Power spectrum of density perturbations in chain inflation

M. Winkler, K. Freese
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Abstract

Chain Inflation is an alternative to slow roll inflation in which the universe undergoes a series of transitions between different vacua. The density perturbations (studied in this paper) are seeded by the probabilistic nature of tunneling rather than quantum fluctuations of the inflaton. We find the scalar power spectrum of chain inflation and show that it is fully consistent with a $\Lambda$CDM cosmology. In agreement with some of the previous literature (and disagreement with others), we show that $10^4$ phase transitions per e-fold are required in order to agree with the amplitude of Cosmic Microwave Background anisotropies within the observed range of scales. Interestingly, the amplitude of perturbations constrains chain inflation to a regime of highly unstable de Sitter spaces, which may be favorable from a quantum gravity perspective since the Swampland Conjecture on Trans-Planckian Censorship is automatically satisfied. We provide new analytic estimates for the bounce action and the tunneling rate in periodic potentials which replace the thin-wall approximation in the regime of fast tunneling. Finally, we study model implications and derive an upper limit of $\sim 10^{10}$ GeV on the axion decay constant in viable chain inflation with axions.
链式膨胀中密度扰动的功率谱
链式暴胀是慢滚动暴胀的另一种选择,宇宙在不同的真空之间经历一系列转变。密度扰动(本文所研究的)是由隧穿的概率性质而不是由暴胀子的量子涨落产生的。我们发现了链暴胀的标量功率谱,并表明它与$\Lambda$ CDM宇宙学完全一致。与先前的一些文献一致(与其他文献不一致),我们表明,为了与观测尺度范围内宇宙微波背景各向异性的幅度一致,需要每个e-fold $10^4$相变。有趣的是,扰动的振幅将链暴胀限制在高度不稳定的德西特空间中,这从量子引力的角度来看可能是有利的,因为跨普朗克审查的沼泽猜想自动得到满足。我们对周期势下的弹跳作用和隧穿速率提供了新的解析估计,取代了快速隧穿状态下的薄壁近似。最后,我们研究了模型的意义,并推导了轴子可行链膨胀中轴子衰变常数$\sim 10^{10}$ GeV的上限。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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