Dark Matter, Symmetries and Cosmology
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(2380) in a Hexaquark Scenario
Proceedings of the 8th International Conference on Quarks and Nuclear Physics (QNP2018) Downloaded from journals.jps.jp by Deutsches Elek Synchrotron on 11/15/19 Proc. 8th Int. Conf. Quarks and Nuclear Physics (QNP2018) JPS Conf. Proc. 26, 022016 (2019) https://doi.org/10.7566/JPSCP.26.022016 The Properties of d∗(2380) in a Hexaquark Scenario Yubing Dong1;2;3;y, Pengnian Shen1;4, Fei Huang2, and Zongye Zhang1;2;3 1 Institute of High Energy Physics, Chinese Academy of Sciences, Beijing 100049, China 2 School of Physical Sciences, University of Chinese Academy of Sciences, Beijing 101408, China 3 Theoretical Physics Center for Science Facilities (TPCSF), CAS, Beijing 100049, China 4 College of Physics and Technology, Guangxi Normal University, Guilin 541004, China E-mail: [email protected] (Received January 5, 2019) The properties of the newly observed dibaryon resonance d∗(2380) (IJ p = 03+), calculated in a constituent chiral quark model, are briefly reported. Comparing to the available experimental data for its decays, we conclude that the resonance d∗(2380) can be reasonably interpreted as a compact heaxquark dominant state. KEYWORDS: d∗(2380), dibaryon, chiral constituent quark model, hexaquark 1. Introduction The history of the studies of dibaryon systems, like d∗, d0 and H particles, can be traced back to about half century ago (see the review article of Clement [1]). The clear experimental evidence for the d∗ was not observed until 2009. They were the CELSIUS/WASA and WASA@COSY collaborations, who carried out the study of ABC effect [2–5], and found that their measurements cannot be simply explained by the contribution either from the intermediate Roper excitation or from the t-channel ∆∆ contribution, except introducing an intermediate new resonance. -
Dark Matter and the Early Universe: a Review Arxiv:2104.11488V1 [Hep-Ph
Dark matter and the early Universe: a review A. Arbey and F. Mahmoudi Univ Lyon, Univ Claude Bernard Lyon 1, CNRS/IN2P3, Institut de Physique des 2 Infinis de Lyon, UMR 5822, 69622 Villeurbanne, France Theoretical Physics Department, CERN, CH-1211 Geneva 23, Switzerland Institut Universitaire de France, 103 boulevard Saint-Michel, 75005 Paris, France Abstract Dark matter represents currently an outstanding problem in both cosmology and particle physics. In this review we discuss the possible explanations for dark matter and the experimental observables which can eventually lead to the discovery of dark matter and its nature, and demonstrate the close interplay between the cosmological properties of the early Universe and the observables used to constrain dark matter models in the context of new physics beyond the Standard Model. arXiv:2104.11488v1 [hep-ph] 23 Apr 2021 1 Contents 1 Introduction 3 2 Standard Cosmological Model 3 2.1 Friedmann-Lema^ıtre-Robertson-Walker model . 4 2.2 A quick story of the Universe . 5 2.3 Big-Bang nucleosynthesis . 8 3 Dark matter(s) 9 3.1 Observational evidences . 9 3.1.1 Galaxies . 9 3.1.2 Galaxy clusters . 10 3.1.3 Large and cosmological scales . 12 3.2 Generic types of dark matter . 14 4 Beyond the standard cosmological model 16 4.1 Dark energy . 17 4.2 Inflation and reheating . 19 4.3 Other models . 20 4.4 Phase transitions . 21 5 Dark matter in particle physics 21 5.1 Dark matter and new physics . 22 5.1.1 Thermal relics . 22 5.1.2 Non-thermal relics . -
Particle Interpretations of the PVLAS Data
DESY 07-054 PARTICLE INTERPRETATIONS OF THE PVLAS DATA∗ ANDREAS RINGWALD Deutsches Elektronen-Synchrotron DESY, Notkestraße 85 D-22607 Hamburg, Germany E-mail: [email protected] ABSTRACT Recently the PVLAS collaboration reported the observation of a rotation of linearly polarized laser light induced by a transverse magnetic field – a sig- nal being unexpected within standard QED. In this review, we emphasize two mechanisms which have been proposed to explain this result: production of a single light neutral spin-zero particle or pair production of light minicharged particles. We discuss a class of models, involving, in addition to our familiar “visible” photon, further light “hidden paraphotons”, which mix kinematically with the visible one, and further light paracharged particles. In these models, very strong astrophysical and cosmological bounds on the weakly interacting light particles mentioned above can be evaded. In the upcoming year, a number of decisive laboratory based tests of the particle interpretation of the PVLAS anomaly will be done. More generally, such experiments, exploiting high fluxes of low-energy photons and/or large electromagnetic fields, will dig into previously unconstrained parameter space of the above mentioned models. 1. Introduction We are entering a new era in particle physics: Next year, the Large Hadron Col- lider (LHC) will start to probe, through the collision of 7 TeV protons, the structure of matter and space-time at an unprecedented level. There is a lot of circumstantial evidence that the physics at the TeV scale exploited at LHC and later at the Inter- arXiv:0704.3195v1 [hep-ph] 24 Apr 2007 national Linear Collider (ILC) will bring decisive insights into fundamental questions such as the origin of particle masses, the nature of dark matter in the universe, and the unification of all forces, including gravity. -
Diffractive Dissociation of Alpha Particles As a Test of Isophobic Short-Range Correlations Inside Nuclei ∗ Jennifer Rittenhouse West A, , Stanley J
Physics Letters B 805 (2020) 135423 Contents lists available at ScienceDirect Physics Letters B www.elsevier.com/locate/physletb Diffractive dissociation of alpha particles as a test of isophobic short-range correlations inside nuclei ∗ Jennifer Rittenhouse West a, , Stanley J. Brodsky a, Guy F. de Téramond b, Iván Schmidt c a SLAC National Accelerator Laboratory, Stanford University, Stanford, CA 94309, USA b Laboratorio de Física Teórica y Computacional, Universidad de Costa Rica, 11501 San José, Costa Rica c Departamento de Física y Centro Científico Tecnológico de Valparáiso-CCTVal, Universidad Técnica Federico Santa María, Casilla 110-V, Valparaíso, Chile a r t i c l e i n f o a b s t r a c t Article history: The CLAS collaboration at Jefferson Laboratory has compared nuclear parton distributions for a range Received 15 January 2020 of nuclear targets and found that the EMC effect measured in deep inelastic lepton-nucleus scattering Received in revised form 9 April 2020 has a strongly “isophobic” nature. This surprising observation suggests short-range correlations between Accepted 9 April 2020 neighboring n and p nucleons in nuclear wavefunctions that are much stronger compared to p − p or n − Available online 14 April 2020 n correlations. In this paper we propose a definitive experimental test of the nucleon-nucleon explanation Editor: W. Haxton of the isophobic nature of the EMC effect: the diffractive dissociation on a nuclear target A of high energy 4 He nuclei to pairs of nucleons n and p with high relative transverse momentum, α + A → n + p + A + X. The comparison of n − p events with p − p and n − n events directly tests the postulated breaking of isospin symmetry. -
Letter of Interest Cosmic Probes of Ultra-Light Axion Dark Matter
Snowmass2021 - Letter of Interest Cosmic probes of ultra-light axion dark matter Thematic Areas: (check all that apply /) (CF1) Dark Matter: Particle Like (CF2) Dark Matter: Wavelike (CF3) Dark Matter: Cosmic Probes (CF4) Dark Energy and Cosmic Acceleration: The Modern Universe (CF5) Dark Energy and Cosmic Acceleration: Cosmic Dawn and Before (CF6) Dark Energy and Cosmic Acceleration: Complementarity of Probes and New Facilities (CF7) Cosmic Probes of Fundamental Physics (TF09) Astro-particle physics and cosmology Contact Information: Name (Institution) [email]: Keir K. Rogers (Oskar Klein Centre for Cosmoparticle Physics, Stockholm University; Dunlap Institute, University of Toronto) [ [email protected]] Authors: Simeon Bird (UC Riverside), Simon Birrer (Stanford University), Djuna Croon (TRIUMF), Alex Drlica-Wagner (Fermilab, University of Chicago), Jeff A. Dror (UC Berkeley, Lawrence Berkeley National Laboratory), Daniel Grin (Haverford College), David J. E. Marsh (Georg-August University Goettingen), Philip Mocz (Princeton), Ethan Nadler (Stanford), Chanda Prescod-Weinstein (University of New Hamp- shire), Keir K. Rogers (Oskar Klein Centre for Cosmoparticle Physics, Stockholm University; Dunlap Insti- tute, University of Toronto), Katelin Schutz (MIT), Neelima Sehgal (Stony Brook University), Yu-Dai Tsai (Fermilab), Tien-Tien Yu (University of Oregon), Yimin Zhong (University of Chicago). Abstract: Ultra-light axions are a compelling dark matter candidate, motivated by the string axiverse, the strong CP problem in QCD, and possible tensions in the CDM model. They are hard to probe experimentally, and so cosmological/astrophysical observations are very sensitive to the distinctive gravitational phenomena of ULA dark matter. There is the prospect of probing fifteen orders of magnitude in mass, often down to sub-percent contributions to the DM in the next ten to twenty years. -
Pandax-II ! 2015.4.9 Sino-French PPL, Hefei Pandax Dark Matter Search Program
Jinping Mountain WIMPs PandaX Dark Matter Search with Liquid Xenon at Jinping Kaixuan Ni! (on behalf of the PandaX Collaboration)! Shanghai Jiao Tong University! from PandaX-I to PandaX-II ! 2015.4.9 Sino-French PPL, Hefei PandaX dark matter search program ❖ 2009.3 SJTU group visited Jinping for the first time! ❖ 2009.4 Proposals submitted for dark matter search with liquid xenon at Jinping! ❖ 2010.1 PandaX collaboration formed, funding supported by SJTU/MOST/NSFC, started to develop the PandaX-I detector at SJTU! ❖ 2012.8 PandaX-I detector moved to CJPL! ❖ 2012.9-2013.9 Two engineering runs carried out for system integration! ❖ 2014.3 Detector fully functional for data taking! ❖ 2014.8 PandaX-I first results (17 days) published! ❖ 2014.11 Another 63 days dark matter data were collected! ❖ 2015 Upgrading from PandaX-I (125-kg) to PandaX-II (500-kg) PandaX Collaboration for Dark Matter Search Shanghai Jiao Tong University! Shanghai Institute of Applied Physics, CAS! Shandong University! University of Maryland! University of Michigan! Peking University! http://pandax.org/ Yalong River Hydropower Development Co.! China Institute of Atomic Energy (new group joined 2015) Why Liquid Xenon? • Ultra-low background: using self-shielding with 3D fiducialization and ER/NR discrimination • Sensitive to both heavy and light dark matter • Sensitive to both Spin-independent and Spin-dependent (129Xe,131Xe) • Ultra-pure Xe target: xenon gas can be purified with sub-ppb (O2 etc.) and sub-ppt (Kr) impurities • Multi-ton target achievable: with reasonable cost ($1.5M/ton) and relative simple cryogenics (165K) Two-phase xenon for dark matter searches WIMPs/Neutrons. -
Unit VI Superconductivity JIT Nashik Contents
Unit VI Superconductivity JIT Nashik Contents 1 Superconductivity 1 1.1 Classification ............................................. 1 1.2 Elementary properties of superconductors ............................... 2 1.2.1 Zero electrical DC resistance ................................. 2 1.2.2 Superconducting phase transition ............................... 3 1.2.3 Meissner effect ........................................ 3 1.2.4 London moment ....................................... 4 1.3 History of superconductivity ...................................... 4 1.3.1 London theory ........................................ 5 1.3.2 Conventional theories (1950s) ................................ 5 1.3.3 Further history ........................................ 5 1.4 High-temperature superconductivity .................................. 6 1.5 Applications .............................................. 6 1.6 Nobel Prizes for superconductivity .................................. 7 1.7 See also ................................................ 7 1.8 References ............................................... 8 1.9 Further reading ............................................ 10 1.10 External links ............................................. 10 2 Meissner effect 11 2.1 Explanation .............................................. 11 2.2 Perfect diamagnetism ......................................... 12 2.3 Consequences ............................................. 12 2.4 Paradigm for the Higgs mechanism .................................. 12 2.5 See also ............................................... -
Surface Pair-Density-Wave Superconducting and Superfluid States
Surface Pair-Density-Wave Superconducting and Superfluid States Mats Barkman,1 Albert Samoilenka,1 and Egor Babaev1 1Department of Physics, Royal Institute of Technology, SE-106 91 Stockholm, Sweden Fulde, Ferrell, Larkin, and Ovchinnikov (FFLO) predicted inhomogeneous superconducting and superfluid ground states, spontaneously breaking translation symmetries. In this Letter, we demon- strate that the transition from the FFLO to the normal state as a function of temperature or increased Fermi surface splitting is not a direct one. Instead the system has an additional phase transition to a different state where pair-density-wave superconductivity (or superfluidity) exists only on the boundaries of the system, while the bulk of the system is normal. The surface pair- density-wave state is very robust and exists for much larger fields and temperatures than the FFLO state. In regular BCS theory, the formation of Cooper pairs The Ginzburg-Landau description of superconductors binding together two electrons with opposite spin and op- in the presence of Zeeman splitting was derived from mi- posite momentum results in a uniform superconducting croscopic theory in Ref. [31]. The free energy functional state [1,2]. In 1964, Fulde and Ferrell [3] and Larkin and R d reads F [ ] = Ω d x where the free energy density is Ovchinnikov [4] (FFLO) independently predicted that F F under certain conditions there should appear an inho- =α 2 + β 2 + γ 4 + δ 2 2+ mogeneous state in the presence of a strong magnetic F j j jr jµ j j jr j (1) µ 2 2 + ( ∗)2( )2 + c.c. + ν 6; field, where Zeeman splitting of the Fermi surfaces leads j j jr j 8 r j j to the formation of Cooper pairs with nonzero total mo- mentum. -
Three-Flavor Color Superconductivity
Three-Flavor Color Superconductivity Dissertation zur Erlangung des Doktorgrades der Naturwissenschaften vorgelegt beim Fachbereich Physik der Johann Wolfgang Goethe-Universit¨at in Frankfurt am Main von Hossein Malekzadeh aus dem Iran Frankfurt am Main, Dezember 2007 (D 30) 2 vom Fachbereich Physik der Johann Wolfgang Goethe–Universit¨at als Dissertation angenommen. Dekan: Prof. Dr. W. Aßmus Gutachter: Prof. Dr. D.-H. Rischke, Prof. Dr. Adrian Dumitru Datum der Disputation: Dezember 7, 2007. Acknowledgements I would like to express my special thanks to Prof. Dirk Rischke for all the generous supports that during my Ph.D thesis he gave mentally and practically to me. I learned a lot of things from him which will be certainly very useful for me in future as well. Without his helps and encouragements it would be difficult to come to the end of this thesis. Thank you Dirk! I am also very grateful to Prof. Igor Shovkovy for very instructive discussions we had. He was the one who taught this stimulating field to me. Also, I had a lot of fun with him during lunch breaks and in other occasions. Since I wanted to take ten watermelons with my tow hands, I needed to work harder. On other words, along my Ph.D thesis, I wanted to work on other fields as well, although the project were not published. I had great times when I was collaborating with Prof. Adrian Dumitru and Prof. Michael Strickland. I thank both of you for teaching me those fascinating topics. I also had a wonderful chance to talk to Prof. -
Supersymmetric Dark Matter Candidates in Light of Constraints from Collider and Astroparticle Observables
THESE` Pour obtenir le grade de DOCTEUR DE L’UNIVERSITE´ DE GRENOBLE Specialit´ e´ : Physique Theorique´ Arretˆ e´ ministeriel´ : 7 aoutˆ 2006 Present´ ee´ par Jonathan DA SILVA These` dirigee´ par Genevieve` BELANGER´ prepar´ ee´ au sein du Laboratoire d’Annecy-le-Vieux de Physique Theorique´ (LAPTh) et de l’Ecole´ Doctorale de Physique de Grenoble Supersymmetric Dark Matter candidates in light of constraints from collider and astroparticle observables These` soutenue publiquement le 3 juillet 2013, devant le jury compose´ de : arXiv:1312.0257v1 [hep-ph] 1 Dec 2013 Dr. Rohini GODBOLE Professeur, CHEP Bangalore, Inde, Presidente´ Dr. Farvah Nazila MAHMOUDI Maˆıtre de Conferences,´ LPC Clermont, Rapporteur Dr. Ulrich ELLWANGER Professeur, LPT Orsay, Rapporteur Dr. Celine´ BŒHM Charge´ de recherche, Durham University, Royaume-Uni, Examinatrice Dr. Anupam MAZUMDAR Professeur, Lancaster University, Royaume-Uni, Examinateur Dr. Genevieve` BELANGER´ Directeur de Recherche, LAPTh, Directeur de these` A meus av´os. Contents Acknowledgements - Remerciements vii List of Figures xi List of Tables xvii List of Abbreviations xix List of Publications xxiii Introduction1 I Status of particle physics and cosmology ... and beyond5 1 From the infinitely small : the Standard Model of particle physics ...7 1.1 Building of the model : gauge sector . .8 1.2 Matter sector . 10 1.2.1 Leptons . 10 1.2.2 Quarks . 12 1.3 The Higgs mechanism . 13 1.4 Full standard picture . 16 1.5 Successes of the SM . 18 1.6 SM issues . 19 1.6.1 Theoretical problems . 19 1.6.2 Experimental discrepancies . 20 1.6.3 Cosmological connexion . 22 2 ... To the infinitely large : the Lambda Cold Dark Matter model 23 2.1 Theoretical framework . -
A New Possibility for Light-Quark Dark Matter 2
A new possibility for light-quark Dark Matter M. Bashkanov Department of Physics, University of York, Heslington, York, Y010 5DD, UK E-mail: [email protected] D. P. Watts Department of Physics, University of York, Heslington, York, Y010 5DD, UK E-mail: [email protected] July 2019 Abstract. Despite many decades of study the physical origin of ”dark matter” in the Universe remains elusive. In this letter we calculate the properties of a completely new dark matter candidate - Bose-Einstein condensates formed from a recently discovered bosonic particle in the light-quark sector, the d∗(2380) hexaquark. In this first study, we show stable d∗(2380) Bose-Einstein condensates could form in the primordial early universe, with a production rate sufficiently large that they are a plausible new candidate for dark matter. Some possible astronomical signatures of such dark matter are also presented. Submitted to: J. Phys. G: Nucl. Phys. Introduction arXiv:2001.08654v1 [astro-ph.CO] 23 Jan 2020 The physical origin of dark matter (DM) in the universe is one of the key unsolved questions for physics and astronomy. There is strong indirect evidence for the existence of such matter[1] from measurements of cosmic primordial radiation, anomalies in the radial dependence of galactic rotational curves and gravitational lensing. Despite its apparently pivotal role in the universe the physical origin of DM remains unknown, with significant research focused on beyond standard model (yet currently undiscovered) particles such as axions, sterile neutrinos and weakly interacting massive particles (WIMPs)[1]. Recent advances in experimental searches have now eliminated significant fractions of the parameter space for WIMP candidates and the initial motivation as a full solution to the dark matter problem appears weaker. -
Lattice QCD Study of the $ H $ Dibaryon Using Hexaquark and Two
CERN-TH-2018-098, DESY 18-066, HIM-2018-02, MITP/18-030, TIFR/TH/18-12 Lattice QCD study of the H dibaryon using hexaquark and two-baryon interpolators A. Francis,1 J. R. Green,2 P. M. Junnarkar,3 Ch. Miao,4, 5 T. D. Rae,4 and H. Wittig4, 5 1Theoretical Physics Department, CERN, CH-1211 Geneva 23, Switzerland 2NIC, Deutsches Elektronen-Synchrotron, D-15738 Zeuthen, Germany 3Tata Institute of Fundamental Research (TIFR), 1 Homi Bhabha Road, Mumbai 400005. India. 4PRISMA Cluster of Excellence and Institut f¨urKernphysik, University of Mainz, Becher Weg 45, D-55099 Mainz, Germany 5Helmholtz Institute Mainz, University of Mainz, D-55099 Mainz, Germany (Dated: April 16, 2019) We present a lattice QCD spectroscopy study in the isospin singlet, strangeness −2 sectors relevant for the conjectured H dibaryon. We employ both local and bilocal interpolating operators to isolate the ground state in the rest frame and in moving frames. Calculations are performed using two flavors of O(a)-improved Wilson fermions and a quenched strange quark. Our initial point-source method for constructing correlators does not allow for bilocal operators at the source; nevertheless, results from using these operators at the sink indicate that they provide an improved overlap onto the ground state in comparison with the local operators. We also present results, in the rest frame, using a second method based on distillation to compute a hermitian matrix of correlators with bilocal operators at both the source and the sink. This method yields a much more precise and reliable determination of the ground-state energy.