Black Hole Physics

黑洞物理学

• 批准号: 138712-2013
• 负责人: Frolov, Valeri
• 金额: $ 3.21万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2013
• 资助国家: 加拿大
• 起止时间: 2013-01-01 至 2014-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=522469
• 关键词: Black; Hole; Physics

Black hole existence is one of the most exciting predictions of the Einstein's theory of gravity. Astrophysical observations strongly support the existence of stellar mass black holes as well as supermassive black holes in the center of many galaxies. Black holes play an important role in theoretical physics as probes of new theoretical ideas and models (such as string theory, brane worlds, large extra dimensions). For quite a long time black holes have been in the focus of interests of the both scientific and public communities. The aim of the project is to gain a better understanding of the properties of spacetime and matter in the strong gravitational field of black holes. The Project includes (i) study of higher dimensional black holes and (ii) study of physical effects in the strong gravitational field of astrophysical black holes. These two directions of research in fact are connected, and require similar tools and methods. In part (i) I shall try to understand which of the properties of four dimensional black holes are generic and valid in any number of dimensions, and which are specific for four dimensions only. The key role in this study will be played by a gepmetric object, recently discovered in our group, Principal Conformal Killing-Yano Tensor, which encodes all the information about the symmetries and other important geometric properties of rotating black holes in any number of spacetime dimensions. It allows one to explain many `miraculous' properties of such black holes. My aim is to study how far one can generalize this method to study non-vacuum black holes, black holes in supergravity, and black holes with non-spherical topology of the horizon. The second direction of my research (ii) is focused on studying physical effects in the close vicinity of black holes which can be used as additional marks for the identification of astrophysical black holes. I would also like to understand the role of the magnetic field and particle collisions in the processes of the energy extraction from rotating black holes. By solving the concrete problems formulated in the Proposal I hope to contribute to our understanding of black holes, their role in the universe, and their special role in theoretical physics.

黑洞的存在是爱因斯坦引力理论最激动人心的预言之一。天体物理观测有力地支持了恒星质量黑洞和许多星系中心存在超大质量黑洞的存在。黑洞在理论物理中扮演着重要的角色，因为它探索了新的理论思想和模型(如弦理论、膜世界、大的额外维度)。长期以来，黑洞一直是科学界和公众关注的焦点。该项目的目的是更好地了解黑洞强引力场中的时空和物质的性质。该项目包括(I)研究高维黑洞和(Ii)研究天体物理黑洞强引力场中的物理效应。这两个研究方向实际上是相互联系的，需要相似的工具和方法。在第(I)部分中，我将试图了解四维黑洞的哪些性质在任何维度上都是通用和有效的，哪些性质只在四维范围内是特定的。在这项研究中，关键的角色将是最近在我们的团队中发现的一个几何对象，主共形Killing-Yano张量，它编码了关于旋转黑洞在任何数量的时空维度上的对称性和其他重要几何性质的所有信息。它使人们能够解释这种黑洞的许多“神奇”性质。我的目的是研究人们可以在多大程度上将这种方法推广到研究非真空黑洞、超重力黑洞和视界非球形拓扑的黑洞。我研究的第二个方向(Ii)集中在研究黑洞附近的物理效应，这些效应可以作为识别天体物理黑洞的额外标志。我还想了解磁场和粒子碰撞在旋转黑洞能量提取过程中的作用。通过解决提案中提出的具体问题，我希望有助于我们理解黑洞，它们在宇宙中的作用，以及它们在理论物理中的特殊作用。