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Higher-order corrections to the bubble-nucleation rate at finite temperature

Andreas Ekstedt

2022The European Physical Journal C39 citationsDOIOpen Access PDF

Abstract

Abstract In this paper I discuss how to consistently incorporate higher-order corrections to the bubble-nucleation rate at finite temperature. Doing so I examine the merits of different approaches, with the goal of reducing uncertainties for gravitational-wave calculations. To be specific, the region of applicability and accuracy of the derivative expansion is discussed. The derivative expansion is then compared to a numerical implementation of the Gelfand–Yaglom theorem. Both methods are applied to popular first-order phase transition models, like a loop-induced barrier and a SM-EFT tree-level barrier. The results of these calculations are presented in easy-to-use parametrizations that can directly be used in gravitational-wave calculations. In addition, higher-order corrections for models with multiple scalar fields, such as singlet/triplet extensions, are studied. Lastly, the main goal of this paper is to investigate the convergence and uncertainty of all calculation. Doing so I argue that current calculations for the Standard Model with a tree-level barrier are inaccurate.

Topics & Concepts

Scalar (mathematics)NucleationBubblePhase transitionApplied mathematicsPhysicsRate of convergenceOrder (exchange)Convergence (economics)Derivative (finance)Statistical physicsTree (set theory)MathematicsThermodynamicsComputer scienceMathematical analysisMechanicsGeometryEconomicsEconomic growthFinancial economicsComputer networkChannel (broadcasting)FinancePulsars and Gravitational Waves ResearchCosmology and Gravitation TheoriesQuantum Chromodynamics and Particle Interactions
Higher-order corrections to the bubble-nucleation rate at finite temperature | Litcius