Non-Markovian memory effects narrow the viable parameter space for electroweak baryogenesis, shift optimal wall velocities lower, produce non-monotonic baryon asymmetry dependence on memory timescale, and can enhance gravitational-wave signals.
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Radioactive molecules offer enhanced sensitivity to new physics through combined nuclear and molecular properties, providing a platform complementary to high-energy colliders.
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Non-Markovian Electroweak Baryogenesis: Memory Effects on CP-Violating Transport and Gravitational Waves
Non-Markovian memory effects narrow the viable parameter space for electroweak baryogenesis, shift optimal wall velocities lower, produce non-monotonic baryon asymmetry dependence on memory timescale, and can enhance gravitational-wave signals.
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Radioactive Molecules as Laboratories of Fundamental Physics
Radioactive molecules offer enhanced sensitivity to new physics through combined nuclear and molecular properties, providing a platform complementary to high-energy colliders.