Flavor physics at the EIC with b-jet tagging

Abstract

We employ an approximate conserved quantum number (defined as "b-Parity" in [1]) of the Standard Model (SM): bP=(-1)n, where n is the number of produced b-jets in the reaction e + p/A n · jb +X, to explore new TeV-scale flavor-changing interactions involving the 3rd generation quarks at the EIC; simply by counting the number of b-jets in the final state. In particular, the SM single and di-jet production at the EIC which occur through charge current interactions, e + p/A j + \!\!ET and e + p/A 2· j + \!\!ET, are bP-even since the bP-violating (i.e, bP=-1) SM signals for these processes are necessarily CKM suppressed and, therefore, have a vanishingly small production rate. In contrast, new flavor physics can generate bP=-1 signals at the EIC whose only significant SM background is due to b-jet misidentification. We thus show that bP can be used as a simple and sensitive probe of new flavor violating physics; specifically, we find that counting single b-jet events in e + p/A j + \!\!ET at the EIC with a center-of-mass (CM) energy of s 140 GeV, can probe scales of new physics up to O(5) TeV for a certain type of new chiral flavor-changing physics in 3rd generation interactions. This is remarkably more than 30 times larger than the assumed EIC CM energy and it critically depends on the b-tagging efficiency and purity as well as the feasibility of electron-beam polarization. The sensitivity of the di-jet process, e + p/A 2j + \!\!ET, to these type of new physics is reduced compared to the single-jet channel.