Revisiting general dark matter-bound-electron interactions
Abstract
In this Letter we revisit general dark matter (DM)-bound-electron interactions studied previously in the influential work [R. Catena et al., Atomic responses to general dark matter-electron interactions, Phys. Rev. Res. 2, 033195 (2020)] For the most general DM-electron nonrelativistic or relativistic interactions for DM with spin up to 1, we find the average ionization matrix element squared can be organized into three terms, each of which is a product of a DM response function (a0,1,2) and a linear combination ( W0,1,2) of the four atomic response functions (W1,2,3,4) given in that work, W0 = W1, \, W1 = |v0|2 W1 - 2 me\, q· v0 q2 W2 + W3,\, W2 = (q· v0)2 q2 W1 - 2 me\, q· v0 q2 W2 + me2 q2W4. Furthermore, we find a crucial minus sign was missed for the calculation of W2 in that work, which has significant phenomenological consequences when explaining experimental bounds on specific DM scenarios. Due to the corrected sign, there can be significant cancellations between the W2 and W3,4 terms, so that W1,2 are dominated by the usual response function W1 in some cases. Many DM scenarios involving DM or electron axial-vector current can yield W2 and thus are potentially affected by the sign. As an example, we show that the recent XENON1T constraint on the fermionic DM anapole moment is weakened by a factor of 2 or so. We also present a complete list of NR operators for spin-1 DM and compute their contributions to the DM response functions.
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