Researchers have developed a new formalism to describe particle production during ultra-relativistic bubble collisions, a key phenomenon in cosmological phase transitions. This process can generate particles much heavier than the phase transition scale. The new approach addresses shortcomings of previous models, which parametrically overestimated hard particle production and showed dependence on gauge and field-space coordinate choices, thus compromising the robustness of their predictions. The proposed formalism offers a more precise and consistent description of these events.
The new model is based on an analogy with the partonic description of high-energy collisions. In the ultra-relativistic limit, colliding bubbles undergo nearly free passage, and hard particle production arises from on-shell scatterings among the quanta constituting the Lorentz-contracted walls. This approach considers on-shell interactions, in contrast to previous models that relied on the off-shell decay of the scalar background.
The application of this formalism has been extended to the study of heavy scalar, fermion, and vector particle production. This advancement has significant implications for various areas of physics, including dark matter generation, leptogenesis (a process that could explain the matter-antimatter asymmetry in the universe), graviton production, and the formation of primordial gravitational waves. The development of this more precise model is crucial for refining our understanding of the fundamental processes that occurred in the early universe.