Abstract
We revisit the calculation of bosonic dark matter absorption via electronic excitations. Working in an effective field theory framework and consistently taking into account in-medium effects, we clarify the relation between dark matter and photon absorption. As is well-known, for vector (dark photon) and pseudoscalar (axion-like particle) dark matter, the absorption rates can be simply related to the target material’s optical properties. However, this is not the case for scalar dark matter, where the dominant contribution comes from a different operator than the one contributing to photon absorption, which is formally next-to-leading-order and does not suffer from in-medium screening. It is therefore imperative to have reliable first-principles numerical calculations and/or semi-analytic modeling in order to predict the detection rate. We present updated sensitivity projections for semiconductor crystal and superconductor targets for ongoing and proposed direct detection experiments.
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SENSEI collaboration, Single-electron and single-photon sensitivity with a silicon Skipper CCD, Phys. Rev. Lett. 119 (2017) 131802 [arXiv:1706.00028] [INSPIRE].
M. Pyle, E. Feliciano-Figueroa and B. Sadoulet, Optimized Designs for Very Low Temperature Massive Calorimeters, arXiv:1503.01200 [INSPIRE].
J. Rothe et al., TES-Based Light Detectors for the CRESST Direct Dark Matter Search, J. Low Temp. Phys. 193 (2018) 1160 [INSPIRE].
C.W. Fink et al., Characterizing TES Power Noise for Future Single Optical-Phonon and Infrared-Photon Detectors, AIP Adv. 10 (2020) 085221 [arXiv:2004.10257] [INSPIRE].
C. Chang et al., Snowmass 2021 Letter of Interest: The TESSARACT Dark Matter Project, https://www.snowmass21.org/docs/files/summaries/CF/SNOWMASS21-CF1_CF2-IF1_IF8-120.pdf (2020).
I. Colantoni et al., BULLKID: BULky and Low-Threshold Kinetic Inductance Detectors, J. Low Temp. Phys. 199 (2020) 593 [INSPIRE].
H.J. Maris, G.M. Seidel and D. Stein, Dark Matter Detection Using Helium Evaporation and Field Ionization, Phys. Rev. Lett. 119 (2017) 181303 [arXiv:1706.00117] [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].
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].
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].
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].
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].
S. Derenzo, R. Essig, A. Massari, A. Soto and T.-T. Yu, Direct Detection of sub-GeV Dark Matter with Scintillating Targets, Phys. Rev. D 96 (2017) 016026 [arXiv:1607.01009] [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].
I.M. Bloch, R. Essig, K. Tobioka, T. Volansky and T.-T. Yu, Searching for Dark Absorption with Direct Detection Experiments, JHEP 06 (2017) 087 [arXiv:1608.02123] [INSPIRE].
N.A. Kurinsky, T.C. Yu, Y. Hochberg and B. Cabrera, Diamond Detectors for Direct Detection of Sub-GeV Dark Matter, Phys. Rev. D 99 (2019) 123005 [arXiv:1901.07569] [INSPIRE].
T. Trickle, Z. Zhang, K.M. Zurek, K. Inzani and S. Griffin, Multi-Channel Direct Detection of Light Dark Matter: Theoretical Framework, JHEP 03 (2020) 036 [arXiv:1910.08092] [INSPIRE].
S.M. Griffin, K. Inzani, T. Trickle, Z. Zhang and K.M. Zurek, Multichannel direct detection of light dark matter: Target comparison, Phys. Rev. D 101 (2020) 055004 [arXiv:1910.10716] [INSPIRE].
S.M. Griffin, Y. Hochberg, K. Inzani, N. Kurinsky, T. Lin and T. Chin, Silicon carbide detectors for sub-GeV dark matter, Phys. Rev. D 103 (2021) 075002 [arXiv:2008.08560] [INSPIRE].
P. Du, D. Egana-Ugrinovic, R. Essig and M. Sholapurkar, Sources of Low-Energy Events in Low-Threshold Dark Matter Detectors, arXiv:2011.13939 [INSPIRE].
S.M. Griffin, K. Inzani, T. Trickle, Z. Zhang and K.M. Zurek, Extended Calculation of Dark Matter-Electron Scattering in Crystal Targets, arXiv:2105.05253 [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, 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, 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].
Y. Hochberg et al., Detection of sub-MeV Dark Matter with Three-Dimensional Dirac Materials, Phys. Rev. D 97 (2018) 015004 [arXiv:1708.08929] [INSPIRE].
A. Coskuner, A. Mitridate, A. Olivares and K.M. Zurek, Directional Dark Matter Detection in Anisotropic Dirac Materials, Phys. Rev. D 103 (2021) 016006 [arXiv:1909.09170] [INSPIRE].
R.M. Geilhufe, F. Kahlhoefer and M.W. Winkler, Dirac Materials for Sub-MeV Dark Matter Detection: New Targets and Improved Formalism, Phys. Rev. D 101 (2020) 055005 [arXiv:1910.02091] [INSPIRE].
K. Inzani, A. Faghaninia and S.M. Griffin, Prediction of Tunable Spin-Orbit Gapped Materials for Dark Matter Detection, Phys. Rev. Res. 3 (2021) 013069 [arXiv:2008.05062] [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].
V.A. Dzuba, V.V. Flambaum and M. Pospelov, Atomic Ionization by keV-scale Pseudoscalar Dark Matter Particles, Phys. Rev. D 81 (2010) 103520 [arXiv:1002.2979] [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].
S. Knapen, T. Lin and K.M. Zurek, Light Dark Matter in Superfluid Helium: Detection with Multi-excitation Production, Phys. Rev. D 95 (2017) 056019 [arXiv:1611.06228] [INSPIRE].
A. Arvanitaki, S. Dimopoulos and K. Van Tilburg, Resonant absorption of bosonic dark matter in molecules, Phys. Rev. X 8 (2018) 041001 [arXiv:1709.05354] [INSPIRE].
S. Knapen, T. Lin, M. Pyle and K.M. Zurek, Detection of Light Dark Matter With Optical Phonons in Polar Materials, Phys. Lett. B 785 (2018) 386 [arXiv:1712.06598] [INSPIRE].
S. Griffin, S. Knapen, T. Lin and K.M. Zurek, Directional Detection of Light Dark Matter with Polar Materials, Phys. Rev. D 98 (2018) 115034 [arXiv:1807.10291] [INSPIRE].
M. Lawson, A.J. Millar, M. Pancaldi, E. Vitagliano and F. Wilczek, Tunable axion plasma haloscopes, Phys. Rev. Lett. 123 (2019) 141802 [arXiv:1904.11872] [INSPIRE].
G.B. Gelmini, A.J. Millar, V. Takhistov and E. Vitagliano, Probing dark photons with plasma haloscopes, Phys. Rev. D 102 (2020) 043003 [arXiv:2006.06836] [INSPIRE].
G.B. Gelmini, V. Takhistov and E. Vitagliano, Scalar direct detection: In-medium effects, Phys. Lett. B 809 (2020) 135779 [arXiv:2006.13909] [INSPIRE].
I.M. Bloch, A. Caputo, R. Essig, D. Redigolo, M. Sholapurkar and T. Volansky, Exploring new physics with O(keV) electron recoils in direct detection experiments, JHEP 01 (2021) 178 [arXiv:2006.14521] [INSPIRE].
H.B.T. Tan, A. Derevianko, V.A. Dzuba and V.V. Flambaum, Atomic Ionization by Scalar Dark Matter and Solar Scalars, Phys. Rev. Lett. 127 (2021) 081301 [arXiv:2105.08296] [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].
P. Agrawal, N. Kitajima, M. Reece, T. Sekiguchi and F. Takahashi, Relic Abundance of Dark Photon Dark Matter, Phys. Lett. B 801 (2020) 135136 [arXiv:1810.07188] [INSPIRE].
J.A. Dror, K. Harigaya and V. Narayan, Parametric Resonance Production of Ultralight Vector Dark Matter, Phys. Rev. D 99 (2019) 035036 [arXiv:1810.07195] [INSPIRE].
R.T. Co, A. Pierce, Z. Zhang and Y. Zhao, Dark Photon Dark Matter Produced by Axion Oscillations, Phys. Rev. D 99 (2019) 075002 [arXiv:1810.07196] [INSPIRE].
M. Bastero-Gil, J. Santiago, L. Ubaldi and R. Vega-Morales, Vector dark matter production at the end of inflation, JCAP 04 (2019) 015 [arXiv:1810.07208] [INSPIRE].
A.J. Long and L.-T. Wang, Dark Photon Dark Matter from a Network of Cosmic Strings, Phys. Rev. D 99 (2019) 063529 [arXiv:1901.03312] [INSPIRE].
J. Preskill, M.B. Wise and F. Wilczek, Cosmology of the Invisible Axion, Phys. Lett. B 120 (1983) 127 [INSPIRE].
L.F. Abbott and P. Sikivie, A Cosmological Bound on the Invisible Axion, Phys. Lett. B 120 (1983) 133 [INSPIRE].
M. Dine and W. Fischler, The Not So Harmless Axion, Phys. Lett. B 120 (1983) 137 [INSPIRE].
R.L. Davis, Cosmic Axions from Cosmic Strings, Phys. Lett. B 180 (1986) 225 [INSPIRE].
M. Gorghetto, E. Hardy and G. Villadoro, Axions from Strings: the Attractive Solution, JHEP 07 (2018) 151 [arXiv:1806.04677] [INSPIRE].
M. Gorghetto, E. Hardy and G. Villadoro, More axions from strings, SciPost Phys. 10 (2021) 050 [arXiv:2007.04990] [INSPIRE].
D.H. Lyth, Axions and inflation: Sitting in the vacuum, Phys. Rev. D 45 (1992) 3394 [INSPIRE].
L. Visinelli and P. Gondolo, Axion cold dark matter in non-standard cosmologies, Phys. Rev. D 81 (2010) 063508 [arXiv:0912.0015] [INSPIRE].
R.T. Co, E. Gonzalez and K. Harigaya, Axion Misalignment Driven to the Hilltop, JHEP 05 (2019) 163 [arXiv:1812.11192] [INSPIRE].
R.T. Co, L.J. Hall and K. Harigaya, Axion Kinetic Misalignment Mechanism, Phys. Rev. Lett. 124 (2020) 251802 [arXiv:1910.14152] [INSPIRE].
R.T. Co, L.J. Hall, K. Harigaya, K.A. Olive and S. Verner, Axion Kinetic Misalignment and Parametric Resonance from Inflation, JCAP 08 (2020) 036 [arXiv:2004.00629] [INSPIRE].
Y. Hochberg, Y. Kahn, N. Kurinsky, B.V. Lehmann, T.C. Yu and K.K. Berggren, Determining Dark Matter-Electron Scattering Rates from the Dielectric Function, arXiv:2101.08263 [INSPIRE].
S. Knapen, J. Kozaczuk and T. Lin, Dark matter-electron scattering in dielectrics, Phys. Rev. D 104 (2021) 015031 [arXiv:2101.08275] [INSPIRE].
S. Knapen, J. Kozaczuk and T. Lin, DarkELF: A python package for dark matter scattering in dielectric targets, arXiv:2104.12786 [INSPIRE].
DAMIC collaboration, The DAMIC dark matter experiment, PoS ICRC2015 (2016) 1221 [arXiv:1510.02126] [INSPIRE].
DAMIC collaboration, Constraints on Light Dark Matter Particles Interacting with Electrons from DAMIC at SNOLAB, Phys. Rev. Lett. 123 (2019) 181802 [arXiv:1907.12628] [INSPIRE].
DAMIC, DAMIC-M collaboration, Search for low-mass dark matter with the DAMIC experiment, in 16th Rencontres du Vietnam: Theory meeting experiment: Particle Astrophysics and Cosmology, Quy Nhon Vietnam (2020) [arXiv:2003.09497] [INSPIRE].
EDELWEISS collaboration, Searches for electron interactions induced by new physics in the EDELWEISS-III Germanium bolometers, Phys. Rev. D 98 (2018) 082004 [arXiv:1808.02340] [INSPIRE].
EDELWEISS collaboration, Searching for low-mass dark matter particles with a massive Ge bolometer operated above-ground, Phys. Rev. D 99 (2019) 082003 [arXiv:1901.03588] [INSPIRE].
EDELWEISS collaboration, First germanium-based constraints on sub-MeV Dark Matter with the EDELWEISS experiment, Phys. Rev. Lett. 125 (2020) 141301 [arXiv:2003.01046] [INSPIRE].
SENSEI collaboration, SENSEI: First Direct-Detection Constraints on sub-GeV Dark Matter from a Surface Run, Phys. Rev. Lett. 121 (2018) 061803 [arXiv:1804.00088] [INSPIRE].
SENSEI collaboration, SENSEI: Direct-Detection Constraints on Sub-GeV Dark Matter from a Shallow Underground Run Using a Prototype Skipper-CCD, Phys. Rev. Lett. 122 (2019) 161801 [arXiv:1901.10478] [INSPIRE].
SENSEI collaboration, SENSEI: Direct-Detection Results on sub-GeV Dark Matter from a New Skipper-CCD, Phys. Rev. Lett. 125 (2020) 171802 [arXiv:2004.11378] [INSPIRE].
SuperCDMS collaboration, Search for Low-Mass Weakly Interacting Massive Particles with SuperCDMS, Phys. Rev. Lett. 112 (2014) 241302 [arXiv:1402.7137] [INSPIRE].
SuperCDMS collaboration, 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].
SuperCDMS collaboration, Projected Sensitivity of the SuperCDMS SNOLAB experiment, Phys. Rev. D 95 (2017) 082002 [arXiv:1610.00006] [INSPIRE].
SuperCDMS collaboration, Low-mass dark matter search with CDMSlite, Phys. Rev. D 97 (2018) 022002 [arXiv:1707.01632] [INSPIRE].
SuperCDMS collaboration, First Dark Matter Constraints from a SuperCDMS Single-Charge Sensitive Detector, Phys. Rev. Lett. 121 (2018) 051301 [Erratum ibid. 122 (2019) 069901] [arXiv:1804.10697] [INSPIRE].
SuperCDMS collaboration, Search for Low-Mass Dark Matter with CDMSlite Using a Profile Likelihood Fit, Phys. Rev. D 99 (2019) 062001 [arXiv:1808.09098] [INSPIRE].
SuperCDMS collaboration, Constraints on low-mass, relic dark matter candidates from a surface-operated SuperCDMS single-charge sensitive detector, Phys. Rev. D 102 (2020) 091101 [arXiv:2005.14067] [INSPIRE].
S.M. Griffin, K. Inzani, T. Trickle, Z. Zhang and K.M. Zurek, EXCEED-DM: DFT-computed electronic wave functions for Si and Ge, zenodo (2021).
EXCEED-DM collaboration, EXCEED-DM-v0.2.0, zenodo (2021).
I.Z. Rothstein, TASI lectures on effective field theories, hep-ph/0308266 [INSPIRE].
R. Penco, An Introduction to Effective Field Theories, arXiv:2006.16285 [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].
A. Derevianko, V.A. Dzuba, V.V. Flambaum and M. Pospelov, Axio-electric effect, Phys. Rev. D 82 (2010) 065006 [arXiv:1007.1833] [INSPIRE].
E.D. Palik eds., Handbook of Optical Constants of Solids, Elsevier, Amsterdam The Netherlands (1985).
R.L. Benbow and D.W. Lynch, Optical absorption in Al and dilute alloys of Mg and Li in Al at 4.2 K, Phys. Rev. B 12 (1975) 5615.
H. An, M. Pospelov and J. Pradler, New stellar constraints on dark photons, Phys. Lett. B 725 (2013) 190 [arXiv:1302.3884] [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].
Particle Data Group collaboration, Review of Particle Physics, Phys. Rev. D 98 (2018) 030001 [INSPIRE].
E.G. Adelberger, B.R. Heckel and A.E. Nelson, Tests of the gravitational inverse square law, Ann. Rev. Nucl. Part. Sci. 53 (2003) 77 [hep-ph/0307284] [INSPIRE].
E. Hardy and R. Lasenby, Stellar cooling bounds on new light particles: plasma mixing effects, JHEP 02 (2017) 033 [arXiv:1611.05852] [INSPIRE].
G.G. Raffelt, Stars as laboratories for fundamental physics: The astrophysics of neutrinos, axions, and other weakly interacting particles, University of Chicago Press, Chicago U.S.A. (1996).
J. Redondo and G. Raffelt, Solar constraints on hidden photons re-visited, JCAP 08 (2013) 034 [arXiv:1305.2920] [INSPIRE].
C. Kittel, Introduction to Solid State Physics, eighth edition, Wiley, Hoboken U.S.A. (2004).
G.D. Mahan, Many Particle Physics, third edition, Plenum, New York U.S.A. (2000).
P.B. Allen, Electron-Phonon Effects in the Infrared Properties of Metals, Phys. Rev. B 3 (1971) 305.
P.B. Allen, Empirical electron-phonon λ values from resistivity of cubic metallic elements, Phys. Rev. B 36 (1987) 2920.
A. Mitridate, T. Trickle, Z. Zhang and K.M. Zurek, Detectability of Axion Dark Matter with Phonon Polaritons and Magnons, Phys. Rev. D 102 (2020) 095005 [arXiv:2005.10256] [INSPIRE].
R. Catena, T. Emken, M. Matas, N.A. Spaldin and E. Urdshals, Crystal responses to general dark matter-electron interactions, Phys. Rev. Res. 3 (2021) 033149 [arXiv:2105.02233] [INSPIRE].
M. Dressel and G. Grüner, Electrodynamics of Solids: Optical Properties of Electrons in Matter, Cambridge University Press, Cambridge U.K. (2002).
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Mitridate, A., Trickle, T., Zhang, Z. et al. Dark matter absorption via electronic excitations. J. High Energ. Phys. 2021, 123 (2021). https://doi.org/10.1007/JHEP09(2021)123
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DOI: https://doi.org/10.1007/JHEP09(2021)123