Black holes and cosmology in quantum gravity

量子引力中的黑洞和宇宙学

• 批准号: RGPIN-2017-04317
• 负责人: Husain, Viqar
• 金额: $ 2.62万
• 依托单位: University of New Brunswick
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=710968
• 关键词: Black; holes; cosmology; quantum; gravity

The physics of the small, at the scale of atomic and nuclear phenomena, is described by quantum theory. We now have broadly successful quantum theories that describe three of the four observed fundamental forces in nature: electromagnetic, weak and strong nuclear interactions. On the other hand, physics on large scales, encompassing the study of solar systems, galaxies and cosmology as a whole, is described by a gravitational theory, the most successful of which is Einstein's theory of general relativity. This theory envisions gravity as a curvature of the geometry of space and time, welded together as one entity: spacetime. Quantum theory is expected to be important in gravitational phenomena involving very strong gravitational fields of highly compact objects, such as black holes and the very early Universe. Combining gravitation with quantum theory is widely considered to be the frontier problem in theoretical physics, and would reveal a "quantum geometry" with matter. The purpose of the proposed research is to explore one approach to developing a quantum theory of gravity. This requires the use of a clock as a part of the description of geometry and matter, and helps us to clarify what is meant by "energy of the Universe." I will use this description, called the Hamiltonian theory, to study the properties of the early Universe very close to the Big Bang, and the formation of black holes, using computer simulations. These simulations will use a method of random sampling of the state of gravity and matter known as the Monte Carlo method. This is a very efficient and well-developed technology that has wide ranging applications, but it has so far not been applied to the study of matter and the geometry of the Universe in a fully quantum setting. This method is expected to reveal properties called phase transitions, that are familiar in solid, liquid and gas phases of matter. But if the physical system is gravity and matter, with gravity described as a spacetime curved geometry, the phases could turn out to be unusual and revealing. One interesting feature is the correlation length. This is a measure of how far apart in space physical effects are correlated. If this distance is very large, it means that very distant physical phenomena are related, or march in step. An infinite correlation length signals a phase transition. I expect the ideas and methods to be employed in this proposal will provide new insights into the problem of quantum gravity. These insights could guide future theoretical developments, and provide a better understanding of cosmological problems, such as dark matter and energy. The simulation methods to be used have diverse applicability, from forecasting polls to analyzing big data sets, and therefore provide important multi-disciplinary tools for training HQP.

原子和核现象尺度上的小物理学是用量子理论来描述的。我们现在有了广泛成功的量子理论，描述了自然界中观察到的四种基本力中的三种：电磁、弱和强核相互作用。另一方面，大尺度的物理学，包括太阳系、星系和宇宙学的整体研究，都是由引力理论描述的，其中最成功的是爱因斯坦的广义相对论。这一理论将重力设想为空间和时间几何体的曲率，并将其融合为一个实体：时空。 量子理论有望在涉及高度致密物体的非常强引力场的引力现象中发挥重要作用，例如黑洞和非常早期的宇宙。将引力与量子理论相结合被广泛认为是理论物理学的前沿问题，并将揭示出与物质有关的“量子几何”。 这项拟议的研究的目的是探索一种发展量子引力理论的方法。这需要使用时钟作为几何和物质描述的一部分，并帮助我们澄清什么是“宇宙能量”。我将使用这种被称为哈密顿理论的描述，通过计算机模拟来研究非常接近大爆炸的早期宇宙的性质，以及黑洞的形成。 这些模拟将使用一种对重力状态和物质进行随机抽样的方法，称为蒙特卡洛方法。这是一项非常高效和发展良好的技术，有着广泛的应用，但到目前为止，它还没有被应用于完全量子环境下的物质和宇宙几何的研究。这种方法有望揭示物质的固态、液态和气相中常见的相变性质。但如果物理系统是重力和物质，而重力被描述为时空弯曲几何，那么这些相位可能会被证明是不寻常的和具有启发性的。一个有趣的特征是关联长度。这是一种衡量空间物理效应相互关联的距离的指标。如果这个距离很大，这意味着非常遥远的物理现象是相关的，或者是步调一致的。无限长的相关长度标志着相变。 我预计，这项提案中将采用的想法和方法将为量子引力问题提供新的见解。这些见解可以指导未来的理论发展，并提供对宇宙问题的更好理解，如暗物质和能量。从预测民意调查到分析大数据集，将使用的模拟方法具有多种适用性，因此为培训HQP提供了重要的多学科工具。