Path integral renormalization in loop quantum cosmology

N. Bodendorfer, Muxin Han, Fabian Haneder, Hongguang Liu
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引用次数: 4

Abstract

A coarse graining technique akin to block spin transformations that groups together fiducial cells in a homogeneous and isotropic universe has been recently developed in the context of loop quantum cosmology. The key technical ingredient was an SU(1, 1) group and Lie algebra structure of the physical observables as well as the use of Perelomov coherent states for SU(1, 1). It was shown that the coarse graining operation is completely captured by changing group representations. Based on this result, it was subsequently shown that one can extract an explicit renormalisation group flow of the loop quantum cosmology Hamiltonian operator in a simple model with dust-clock. In this paper, we continue this line of investigation and derive a coherent state path integral formulation of this quantum theory and extract an explicit expression for the renormalisation-scale dependent classical Hamiltonian entering the path integral for a coarse grained description at that scale. We find corrections to the non-renormalised Hamiltonian that are qualitatively similar to those previously investigated via canonical quantisation. In particular, they are again most sensitive to small quantum numbers, showing that the large quantum number (spin) description captured by so called "effective equations" in loop quantum cosmology does not reproduce the physics of many small quantum numbers (spins). Our results have direct impact on path integral quantisation in loop quantum gravity, showing that the usually taken large spin limit should be expected not to capture (without renormalisation, as mostly done) the physics of many small spins that is usually assumed to be present in physically reasonable quantum states.
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环量子宇宙学中的路径积分重整化
在圈量子宇宙学的背景下,最近开发了一种类似于块自旋变换的粗粒化技术,该技术将均匀和各向同性宇宙中的基准细胞组合在一起。关键技术成分是物理观测的SU(1,1)群和李代数结构,以及SU(1,1)的Perelomov相干态的使用。结果表明,通过改变群表示可以完全捕获粗粒化操作。在此结果的基础上,随后证明了可以在具有尘埃时钟的简单模型中提取环量子宇宙学哈密顿算子的显式重整化群流。在本文中,我们继续这一研究路线,并推导出该量子理论的相干状态路径积分公式,并提取出在该尺度上粗粒度描述的重正化尺度相关的经典哈密顿量进入路径积分的显式表达式。我们发现对非重整化哈密顿量的修正在质量上类似于以前通过正则量化研究的那些。特别是,它们再次对小量子数最为敏感,这表明环路量子宇宙学中所谓的“有效方程”所捕获的大量子数(自旋)描述并不能再现许多小量子数(自旋)的物理学。我们的结果对环量子引力中的路径积分量子化有直接影响,表明通常采用的大自旋极限应该不会捕获(没有重整化,正如大多数人所做的那样)通常假设存在于物理上合理的量子态中的许多小自旋的物理学。
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