Abstract
We investigate the nightmare scenario of dark sectors that are made of non-abelian gauge theories with fermions, gravitationally coupled to the Standard Model (SM). While testing these scenarios is experimentally challenging, they are strongly motivated by the accidental stability of dark baryons and pions, that explain the cosmological stability of dark matter (DM). We study the production of these sectors which are minimally populated through gravitational freeze-in, leading to a dark sector temperature much lower than the SM, or through inflaton decay, or renormalizable interactions producing warmer DM. Despite having only gravitational couplings with the SM these scenarios turn out to be rather predictive depending roughly on three parameters: the dark sector temperature, the confinement scale and the dark pion mass. In particular, when the initial temperature is comparable to the SM one these scenarios are very constrained by structure formation, ∆Neff and limits on DM self-interactions. Dark sectors with same temperature or warmer than SM are typically excluded.
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References
Particle Data Group collaboration, Review of Particle Physics, PTEP 2020 (2020) 083C01 [INSPIRE].
WMAP collaboration, Nine-Year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Cosmological Parameter Results, Astrophys. J. Suppl. 208 (2013) 19 [arXiv:1212.5226] [INSPIRE].
M. Garny, M. Sandora and M. S. Sloth, Planckian Interacting Massive Particles as Dark Matter, Phys. Rev. Lett. 116 (2016) 101302 [arXiv:1511.03278] [INSPIRE].
E. Babichev, L. Marzola, M. Raidal, A. Schmidt-May, F. Urban, H. Veermäe et al., Bigravitational origin of dark matter, Phys. Rev. D 94 (2016) 084055 [arXiv:1604.08564] [INSPIRE].
Y. Tang and Y.-L. Wu, Pure Gravitational Dark Matter, Its Mass and Signatures, Phys. Lett. B 758 (2016) 402 [arXiv:1604.04701] [INSPIRE].
M. Garny, A. Palessandro, M. Sandora and M. S. Sloth, Theory and Phenomenology of Planckian Interacting Massive Particles as Dark Matter, JCAP 02 (2018) 027 [arXiv:1709.09688] [INSPIRE].
M. Garny, A. Palessandro, M. Sandora and M. S. Sloth, Charged Planckian Interacting Dark Matter, JCAP 01 (2019) 021 [arXiv:1810.01428] [INSPIRE].
Y. Ema, K. Nakayama and Y. Tang, Production of Purely Gravitational Dark Matter, JHEP 09 (2018) 135 [arXiv:1804.07471] [INSPIRE].
N. Bernal, M. Dutra, Y. Mambrini, K. Olive, M. Peloso and M. Pierre, Spin-2 Portal Dark Matter, Phys. Rev. D 97 (2018) 115020 [arXiv:1803.01866] [INSPIRE].
Y. Ema, K. Nakayama and Y. Tang, Production of purely gravitational dark matter: the case of fermion and vector boson, JHEP 07 (2019) 060 [arXiv:1903.10973] [INSPIRE].
M. Redi, A. Tesi and H. Tillim, Gravitational Production of a Conformal Dark Sector, JHEP 05 (2021) 010 [arXiv:2011.10565] [INSPIRE].
A. Ahmed, B. Grzadkowski and A. Socha, Gravitational production of vector dark matter, JHEP 08 (2020) 059 [arXiv:2005.01766] [INSPIRE].
S. Nussinov, Technocosmology: Could A Technibaryon Excess Provide A ‘Natural’ Missing Mass Candidate?, Phys. Lett. B 165 (1985) 55 [INSPIRE].
E. D. Carlson, M. E. Machacek and L. J. Hall, Self-interacting dark matter, Astrophys. J. 398 (1992) 43 [INSPIRE].
G. D. Kribs, T. S. Roy, J. Terning and K. M. Zurek, Quirky Composite Dark Matter, Phys. Rev. D 81 (2010) 095001 [arXiv:0909.2034] [INSPIRE].
A. Hietanen, R. Lewis, C. Pica and F. Sannino, Composite Goldstone Dark Matter: Experimental Predictions from the Lattice, JHEP 12 (2014) 130 [arXiv:1308.4130] [INSPIRE].
E. Hardy, R. Lasenby, J. March-Russell and S. M. West, Big Bang Synthesis of Nuclear Dark Matter, JHEP 06 (2015) 011 [arXiv:1411.3739] [INSPIRE].
O. Antipin, M. Redi, A. Strumia and E. Vigiani, Accidental Composite Dark Matter, JHEP 07 (2015) 039 [arXiv:1503.08749] [INSPIRE].
T. Appelquist et al., Stealth Dark Matter: Dark scalar baryons through the Higgs portal, Phys. Rev. D 92 (2015) 075030 [arXiv:1503.04203] [INSPIRE].
J. M. Cline, W. Huang and G. D. Moore, Challenges for models with composite states, Phys. Rev. D 94 (2016) 055029 [arXiv:1607.07865] [INSPIRE].
S. J. Lonsdale, M. Schroor and R. R. Volkas, Asymmetric Dark Matter and the hadronic spectra of hidden QCD, Phys. Rev. D 96 (2017) 055027 [arXiv:1704.05213] [INSPIRE].
A. Mitridate, M. Redi, J. Smirnov and A. Strumia, Dark Matter as a weakly coupled Dark Baryon, JHEP 10 (2017) 210 [arXiv:1707.05380] [INSPIRE].
A. Carvunis, D. Guadagnoli, M. Reboud and P. Stangl, Composite Dark Matter and a horizontal symmetry, JHEP 02 (2021) 056 [arXiv:2007.11931] [INSPIRE].
G. D. Kribs and E. T. Neil, Review of strongly-coupled composite dark matter models and lattice simulations, Int. J. Mod. Phys. A 31 (2016) 1643004 [arXiv:1604.04627] [INSPIRE].
S. Bottaro, M. Costa and O. Popov, Asymmetric accidental composite dark matter, JHEP 11 (2021) 055 [arXiv:2104.14244] [INSPIRE].
N. A. Dondi, F. Sannino and J. Smirnov, Thermal history of composite dark matter, Phys. Rev. D 101 (2020) 103010 [arXiv:1905.08810] [INSPIRE].
L. Morrison, S. Profumo and D. J. Robinson, Large N -ightmare Dark Matter, JCAP 05 (2021) 058 [arXiv:2010.03586] [INSPIRE].
Y.-D. Tsai, R. McGehee and H. Murayama, Resonant Self-Interacting Dark Matter from Dark QCD, arXiv:2008.08608 [INSPIRE].
J. M. Cline, Z. Liu, G. D. Moore and W. Xue, Composite strongly interacting dark matter, Phys. Rev. D 90 (2014) 015023 [arXiv:1312.3325] [INSPIRE].
K. K. Boddy, J. L. Feng, M. Kaplinghat and T. M. P. Tait, Self-Interacting Dark Matter from a Non-Abelian Hidden Sector, Phys. Rev. D 89 (2014) 115017 [arXiv:1402.3629] [INSPIRE].
A. Soni and Y. Zhang, Hidden SU(N) Glueball Dark Matter, Phys. Rev. D 93 (2016) 115025 [arXiv:1602.00714] [INSPIRE].
L. Forestell, D. E. Morrissey and K. Sigurdson, Cosmological Bounds on Non-Abelian Dark Forces, Phys. Rev. D 97 (2018) 075029 [arXiv:1710.06447] [INSPIRE].
B. S. Acharya, M. Fairbairn and E. Hardy, Glueball dark matter in non-standard cosmologies, JHEP 07 (2017) 100 [arXiv:1704.01804] [INSPIRE].
B. Jo, H. Kim, H. D. Kim and C. S. Shin, Exploring the Universe with dark light scalars, Phys. Rev. D 103 (2021) 083528 [arXiv:2010.10880] [INSPIRE].
C. Gross, S. Karamitsos, G. Landini and A. Strumia, Gravitational Vector Dark Matter, JHEP 03 (2021) 174 [arXiv:2012.12087] [INSPIRE].
E. Witten, Global Aspects of Current Algebra, Nucl. Phys. B 223 (1983) 422 [INSPIRE].
Y. Hochberg, E. Kuflik, H. Murayama, T. Volansky and J. G. Wacker, Model for Thermal Relic Dark Matter of Strongly Interacting Massive Particles, Phys. Rev. Lett. 115 (2015) 021301 [arXiv:1411.3727] [INSPIRE].
A. Djouadi, The Anatomy of electro-weak symmetry breaking. I: The Higgs boson in the standard model, Phys. Rept. 457 (2008) 1 [hep-ph/0503172] [INSPIRE].
A. Arvanitaki, S. Dimopoulos, S. Dubovsky, P. W. Graham, R. Harnik and S. Rajendran, Astrophysical Probes of Unification, Phys. Rev. D 79 (2009) 105022 [arXiv:0812.2075] [INSPIRE].
R. Essig, E. Kuflik, S. D. McDermott, T. Volansky and K. M. Zurek, Constraining Light Dark Matter with Diffuse X-Ray and Gamma-Ray Observations, JHEP 11 (2013) 193 [arXiv:1309.4091] [INSPIRE].
D. J. H. Chung, E. W. Kolb and A. Riotto, Superheavy dark matter, Phys. Rev. D 59 (1998) 023501 [hep-ph/9802238] [INSPIRE].
L. J. Hall, K. Jedamzik, J. March-Russell and S. M. West, Freeze-In Production of FIMP Dark Matter, JHEP 03 (2010) 080 [arXiv:0911.1120] [INSPIRE].
H. Osborn and A. C. Petkou, Implications of conformal invariance in field theories for general dimensions, Annals Phys. 231 (1994) 311 [hep-th/9307010] [INSPIRE].
S. S. Gubser and I. R. Klebanov, Absorption by branes and Schwinger terms in the world volume theory, Phys. Lett. B 413 (1997) 41 [hep-th/9708005] [INSPIRE].
Y. Mambrini and K. A. Olive, Gravitational Production of Dark Matter during Reheating, Phys. Rev. D 103 (2021) 115009 [arXiv:2102.06214] [INSPIRE].
E. W. Kolb and A. J. Long, Completely dark photons from gravitational particle production during the inflationary era, JHEP 03 (2021) 283 [arXiv:2009.03828] [INSPIRE].
P. Adshead, L. Pearce, M. Peloso, M. A. Roberts and L. Sorbo, Phenomenology of fermion production during axion inflation, JCAP 06 (2018) 020 [arXiv:1803.04501] [INSPIRE].
D. J. H. Chung, L. L. Everett, H. Yoo and P. Zhou, Gravitational Fermion Production in Inflationary Cosmology, Phys. Lett. B 712 (2012) 147 [arXiv:1109.2524] [INSPIRE].
N. Herring and D. Boyanovsky, Gravitational production of nearly thermal fermionic dark matter, Phys. Rev. D 101 (2020) 123522 [arXiv:2005.00391] [INSPIRE].
P. B. Arnold, G. D. Moore and L. G. Yaffe, Effective kinetic theory for high temperature gauge theories, JHEP 01 (2003) 030 [hep-ph/0209353] [INSPIRE].
A. Kurkela and E. Lu, Approach to Equilibrium in Weakly Coupled Non-Abelian Plasmas, Phys. Rev. Lett. 113 (2014) 182301 [arXiv:1405.6318] [INSPIRE].
M. Panero, Thermodynamics of the QCD plasma and the large-N limit, Phys. Rev. Lett. 103 (2009) 232001 [arXiv:0907.3719] [INSPIRE].
B. Lucini and M. Panero, SU(N) gauge theories at large N , Phys. Rept. 526 (2013) 93 [arXiv:1210.4997] [INSPIRE].
N. Brambilla et al., QCD and Strongly Coupled Gauge Theories: Challenges and Perspectives, Eur. Phys. J. C 74 (2014) 2981 [arXiv:1404.3723] [INSPIRE].
CP-PACS collaboration, Equation of state in finite temperature QCD with two flavors of improved Wilson quarks, Phys. Rev. D 64 (2001) 074510 [hep-lat/0103028] [INSPIRE].
Y. Aoki, Z. Fodor, S. D. Katz and K. K. Szabo, The Equation of state in lattice QCD: With physical quark masses towards the continuum limit, JHEP 01 (2006) 089 [hep-lat/0510084] [INSPIRE].
S. Borsányi, G. Endrodi, Z. Fodor, S. D. Katz and K. K. Szabo, Precision SU(3) lattice thermodynamics for a large temperature range, JHEP 07 (2012) 056 [arXiv:1204.6184] [INSPIRE].
I. Garcia Garcia, R. Lasenby and J. March-Russell, Twin Higgs WIMP Dark Matter, Phys. Rev. D 92 (2015) 055034 [arXiv:1505.07109] [INSPIRE].
K.-C. Yang, Thermodynamic Evolution of Secluded Vector Dark Matter: Conventional WIMPs and Nonconventional WIMPs, JHEP 11 (2019) 048 [arXiv:1905.09582] [INSPIRE].
C. Mondino, M. Pospelov, J. T. Ruderman and O. Slone, Dark Higgs Dark Matter, Phys. Rev. D 103 (2021) 035027 [arXiv:2005.02397] [INSPIRE].
M. Cirelli, Y. Gouttenoire, K. Petraki and F. Sala, Homeopathic Dark Matter, or how diluted heavy substances produce high energy cosmic rays, JCAP 02 (2019) 014 [arXiv:1811.03608] [INSPIRE].
C. Amsler, Proton - anti-proton annihilation and meson spectroscopy with the crystal barrel, Rev. Mod. Phys. 70 (1998) 1293 [hep-ex/9708025] [INSPIRE].
D. Pappadopulo, J. T. Ruderman and G. Trevisan, Dark matter freeze-out in a nonrelativistic sector, Phys. Rev. D 94 (2016) 035005 [arXiv:1602.04219] [INSPIRE].
M. Farina, D. Pappadopulo, J. T. Ruderman and G. Trevisan, Phases of Cannibal Dark Matter, JHEP 12 (2016) 039 [arXiv:1607.03108] [INSPIRE].
D. N. Spergel and P. J. Steinhardt, Observational evidence for selfinteracting cold dark matter, Phys. Rev. Lett. 84 (2000) 3760 [astro-ph/9909386] [INSPIRE].
B. D. Fields, K. A. Olive, T.-H. Yeh and C. Young, Big-Bang Nucleosynthesis after Planck, JCAP 03 (2020) 010 [Erratum ibid. 11 (2020) E02] [arXiv:1912.01132] [INSPIRE].
CMB-S4 collaboration, CMB-S4 Science Book, First Edition, arXiv:1610.02743 [INSPIRE].
V. Iršič et al., New Constraints on the free-streaming of warm dark matter from intermediate and small scale Lyman-α forest data, Phys. Rev. D 96 (2017) 023522 [arXiv:1702.01764] [INSPIRE].
X. Chu, B. Dasgupta and J. Kopp, Sterile neutrinos with secret interactions—lasting friendship with cosmology, JCAP 10 (2015) 011 [arXiv:1505.02795] [INSPIRE].
D. Egana-Ugrinovic, R. Essig, D. Gift and M. LoVerde, The Cosmological Evolution of Self-interacting Dark Matter, JCAP 05 (2021) 013 [arXiv:2102.06215] [INSPIRE].
F. D’Eramo and A. Lenoci, Lower mass bounds on FIMP dark matter produced via freeze-in, JCAP 10 (2021) 045 [arXiv:2012.01446] [INSPIRE].
E. Witten, Cosmic Separation of Phases, Phys. Rev. D 30 (1984) 272 [INSPIRE].
I. Garcia Garcia, R. Lasenby and J. March-Russell, Twin Higgs Asymmetric Dark Matter, Phys. Rev. Lett. 115 (2015) 121801 [arXiv:1505.07410] [INSPIRE].
M. Breitbach, J. Kopp, E. Madge, T. Opferkuch and P. Schwaller, Dark, Cold, and Noisy: Constraining Secluded Hidden Sectors with Gravitational Waves, JCAP 07 (2019) 007 [arXiv:1811.11175] [INSPIRE].
J. Ellis, M. Lewicki, J. M. No and V. Vaskonen, Gravitational wave energy budget in strongly supercooled phase transitions, JCAP 06 (2019) 024 [arXiv:1903.09642] [INSPIRE].
C. Caprini et al., Science with the space-based interferometer eLISA. II: Gravitational waves from cosmological phase transitions, JCAP 04 (2016) 001 [arXiv:1512.06239] [INSPIRE].
P. A. Rosado, Gravitational wave background from binary systems, Phys. Rev. D 84 (2011) 084004 [arXiv:1106.5795] [INSPIRE].
A. J. Farmer and E. S. Phinney, The gravitational wave background from cosmological compact binaries, Mon. Not. Roy. Astron. Soc. 346 (2003) 1197 [astro-ph/0304393] [INSPIRE].
A. J. Ruiter, K. Belczynski, M. Benacquista, S. L. Larson and G. Williams, The LISA Gravitational Wave Foreground: A Study of Double White Dwarfs, Astrophys. J. 717 (2010) 1006 [arXiv:0705.3272] [INSPIRE].
D. I. Kosenko and K. A. Postnov, On the gravitational wave noise from unresolved extragalactic binaries, Astron. Astrophys. 336 (1998) 786 [astro-ph/9801032] [INSPIRE].
M. R. Adams and N. J. Cornish, Discriminating between a Stochastic Gravitational Wave Background and Instrument Noise, Phys. Rev. D 82 (2010) 022002 [arXiv:1002.1291] [INSPIRE].
M. R. Adams and N. J. Cornish, Detecting a Stochastic Gravitational Wave Background in the presence of a Galactic Foreground and Instrument Noise, Phys. Rev. D 89 (2014) 022001 [arXiv:1307.4116] [INSPIRE].
T. Regimbau, M. Evans, N. Christensen, E. Katsavounidis, B. Sathyaprakash and S. Vitale, Digging deeper: Observing primordial gravitational waves below the binary black hole produced stochastic background, Phys. Rev. Lett. 118 (2017) 151105 [arXiv:1611.08943] [INSPIRE].
S. Sachdev, T. Regimbau and B. S. Sathyaprakash, Subtracting compact binary foreground sources to reveal primordial gravitational-wave backgrounds, Phys. Rev. D 102 (2020) 024051 [arXiv:2002.05365] [INSPIRE].
R. Contino, K. Max and R. K. Mishra, Searching for elusive dark sectors with terrestrial and celestial observations, JHEP 06 (2021) 127 [arXiv:2012.08537] [INSPIRE].
P. Gondolo and G. Gelmini, Cosmic abundances of stable particles: Improved analysis, Nucl. Phys. B 360 (1991) 145 [INSPIRE].
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Garani, R., Redi, M. & Tesi, A. Dark QCD matters. J. High Energ. Phys. 2021, 139 (2021). https://doi.org/10.1007/JHEP12(2021)139
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DOI: https://doi.org/10.1007/JHEP12(2021)139