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We point out that the existence of metastable, >10^3 s, negatively charged electroweak-scale particles (X^-) alters the predictions for lithium and other primordial elemental abundances for A>4 via the formation of bound states with nuclei during big bang nucleosynthesis. In particular, we show that the bound states of X^- with helium, formed at temperatures of about T=10^8 K, lead to the catalytic enhancement of ^6Li production, which is 8 orders of magnitude more efficient than the standard channel. In particle physics models where subsequent decay of X^- does not lead to large nonthermal big bang nucleosynthesis effects, this directly translates to the level of sensitivity to the number density of long-lived X^- particles (>10^5 s) relative to entropy of nₗ^{-}/s310^-17, which is one of the most stringent probes of electroweak scale remnants known to date.
Maxim Pospelov (Mon,) studied this question.