Models of ultraheavy dark matter visible to macroscopic mechanical sensing arrays
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R. Lang | C. Blanco | Bahaa Elshimy | R. Orlando | R. Lang
[1] B. Carr,et al. Primordial black holes as dark matter candidates , 2021, SciPost Physics Lecture Notes.
[2] M. J. Williams,et al. Constraints on dark photon dark matter using data from LIGO's and Virgo's third observing run , 2021, 2105.13085.
[3] O. Mena,et al. A Brief Review on Primordial Black Holes as Dark Matter , 2021, Frontiers in Astronomy and Space Sciences.
[4] N. Bernal,et al. Dark matter in the time of primordial black holes , 2020, Journal of Cosmology and Astroparticle Physics.
[5] N. Bernal,et al. Self-interacting dark matter from primordial black holes , 2020, Journal of Cosmology and Astroparticle Physics.
[6] J. Bramante,et al. Detecting composite dark matter with long-range and contact interactions in gas clouds , 2020, 2010.07240.
[7] M. Clark,et al. Direct detection limits on heavy dark matter , 2020, Physical Review D.
[8] Barmak Shams Es Haghi,et al. The Effects of Primordial Black Holes on Dark Matter Models , 2020, 2009.02424.
[9] D. Moore,et al. Searching for new physics using optically levitated sensors , 2020, Quantum Science and Technology.
[10] J. Lykken,et al. Mechanical quantum sensing in the search for dark matter , 2020, Quantum Science and Technology.
[11] Sunghoon Jung,et al. Fermi-ball dark matter from a first-order phase transition , 2020, 2008.04430.
[12] A. Zadro.zny,et al. Limits on the Flux of Nuclearites and Other Heavy Compact Objects from the Pi of the Sky Project. , 2020, Physical review letters.
[13] D. Moore,et al. Search for Composite Dark Matter with Optically Levitated Sensors. , 2020, Physical review letters.
[14] D. Grin,et al. Searching for Vector Dark Matter with an Optomechanical Accelerometer. , 2020, Physical review letters.
[15] Jing Ren,et al. Not quite black holes as dark matter , 2020, 2003.10682.
[16] Siyi Zhou,et al. Cosmological signatures of superheavy dark matter , 2020, Journal of High Energy Physics.
[17] H. Veermäe,et al. Horizonless ultracompact objects and dark matter in quadratic gravity , 2019, Journal of Cosmology and Astroparticle Physics.
[18] J. Sidhu. Charge constraints of macroscopic dark matter , 2019, Physical Review D.
[19] Jacob M. Taylor,et al. Backaction-evading impulse measurement with mechanical quantum sensors , 2019, 1910.11892.
[20] D. Grin,et al. Searching for Scalar Dark Matter with Compact Mechanical Resonators. , 2019, Physical review letters.
[21] J. Beacom,et al. Not as big as a barn: Upper bounds on dark matter-nucleus cross sections , 2019, Physical Review D.
[22] G. Starkman,et al. Death and serious injury from dark matter , 2019, Physics Letters B.
[23] Yang Bai,et al. Electroweak symmetric dark matter balls , 2019, Journal of High Energy Physics.
[24] Christian I. Johnson,et al. Direct detection of primordial black hole relics as dark matter , 2019, Journal of Cosmology and Astroparticle Physics.
[25] Yang Bai,et al. Primordial extremal black holes as dark matter , 2019, Physical Review D.
[26] J. Silk,et al. Constraining primordial black hole masses with the isotropic gamma ray background , 2019, Physical Review D.
[27] D. Hooper,et al. Dark radiation and superheavy dark matter from black hole domination , 2019, Journal of High Energy Physics.
[28] Jacob M. Taylor,et al. Proposal for gravitational direct detection of dark matter , 2019, 1903.00492.
[29] N. W. Evans,et al. Refinement of the standard halo model for dark matter searches in light of the Gaia Sausage , 2019, Physical Review D.
[30] A. Tesi,et al. Cosmological production of dark nuclei , 2018, Journal of High Energy Physics.
[31] A. J. Long,et al. Dark quark nuggets , 2018, Physical Review D.
[32] H. Nicolai,et al. Planck mass charged gravitino dark matter , 2018, Physical Review D.
[33] A. Kawasaki. Search for kilogram-scale dark matter with precision displacement sensors , 2018, Physical Review D.
[34] M. Ahlers,et al. Probing particle physics with IceCube , 2018, The European Physical Journal C.
[35] V. Narayan,et al. White dwarfs as dark matter detectors , 2018, Physical Review D.
[36] H. K. Lou,et al. Astrophysical signatures of asymmetric dark matter bound states , 2018, Physical Review D.
[37] H. K. Lou,et al. Early Universe synthesis of asymmetric dark matter nuggets , 2018 .
[38] D. F. Kimball,et al. Searching for axion stars and Q -balls with a terrestrial magnetometer network , 2017, 1710.04323.
[39] A. J. Long,et al. Superheavy dark matter through Higgs portal operators , 2017, 1708.04293.
[40] H. K. Lou,et al. Nuclear structure of bound states of asymmetric dark matter , 2017, 1707.02313.
[41] A. Kusenko,et al. Astrophysical constraints on dark-matter Q -balls in the presence of baryon-violating operators , 2016, 1609.00970.
[42] H. K. Lou,et al. GUTzilla dark matter , 2016, 1606.00923.
[43] R. Massey,et al. What does the Bullet Cluster tell us about Self-Interacting Dark Matter? , 2016, 1605.04307.
[44] R. Adhikari,et al. Laser interferometers as dark matter detectors , 2016, Physical Review D.
[45] M. Kawasaki,et al. Charged Q-ball dark matter from B and L direction , 2016, 1604.04352.
[46] E. Mayotte. Searching for slow-developing cosmic-ray showers : looking for evidence of exotic primaries at the Pierre Auger Observatory , 2016 .
[47] Y. Minenkov,et al. Dark matter searches using gravitational wave bar detectors: Quark nuggets and newtorites , 2015, 1512.06249.
[48] Seyen Kouwn,et al. Classically scale invariant inflation, supermassive WIMPs, and adimensional gravity , 2015, 1512.05890.
[49] M. Garny,et al. Planckian Interacting Massive Particles as Dark Matter. , 2015, Physical review letters.
[50] M. Pshirkov,et al. Prospects for strangelet detection with large-scale cosmic ray observatories , 2015, 1509.05553.
[51] J. March-Russell,et al. Signatures of large composite Dark Matter states , 2015, 1504.05419.
[52] J. March-Russell,et al. Big Bang synthesis of nuclear dark matter , 2014, 1411.3739.
[53] Glenn D. Starkman,et al. Macro Dark Matter , 2014, 1410.2236.
[54] E. Kolb,et al. Irruption of massive particle species during inflation , 2014, 1409.1584.
[55] M. McCullough,et al. Dark nuclei. II. Nuclear spectroscopy in two-color QCD , 2014, 1406.4116.
[56] M. McCullough,et al. Dark nuclei. I. Cosmology and indirect detection , 2014, 1406.2276.
[57] K. Sigurdson,et al. Big Bang Darkleosynthesis , 2014, 1406.1171.
[58] J. Read. The local dark matter density , 2014, 1404.1938.
[59] S. Park,et al. A testable scenario of WIMPZILLA with dark radiation , 2013, 1305.5013.
[60] E. Pitjeva,et al. Constraints on dark matter in the solar system , 2013, 1306.5534.
[61] V. Rubakov,et al. Cosmological phase transition, baryon asymmetry, and dark matter Q-balls , 2013, 1301.0354.
[62] J. Gundlach,et al. Torsion-balance tests of the weak equivalence principle , 2012, 1207.2442.
[63] J. Pinfold,et al. Results of the search for strange quark matter and Q-balls with the SLIM experiment , 2008, 0805.1797.
[64] S Schlamminger,et al. Test of the equivalence principle using a rotating torsion balance. , 2007, Physical review letters.
[65] A. Kusenko. Properties and signatures of supersymmetric Q-balls , 2006, hep-ph/0612159.
[66] M. Dine,et al. Origin of the matter-antimatter asymmetry , 2003, hep-ph/0303065.
[67] T. Yoshida,et al. Stable neutral Fermi ball , 2002, hep-ph/0212332.
[68] T. M. Collaboration,et al. Final results of magnetic monopole searches with the MACRO experiment , 2002, hep-ex/0207020.
[69] A. Zhitnitsky. `Nonbaryonic' dark matter as baryonic colour superconductor , 2002, hep-ph/0202161.
[70] K. Enqvist,et al. Constraints on self-interacting Q-ball dark matter , 2001, hep-ph/0111348.
[71] D. Stojkovic. Nontopological solitons in brane world models , 2001, hep-ph/0111061.
[72] P. Steinhardt,et al. Q-ball candidates for self-interacting dark matter. , 2001, Physical review letters.
[73] E. Kolb,et al. Gravitational production of superheavy dark matter , 2001, hep-ph/0104100.
[74] T. Yoshida,et al. Experimental bounds on masses and fluxes of nontopological solitons , 2000, hep-ph/0005103.
[75] E. Kolb,et al. Probing Planckian physics : resonant production of particles during inflation and features in the primordial power spectrum , 1999, hep-ph/9910437.
[76] A. Riotto,et al. WIMPZILLAS! , 1998, hep-ph/9810361.
[77] V. Kuzmin,et al. Matter creation via vacuum fluctuations in the early Universe and observed ultrahigh energy cosmic ray events , 1998, hep-ph/9809547.
[78] E. Kolb,et al. Nonthermal Supermassive Dark Matter , 1998, hep-ph/9805473.
[79] M. Shaposhnikov,et al. Supersymmetric Q-balls as dark matter , 1997, hep-ph/9709492.
[80] A. Kusenko. Solitons in the supersymmetric extensions of the standard model , 1997, hep-ph/9704273.
[81] A. Macpherson,et al. Biased discrete symmetry breaking and Fermi balls , 1994, hep-ph/9408387.
[82] Daksh Lohia. Non - Topological Solitons in non-minimally coupled Scalar fields: Theory and consequences , 1994, gr-qc/9407014.
[83] Price. Limits on contribution of cosmic nuclearites to galactic dark matter. , 1988, Physical review. D, Particles and fields.
[84] J. MacGibbon. Can Planck-mass relics of evaporating black holes close the Universe? , 1987, Nature.
[85] Holdom,et al. Cosmic balls of trapped neutrinos. , 1987, Physical review. D, Particles and fields.
[86] S. Theisen. Fourth-order supergravity S. Theisen, Nucl. Phys. B263 (1986) 687 Appendum , 1986 .
[87] I. Affleck,et al. A NEW MECHANISM FOR BARYOGENESIS , 1985 .
[88] S. Glashow,et al. Nuclearites—a novel form of cosmic radiation , 1984, Nature.
[89] T. D. Lee,et al. Class of scalar-field soliton solutions in three space dimensions , 1976 .
[90] A. Berlin,et al. WIMPs with GUTs: Dark Matter Coannihilation with a Lighter Species , 2017 .
[91] Edwax 'd % 'itten. Cosmic separation of phases , 2011 .
[92] D. Chung. SUPERHEAVY DARK MATTER a , 1998 .
[93] Joshua,et al. SOLITOGENESIS : PRIMORDIAL ORIGIN OF NON-TOPOLOGICAL SOLITONS , 1988 .