On heat coefficients, multiplicative anomaly and 4D Casimir energy for GJMS operators
Rodrigo Aros, Fabrizzio Bugini, Danilo E. D\'iaz, Camilo Nu\~nez-Barra
TL;DR
This paper verifies the predicted total derivative term of the 4D trace anomaly for GJMS operators by explicit heat coefficient calculations, linking Casimir energy, multiplicative anomaly, and conformal invariants.
Contribution
It provides the first explicit computation of the heat coefficient for GJMS operators, connecting anomaly terms, Casimir energy, and conformal invariants using advanced formulas.
Findings
Confirmed the relation between heat coefficients and trace anomaly terms.
Linked Casimir energy with multiplicative anomalies and conformal charges.
Validated theoretical predictions with explicit calculations.
Abstract
This note aims to verify a prediction on the total derivative term of the 4D trace anomaly, and the corresponding heat coefficient, for GJMS operators. It stems from the explicit computation of an {\it improved} Casimir (or vacuum) energy on the sphere that takes into account the multiplicative anomaly among the (shifted) Laplacian factors and connects, via the Cappelli-Coste relation, with both the type A central charge and the total derivative term of the 4D trace anomaly. The present heat coefficient computation is based on Juhl's explicit formula for GJMS operators, Gilkey's formula for the integrated heat coefficient of higher-order Laplacians, and the \textit{conformal principle} by Branson and {\O}rsted.
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Taxonomy
TopicsQuantum Electrodynamics and Casimir Effect · Noncommutative and Quantum Gravity Theories · Quantum Mechanics and Applications