Bohmian Quantum Gravity and Cosmology

Applied Bohmian Mechanics Pub Date : 2018-01-10 DOI:10.1201/9780429294747-11

N. Pinto-Neto, W. Struyve

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引用次数: 34

Abstract

Quantum gravity aims to describe gravity in quantum mechanical terms. How exactly this needs to be done remains an open question. Various proposals have been put on the table, such as canonical quantum gravity, loop quantum gravity, string theory, etc. These proposals often encounter technical and conceptual problems. In this chapter, we focus on canonical quantum gravity and discuss how many conceptual problems, such as the measurement problem and the problem of time, can be overcome by adopting a Bohmian point of view. In a Bohmian theory (also called pilot-wave theory or de Broglie-Bohm theory, after its originators de Broglie and Bohm), a system is described by certain variables in space-time such as particles or fields or something else, whose dynamics depends on the wave function. In the context of quantum gravity, these variables are a space-time metric and suitable variable for the matter fields (e.g., particles or fields). In addition to solving the conceptual problems, the Bohmian approach yields new applications and predictions in quantum cosmology. These include space-time singularity resolution, new types of semi-classical approximations to quantum gravity, and approximations for quantum perturbations moving in a quantum background.

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波西米亚量子引力与宇宙学

量子引力旨在用量子力学的术语来描述引力。具体如何做到这一点仍是一个悬而未决的问题。各种各样的建议已经被提上了台，如经典量子引力，环量子引力，弦理论等。这些建议经常遇到技术和概念上的问题。在本章中，我们将重点讨论经典量子引力，并讨论有多少概念问题，如测量问题和时间问题，可以通过采用波西米亚的观点来克服。在波米理论(也称为导波理论或德布罗意-玻姆理论，以其创始人德布罗意和玻姆命名)中，系统由时空中的某些变量描述，如粒子或场或其他东西，其动力学取决于波函数。在量子引力的背景下，这些变量是一个时空度量，适合于物质场(如粒子或场)的变量。除了解决概念上的问题，波西米亚方法在量子宇宙学中产生了新的应用和预测。这些包括时空奇点分辨率，量子引力的新型半经典近似，以及在量子背景中移动的量子微扰的近似。

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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Applied Bohmian Mechanics

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