We explore the implications of finite-temperature quantum field theory effects on cosmological parameters within the framework of the ŁCDM model and its modification. By incorporating temperature-dependent corrections to the cosmological constant, we extend the standard cosmological model to include additional density parameters, Ωↀ䃒 and Ωↀ䃓, which arise from finite-T quantum gravitational effects. Using the Cosmic Linear Anisotropy Solving System (CLASS), we analyze the impact of these corrections on the cosmic microwave background power spectrum and compare the results with the Planck 2018 data. Through brute-force parameter scans and advanced machine learning techniques, including quartic regression, we demonstrate that the inclusion of Ωↀ䃒 and Ωↀ䃓 improves the model's predictive accuracy, achieving high R² values and low mean squared error. The present work paves the way for future research into higher-order corrections and enhanced computational methods for cosmological parameter estimation.
Park et al. (Mon,) studied this question.
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