Abstract
We consider the absorption by bound electrons of dark matter in the form of dark photons and axion-like particles, as well as of dark photons from the Sun, in current and next-generation direct detection experiments. Experiments sensitive to electron recoils can detect such particles with masses between a few eV to more than 10 keV. For dark photon dark matter, we update a previous bound based on XENON10 data and derive new bounds based on data from XENON100 and CDMSlite. We find these experiments to disfavor previously allowed parameter space. Moreover, we derive sensitivity projections for SuperCDMS at SNOLAB for silicon and germanium targets, as well as for various possible experiments with scintillating targets (cesium iodide, sodium iodide, and gallium arsenide). The projected sensitivity can probe large new regions of parameter space. For axion-like particles, the same current direction detection data improves on previously known direct-detection constraints but does not bound new parameter space beyond known stellar cooling bounds. However, projected sensitivities of the upcoming SuperCDMS SNOLAB using germanium can go beyond these and even probe parameter space consistent with possible hints from the white dwarf luminosity function. We find similar results for dark photons from the sun. For all cases, direct-detection experiments can have unprecedented sensitivity to dark-sector particles.
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P. Cushman et al., Working group report: WIMP dark matter direct detection, in Community Summer Study 2013: Snowmass on the Mississippi (CSS2013), Minneapolis MN U.S.A., 29 July-6 August 2013 [arXiv:1310.8327] [INSPIRE].
M. Pospelov, A. Ritz and M.B. Voloshin, Bosonic super-WIMPs as keV-scale dark matter, Phys. Rev. D 78 (2008) 115012 [arXiv:0807.3279] [INSPIRE].
J. Jaeckel and A. Ringwald, A cavity experiment to search for hidden sector photons, Phys. Lett. B 659 (2008) 509 [arXiv:0707.2063] [INSPIRE].
M. Ahlers, H. Gies, J. Jaeckel, J. Redondo and A. Ringwald, Light from the hidden sector, Phys. Rev. D 76 (2007) 115005 [arXiv:0706.2836] [INSPIRE].
ADMX collaboration, A. Wagner et al., A search for hidden sector photons with ADMX, Phys. Rev. Lett. 105 (2010) 171801 [arXiv:1007.3766] [INSPIRE].
R. Povey, J. Hartnett and M. Tobar, Microwave cavity light shining through a wall optimization and experiment, Phys. Rev. D 82 (2010) 052003 [arXiv:1003.0964] [INSPIRE].
D. Horns, J. Jaeckel, A. Lindner, A. Lobanov, J. Redondo and A. Ringwald, Searching for WISPy cold dark matter with a dish antenna, JCAP 04 (2013) 016 [arXiv:1212.2970] [INSPIRE].
S.R. Parker, G. Rybka and M.E. Tobar, Hidden sector photon coupling of resonant cavities, Phys. Rev. D 87 (2013) 115008 [arXiv:1304.6866] [INSPIRE].
M. Betz, F. Caspers, M. Gasior, M. Thumm and S.W. Rieger, First results of the CERN resonant weakly interacting sub-eV particle search (CROWS), Phys. Rev. D 88 (2013) 075014 [arXiv:1310.8098] [INSPIRE].
B. Döbrich et al., Hidden photon dark matter search with a large metallic mirror, arXiv:1410.0200 [INSPIRE].
S. Chaudhuri, P.W. Graham, K. Irwin, J. Mardon, S. Rajendran and Y. Zhao, Radio for hidden-photon dark matter detection, Phys. Rev. D 92 (2015) 075012 [arXiv:1411.7382] [INSPIRE].
P.W. Graham, J. Mardon, S. Rajendran and Y. Zhao, Parametrically enhanced hidden photon search, Phys. Rev. D 90 (2014) 075017 [arXiv:1407.4806] [INSPIRE].
C. Kouvaris and J. Pradler, Probing sub-GeV dark matter with conventional detectors, Phys. Rev. Lett. 118 (2017) 031803 [arXiv:1607.01789] [INSPIRE].
S. Weinberg, A new light boson?, Phys. Rev. Lett. 40 (1978) 223 [INSPIRE].
F. Wilczek, Problem of strong p and t invariance in the presence of instantons, Phys. Rev. Lett. 40 (1978) 279 [INSPIRE].
R.D. Peccei and H.R. Quinn, CP conservation in the presence of instantons, Phys. Rev. Lett. 38 (1977) 1440 [INSPIRE].
S. Dimopoulos, G.D. Starkman and B.W. Lynn, Atomic enhancements in the detection of weakly interacting particles, Phys. Lett. B 168 (1986) 145 [INSPIRE].
F.T. Avignone III et al., Laboratory limits on solar axions from an ultralow background germanium spectrometer, Phys. Rev. D 35 (1987) 2752 [INSPIRE].
CoGeNT collaboration, C.E. Aalseth et al., Experimental constraints on a dark matter origin for the DAMA annual modulation effect, Phys. Rev. Lett. 101 (2008) 251301 [Erratum ibid. 102 (2009) 109903] [arXiv:0807.0879] [INSPIRE].
CDMS collaboration, Z. Ahmed et al., Search for axions with the CDMS experiment, Phys. Rev. Lett. 103 (2009) 141802 [arXiv:0902.4693] [INSPIRE].
E. Armengaud et al., Axion searches with the EDELWEISS-II experiment, JCAP 11 (2013) 067 [arXiv:1307.1488] [INSPIRE].
XENON100 collaboration, E. Aprile et al., First axion results from the XENON100 experiment, Phys. Rev. D 90 (2014) 062009 [Erratum ibid. D 95 (2017) 029904] [arXiv:1404.1455] [INSPIRE].
KIMS collaboration, Y.S. Yoon et al., Search for solar axions with CsI(Tl) crystal detectors, JHEP 06 (2016) 011 [arXiv:1604.01825] [INSPIRE].
B. Holdom, Two U(1)′ s and ϵ charge shifts, Phys. Lett. B 166 (1986) 196 [INSPIRE].
P. Galison and A. Manohar, Two Z ′ s or not two Z ′ s?, Phys. Lett. B 136 (1984) 279 [INSPIRE].
N. Arkani-Hamed, D.P. Finkbeiner, T.R. Slatyer and N. Weiner, A theory of dark matter, Phys. Rev. D 79 (2009) 015014 [arXiv:0810.0713] [INSPIRE].
M. Pospelov, A. Ritz and M.B. Voloshin, Secluded WIMP dark matter, Phys. Lett. B 662 (2008) 53 [arXiv:0711.4866] [INSPIRE].
M. Pospelov and A. Ritz, Astrophysical signatures of secluded dark matter, Phys. Lett. B 671 (2009) 391 [arXiv:0810.1502] [INSPIRE].
J. Jaeckel and A. Ringwald, The low-energy frontier of particle physics, Ann. Rev. Nucl. Part. Sci. 60 (2010) 405 [arXiv:1002.0329] [INSPIRE].
J. Hewett et al., Fundamental physics at the intensity frontier, arXiv:1205.2671 [INSPIRE].
R. Essig et al., Working group report: new light weakly coupled particles, arXiv:1311.0029 [INSPIRE].
A.E. Nelson and J. Scholtz, Dark light, dark matter and the misalignment mechanism, Phys. Rev. D 84 (2011) 103501 [arXiv:1105.2812] [INSPIRE].
P. Arias, D. Cadamuro, M. Goodsell, J. Jaeckel, J. Redondo and A. Ringwald, WISPy cold dark matter, JCAP 06 (2012) 013 [arXiv:1201.5902] [INSPIRE].
P.W. Graham, J. Mardon and S. Rajendran, Vector dark matter from inflationary fluctuations, Phys. Rev. D 93 (2016) 103520 [arXiv:1504.02102] [INSPIRE].
H. An, M. Pospelov, J. Pradler and A. Ritz, Direct detection constraints on dark photon dark matter, Phys. Lett. B 747 (2015) 331 [arXiv:1412.8378] [INSPIRE].
R. Essig, J. Mardon and T. Volansky, Direct detection of sub-GeV dark matter, Phys. Rev. D 85 (2012) 076007 [arXiv:1108.5383] [INSPIRE].
XENON10 collaboration, J. Angle et al., A search for light dark matter in XENON10 data, Phys. Rev. Lett. 107 (2011) 051301 [Erratum ibid. 110 (2013) 249901] [arXiv:1104.3088] [INSPIRE].
R. Essig, A. Manalaysay, J. Mardon, P. Sorensen and T. Volansky, First direct detection limits on sub-GeV dark matter from XENON10, Phys. Rev. Lett. 109 (2012) 021301 [arXiv:1206.2644] [INSPIRE].
XENON collaboration, E. Aprile et al., Low-mass dark matter search using ionization signals in XENON100, Phys. Rev. D 94 (2016) 092001 [Erratum ibid. D 95 (2017) 059901] [arXiv:1605.06262] [INSPIRE].
SuperCDMS collaboration, R. Agnese et al., New results from the search for low-mass weakly interacting massive particles with the CDMS low ionization threshold experiment, Phys. Rev. Lett. 116 (2016) 071301 [arXiv:1509.02448] [INSPIRE].
G. Fernandez Moroni, J. Estrada, G. Cancelo, S.E. Holland, E.E. Paolini and H.T. Diehl, Sub-electron readout noise in a Skipper CCD fabricated on high resistivity silicon, Exper. Astron. 34 (2012) 43 [arXiv:1106.1839] [INSPIRE].
DAMIC collaboration, A. Aguilar-Arevalo et al., Search for low-mass WIMPs in a 0.6 kg day exposure of the DAMIC experiment at SNOLAB, Phys. Rev. D 94 (2016) 082006 [arXiv:1607.07410] [INSPIRE].
R. Essig, M. Fernandez-Serra, J. Mardon, A. Soto, T. Volansky and T.-T. Yu, Direct detection of sub-GeV dark matter with semiconductor targets, JHEP 05 (2016) 046 [arXiv:1509.01598] [INSPIRE].
P.W. Graham, D.E. Kaplan, S. Rajendran and M.T. Walters, Semiconductor probes of light dark matter, Phys. Dark Univ. 1 (2012) 32 [arXiv:1203.2531] [INSPIRE].
S.K. Lee, M. Lisanti, S. Mishra-Sharma and B.R. Safdi, Modulation effects in dark matter-electron scattering experiments, Phys. Rev. D 92 (2015) 083517 [arXiv:1508.07361] [INSPIRE].
Y. Hochberg, Y. Kahn, M. Lisanti, C.G. Tully and K.M. Zurek, Directional detection of dark matter with 2D targets, arXiv:1606.08849 [INSPIRE].
S. Derenzo, R. Essig, A. Massari, A. Soto and T.-T. Yu, Direct detection of sub-GeV dark matter with scintillating targets, arXiv:1607.01009 [INSPIRE].
Y. Hochberg, M. Pyle, Y. Zhao and K.M. Zurek, Detecting superlight dark matter with Fermi-degenerate materials, JHEP 08 (2016) 057 [arXiv:1512.04533] [INSPIRE].
Y. Hochberg, Y. Zhao and K.M. Zurek, Superconducting detectors for superlight dark matter, Phys. Rev. Lett. 116 (2016) 011301 [arXiv:1504.07237] [INSPIRE].
Y. Hochberg, T. Lin and K.M. Zurek, Detecting ultralight bosonic dark matter via absorption in superconductors, Phys. Rev. D 94 (2016) 015019 [arXiv:1604.06800] [INSPIRE].
R. Essig, J. Mardon, O. Slone and T. Volansky, Detection of sub-GeV dark matter and solar neutrinos via chemical-bond breaking, Phys. Rev. D 95 (2017) 056011 [arXiv:1608.02940] [INSPIRE].
R. Budnik, O. Chesnovsky, O. Slone and T. Volansky, Direct detection of light dark matter and solar neutrinos via color center production in crystals, arXiv:1705.03016 [INSPIRE].
K. Schutz and K.M. Zurek, Detectability of light dark matter with superfluid helium, Phys. Rev. Lett. 117 (2016) 121302 [arXiv:1604.08206] [INSPIRE].
A. Derevianko, V.A. Dzuba, V.V. Flambaum and M. Pospelov, Axio-electric effect, Phys. Rev. D 82 (2010) 065006 [arXiv:1007.1833] [INSPIRE].
B. Henke, E. Gullikson and J. Davis, X-ray interactions: photoabsorption, scattering, transmission, and reflection at E = 50-30, 000 eV, Z = 1-92, Atom. Data Nucl. Data Tabl. 54 (1993) 181.
X-ray interactions with matter webpage, http://henke.lbl.gov/optical_constants/.
E.D. Palik, Gallium arsenide (GaAs), in Handbook of optical constants of solids, volume 1, E.D. Palik ed., Academic Press, Boston U.S.A., (1985), pg. 429.
R.F. Potter, Germanium (Ge), in Handbook of optical constants of solids, volume 1, E.D. Palik ed., Academic Press, Boston U.S.A., (1985), pg. 465.
D.F. Edwards, Silicon (Si)*, in Handbook of optical constants of solids, volume 1, E.D. Palik ed., Academic Press, Boston U.S.A., (1985), pg. 547.
J.E. Eldridge, Cesium iodide, in Handbook of optical constants of solids, volume 2, E.D. Palik ed., Academic Press, Boston U.S.A., (1997), pg. 853.
E. Saloman and J. Hubbel, X-ray attenuation coefficients (total cross sections): comparison of the experimental data base with the recommended values of Henke and the theoretical values of Scofield for energies between 0.1-100 keV, U.S.A., (1986).
P. Sikivie, Axion cosmology, Lect. Notes Phys. 741 (2008) 19 [astro-ph/0610440] [INSPIRE].
D.J.E. Marsh, Axion cosmology, Phys. Rept. 643 (2016) 1 [arXiv:1510.07633] [INSPIRE].
J. Redondo, Solar axion flux from the axion-electron coupling, JCAP 12 (2013) 008 [arXiv:1310.0823] [INSPIRE].
F.T. Avignone, III, R.J. Creswick and S. Nussinov, Can large scintillators be used for solar-axion searches to test the cosmological axion-photon oscillation proposal?, Phys. Lett. B 681 (2009) 122 [arXiv:0903.4451] [INSPIRE].
H. An, M. Pospelov and J. Pradler, Dark matter detectors as dark photon helioscopes, Phys. Rev. Lett. 111 (2013) 041302 [arXiv:1304.3461] [INSPIRE].
J. Redondo, Helioscope bounds on hidden sector photons, JCAP 07 (2008) 008 [arXiv:0801.1527] [INSPIRE].
H. An, M. Pospelov and J. Pradler, New stellar constraints on dark photons, Phys. Lett. B 725 (2013) 190 [arXiv:1302.3884] [INSPIRE].
R. Essig, T. Volansky and T.-T. Yu, New constraints and prospects for sub-GeV dark matter scattering off electrons in xenon, arXiv:1703.00910 [INSPIRE].
SuperCDMS collaboration, S. Golwala, SuperCDMS SNOLAB: goals, design, and status, talk given at UCLA DM, Los Angeles U.S.A., (2016).
B.G. Lowe, Measurements of Fano factors in silicon and germanium in the low-energy X-ray region, Nucl. Instrum. Meth. A 399 (1997) 354.
M. Lépy, J. Campbell, J. Laborie, J. Plagnard, P. Stemmler and W. Teesdale, Experimental study of the response of semiconductor detectors to low-energy photons, Nucl. Instrum. Meth. A 439 (2000) 239.
B.G. Streetman and S. Banerjee, Solid state electronic devices, Prentice Hall, U.S.A., (2005).
C.A. Klein, Bandgap dependence and related features of radiation ionization energies in semiconductors, J. Appl. Phys. 39 (1968) 2029.
SuperCDMS collaboration, A. Robinson, Controlling cosmogenic radioactivity in SuperCDMS SNOLAB, talk given at APS April Meeting, Salt Lake City U.S.A., (2016).
DAMIC collaboration, J. Barreto et al., Direct search for low mass dark matter particles with CCDs, Phys. Lett. B 711 (2012) 264 [arXiv:1105.5191] [INSPIRE].
J. Estrada and J. Tiffenberg, private communication.
Particle Data Group collaboration, K.A. Olive et al., Review of particle physics, Chin. Phys. C 38 (2014) 090001 [INSPIRE].
G.G. Raffelt, Axion constraints from white dwarf cooling times, Phys. Lett. B 166 (1986) 402 [INSPIRE].
J. Redondo and G. Raffelt, Solar constraints on hidden photons re-visited, JCAP 08 (2013) 034 [arXiv:1305.2920] [INSPIRE].
S.I. Blinnikov and N.V. Dunina-Barkovskaya, The cooling of hot white dwarfs: a theory with non-standard weak interactions and a comparison with observations, Mon. Not. Roy. Astron. Soc. 266 (1994) 289 [INSPIRE].
M.M. Miller Bertolami, B.E. Melendez, L.G. Althaus and J. Isern, Revisiting the axion bounds from the galactic white dwarf luminosity function, JCAP 10 (2014) 069 [arXiv:1406.7712] [INSPIRE].
J. Isern, E. Garcia-Berro, S. Torres and S. Catalan, Axions and the cooling of white dwarf stars, Astrophys. J. 682 (2008) L109 [arXiv:0806.2807] [INSPIRE].
J. Isern, S. Catalan, E. Garcia-Berro and S. Torres, Axions and the white dwarf luminosity function, J. Phys. Conf. Ser. 172 (2009) 012005 [arXiv:0812.3043] [INSPIRE].
DAMIC collaboration, A. Aguilar-Arevalo et al., First direct-detection constraints on eV-scale hidden-photon dark matter with DAMIC at SNOLAB, Phys. Rev. Lett. 118 (2017) 141803 [arXiv:1611.03066] [INSPIRE].
Y. Hochberg, T. Lin and K.M. Zurek, Absorption of light dark matter in semiconductors, Phys. Rev. D 95 (2017) 023013 [arXiv:1608.01994] [INSPIRE].
C. Pena-Garay and A. Serenelli, Solar neutrinos and the solar composition problem, arXiv:0811.2424 [INSPIRE].
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Bloch, I.M., Essig, R., Tobioka, K. et al. Searching for dark absorption with direct detection experiments. J. High Energ. Phys. 2017, 87 (2017). https://doi.org/10.1007/JHEP06(2017)087
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DOI: https://doi.org/10.1007/JHEP06(2017)087