Alternative and Averaged Theories of Gravity

引力的替代理论和平均理论

• 批准号: RGPIN-2021-02465
• 负责人: vandenHoogen, Robert
• 金额: $ 1.75万
• 依托单位: St. Francis Xavier University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=758276
• 关键词: Alternative; Averaged; Theories; Gravity

General Relativity (GR) has been very successful in explaining a wide range of astrophysical observations and laboratory experiments to high precision. However, GR offers no explanation for the currently observed acceleration of the universe without the introduction of an additional "exotic" field, called Dark Energy. A different explanation for the equivalent effects of dark energy can perhaps be explained within an alternative theory of gravity possibly without the need to add an exotic field. There are two primary objectives over the next five years. The first objective of the research program attempts to define an averaged theory of gravity. Since one commonly assumes the universe is isotropic and spatially homogeneous on cosmological scales, there may be nontrivial dynamical effects that are lost due to these assumptions. On cosmological scales, one should incorporate the effects of small scale inhomogeneities on the overall macroscopic dynamics. One proposal to address the issue is to develop an averaged theory of gravity. An averaged theory of gravity based on GR is challenging due to the difficulty in defining a covariant averaging procedure and the nonlinear nature of the gravitational field equations. The Teleparallel Equivalent to General Relativity (TEGR) is dynamically equivalent to GR and therefore offers us an opportunity to develop an averaged theory of gravity. Assuming that TEGR describes gravity on small to intermediate length scales, one can then use a covariant averaging procedure already developed to determine the field equations describing the dynamics in the averaged or macroscopic space-time. As we move to precision observational cosmology, analysis of models based on averaged theories of gravity becomes much more critical. These averaged theories could yield small but important contributions in the understanding of the energy budget of the universe. Moreover, these averaged theories of gravity show promise in resolving the Hubble tension - why two independent sets of cosmological observations yield different values for the Hubble parameter. The second objective within my research program grew out of my preliminary development of an averaged theory of gravity. Teleparallel gravity is a promising class of alternative theories of gravity that assumes that the dynamics of the gravitational field are no longer encoded in the curvature via the metric as in GR, but are encoded in the torsion of a zero curvature connection via the frame field. One class of teleparallel gravity theories are based on a function of the torsion scalar T, f(T). One of the current challenges in f(T) teleparallel gravity is in the selection of a viable ansatz for the inertial frame (or equivalently for the frame and connection), in particular, when symmetry constraints are imposed on the geometry. I will develop a clear and concise procedure that can be used to impose consistent geometrical symmetries in teleparallel gravity.

广义相对论（GR）已经非常成功地解释了广泛的天体物理观测和实验室实验的高精度。然而，如果没有引入一个额外的“奇异”场，即暗能量，GR就无法解释目前观测到的宇宙加速。对暗能量等效效应的另一种解释也许可以在另一种引力理论中得到解释，可能不需要添加一个奇异场。今后五年有两个主要目标。该研究计划的第一个目标是试图定义一个平均的引力理论。由于人们通常假设宇宙在宇宙学尺度上是各向同性和空间均匀的，因此可能会有非平凡的动力学效应由于这些假设而丢失。在宇宙学尺度上，我们应该考虑小尺度不均匀性对整体宏观动力学的影响。解决这个问题的一个建议是发展一个平均的引力理论。基于广义相对论的平均引力理论是一个具有挑战性的问题，这是由于定义协变平均过程的困难和引力场方程的非线性性质。广义相对论的遥平行等效理论（TEGR）在动力学上等价于广义相对论，因此为我们提供了一个发展平均引力理论的机会。假设TEGR描述了小到中等长度尺度上的引力，那么可以使用已经开发的协变平均程序来确定描述平均或宏观时空中动力学的场方程。随着我们转向精确观测宇宙学，基于平均引力理论的模型分析变得更加重要。这些平均理论可能会在理解宇宙能量收支方面产生微小但重要的贡献。此外，这些平均的引力理论在解决哈勃张力方面显示出希望-为什么两组独立的宇宙学观测会产生不同的哈勃参数值。我的研究计划中的第二个目标源于我对平均引力理论的初步发展。遥平行引力是一种有前途的引力理论，它假设引力场的动力学不再像GR那样通过度规编码在曲率中，而是通过框架场编码在零曲率连接的挠率中。一类遥平行引力理论是基于挠率标量T的函数f（T）。f（T）远程平行引力当前的挑战之一是为惯性系（或等效的系和连接）选择可行的假设，特别是当对几何形状施加对称约束时。我将发展一个清晰而简洁的程序，可以用来在遥平行引力中施加一致的几何对称性。