This research paper investigates the cosmological implications of a non-zero, spatially dependent mean for primordial perturbations, a departure from the standard assumption of a Bunch-Davies vacuum state. The authors explore the consequences of using a coherent initial quantum state during inflation, which induces a spatially varying mean and violates statistical homogeneity and isotropy.
Research Objective:
The study aims to examine the observational effects of a primordial mean on cosmological observables, focusing on the matter power spectrum, CMB anisotropies, and spectral distortions.
Methodology:
The authors utilize the formalism of quantum field theory in curved spacetime to calculate the two- and three-point correlation functions of cosmological perturbations in the presence of a coherent initial state. They then relate these correlation functions to observable quantities like the matter power spectrum and CMB bispectrum.
Key Findings:
Main Conclusions:
The presence of a primordial mean leads to distinct observational signatures in cosmological data, potentially detectable by current and future surveys. The authors argue that the squeezed limit of the CMB bispectrum and CMB spectral distortions offer particularly promising avenues for probing this scenario.
Significance:
This research challenges the standard assumptions of statistical homogeneity and isotropy in cosmology, highlighting the importance of exploring alternative initial quantum states for inflation.
Limitations and Future Research:
The study primarily focuses on Gaussian perturbations and a specific parameterization of the primordial mean. Future work could explore non-Gaussianities and more general forms of the mean. Additionally, a detailed analysis of observational data is required to place concrete constraints on the proposed scenario.
Ke Bahasa Lain
dari konten sumber
arxiv.org
Wawasan Utama Disaring Dari
by H. V. Ragave... pada arxiv.org 11-05-2024
https://arxiv.org/pdf/2411.01331.pdfPertanyaan yang Lebih Dalam