies observed in the cosmic- ray positron and electron fluxes as measured by PAMELA and Fermi LAT, we find that this possibility is ruled out by strong constraints from gamma-ray and antiproton observations. Therefore, we employ current data of indirect detection experiments to place strong constraints on the gravitino lifetime and the strength of R-parity violation. In addition, we discuss the prospects of forthcoming searches for a gravitino signal in the spectrum of cosmic-ray antideuterons, finding that they are in particular sensitive to rather low gravitino masses.
    [Show full text]
  • DEUTSCHES ELEKTRONEN-SYNCHROTRON Ftfe? 6D Supergravity: Warped Solution and Gravity Mediated Supersymmetry Breaking
    DE06FA376 DEUTSCHES ELEKTRONEN-SYNCHROTRON ftfe? in der HELMHOLTZ-GEMEINSCHAFT VX^*, DESY-THESIS-2006-020 July 2006 6D Supergravity: Warped Solution and Gravity Mediated Supersymmetry Breaking by C. Lüdeling ISSN 1435-8085 NOTKESTRASSE 85 - 22607 HAMBURG DESY behält sich alle Rechte für den Fall der Schutzrechtserteilung und für die wirtschaftliche Verwertung der in diesem Bericht enthaltenen Informationen vor. DESY reserves all rights for commercial use of information included in this report, especially in case of filing application for or grant of patents. To be sure that your reports and preprints are promptly included in the HEP literature database send them to (if possible by air mail): DESY DESY Zentralbibliothek Bibliothek Notkestraße 85 Platanenallee 6 22607 Hamburg 15738 Zeuthen Germany Germany 6D Supergravity: Warped Solution and Gravity Mediated Supersymmetry Breaking Dissertation zur Erlangung des Doktorgrades des Departments Physik der Universit¨at Hamburg vorgelegt von Christoph Ludeling¨ aus Leer Hamburg 2006 Gutachter des Dissertation: Prof. Dr. W. Buchmuller¨ Prof. Dr. J. Louis Gutachter der Disputation: Prof. Dr. W. Buchmuller¨ JP Dr. H. Samtleben Datum der Disputation: 10.07. 2006 Vorsitzender des Prufungsaussc¨ husses: Prof. Dr. J. Bartels Vorsitzender des Promotionsausschusses: Prof. Dr. G. Huber Dekan der Fakult¨at MIN: Prof. Dr. A. Fruh¨ wald Abstract We consider compactified six-dimensional gauged supergravity and find the general warped solution with four-dimensional maximal symmetry. Important features of the solution such as the number and position of singularities are determined by a free holomorphic function. Further- more, in a particular torus compactification we derive the supergrav- ity coupling of brane fields by the Noether procedure and investigate gravity-mediated supersymmetry breaking.
    [Show full text]
  • Baryogenesis
    CP Violation, Baryon violation, RPV in SUSY, Mesino Oscillations, and Baryogenesis David McKeen and AEN, arXiv:1512.05359 Akshay Ghalsasi, David McKeen, AEN., arXiv:1508.05392 (Thursday: Kyle Aitken, David McKeen, AEN, Thomas Neder, arXiv:1708.01259) (See also Seyda Ipek, David McKeen, AEN., arXiv:1407.8193 Seyda Ipek, John March-Russell, arXiv:1604.00009) Neutron-Antineutron Oscillations: Appearance, Disappearance, and Baryogenesis October 24, 2017 CP V beyond the Standard Model • Needed to produce early universe asymmetry of 10-8 between quarks and anti-quarks? (baryogenesis) • Effects of CKM phase in early universe highly suppressed by small mixing angles and mass differences. non standard CPV • or • non standard enhancement of standard CPV 2 Baryon Violation • SM: Anomalous effect in weak interactions (“Sphalerons”) rapid violation of B, L at T> ~ 100 GeV (weak transition), negligible B violation at low T (tunneling) • Sphalerons conserve B-L • Baryogenesis: • produce net B-L at high T (e.g. leptogenesis) • electroweak baryogenesis (no BSM B or L violation needed) • post sphaleron baryogenesis (requires B violation at low energy which does not allow proton decay) 3 Why ‘post sphaleron’ baryogenesis is compelling • Consistent with wide range of cosmology/inflation models. • No high temperature required (solves a lot of cosmological issues, e.g. gravitino over production) • Electroweak baryogenesis requires 1st order weak transition, CPV in Higgs sector—very constrained by electric dipole moment of electron, mass of Higgs. 4 Consequence
    [Show full text]