"This text examines the myriad challenges of developing quantum gravity theories by considering the conceptual development of time and background dependence. ... Recommended. Graduate students, researchers, and faculty." (E. Kincanon, Choice, Vol. 55 (11), July, 2018) "From a very special perspective, this book presents a well-versed discussion of quantum gravity programs and, respectively, their problems. ... the text begins with a 'largely theory-free conceptual outline of time and clock concepts, alongside notions of space, length-measuring devices, spacetime and frames'. ... it has enough room to trace the Problem of Time facets back to more basic and well-known temporal concepts." (Horst-Heino von Borzeszkowski, zbMATH 1394.81007, 2018)
Introduction.- Part I Problem of Time at the Classical Level.- Temporal Relationalism.- Configurational Relationalism.- The Internal Time Alternative.- Brackets and Constraint Closure.- The Problem of Beables.- Records, Histories and Combined Schemes.- Diffeomorphism-specific issues.- Classical Problem of Time in the Halliwell-Hawking Model.- Global Problems of Time at the Classical Level.- Part II Problem of Time at the Quantum Level.- Quantization.- Problem of Time Facets at the Quantum Level.- Strategies for dealing with the Quantum Frozen Formalism Problem.- These strategies for models with nontrivial Configurational Relationalism.- Strategies for the Quantum Problem of Beables.- Strategies for the Quantum Constraint Closure, Foliation Dependence and Spacetime Reconstruction Problems.- Quantum Problem of Time in the Halliwell-Hawking Model.- Quantum Global Problems of Time and Multiple Choice Problem.- A. Toy Models used in this Book.- B. Levels of Structure.
E. Anderson graduated from Cambridge with distinction in Part III Mathematics, and did a PhD in General Relativity at Queen Mary, University of London, before returning to Cambridge as a Research Fellow of Peterhouse and member of DAMTP. E.A. has also occupied positions at the University of Alberta, Universidad Autónoma de Madrid and Université Paris 7 (with a FQXi large grant to study the titular Problem of Time).
This book is a treatise on time and on background independence in physics. It first considers how time is conceived of in each accepted paradigm of physics: Newtonian, special relativity, quantum mechanics (QM) and general relativity (GR). Substantial differences are moreover uncovered between what is meant by time in QM and in GR. These differences jointly source the Problem of Time: Nine interlinked facets which arise upon attempting concurrent treatment of the QM and GR paradigms, as is required in particular for a background independent theory of quantum gravity. A sizeable proportion of current quantum gravity programs - e.g. geometrodynamical and loop quantum gravity approaches to quantum GR, quantum cosmology, supergravity and M-theory - are background independent in this sense. This book's foundational topic is thus furthermore of practical relevance in the ongoing development of quantum gravity programs.
This book shows moreover that eight of the nine facets of the Problem of Time already occur upon entertaining background independence in classical (rather than quantum) physics. By this development, and interpreting shape theory as modelling background independence, this book further establishes background independence as a field of study. Background independent mechanics, as well as minisuperspace (spatially homogeneous) models of GR and perturbations thereabout are used to illustrate these points. As hitherto formulated, the different facets of the Problem of Time greatly interfere with each others' attempted resolutions. This book explains how, none the less, a local resolution of the Problem of Time can be arrived at after various reconceptualizations of the facets and reformulations of their mathematical implementation. Self-contained appendices on mathematical methods for basic and foundational quantum gravity are included. Finally, this book outlines how supergravity is refreshingly different from GR as a realization of background independence, and what background independence entails at the topological level and beyond.