The intersection of general relativity and quantum mechanics
APA
Martin, K. (2008). The intersection of general relativity and quantum mechanics. Perimeter Institute. https://pirsa.org/08080000
MLA
Martin, Keye. The intersection of general relativity and quantum mechanics. Perimeter Institute, Aug. 12, 2008, https://pirsa.org/08080000
BibTex
@misc{ pirsa_PIRSA:08080000, doi = {10.48660/08080000}, url = {https://pirsa.org/08080000}, author = {Martin, Keye}, keywords = {Quantum Foundations}, language = {en}, title = {The intersection of general relativity and quantum mechanics}, publisher = {Perimeter Institute}, year = {2008}, month = {aug}, note = {PIRSA:08080000 see, \url{https://pirsa.org}} }
United States Naval Research Laboratory
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Abstract
Domains were introduced in computer science in the late 1960\'s by Dana Scott to provide a semantics for the lambda calculus (the lambda calculus is the basic prototype for a functional programming language i.e. ML). The study of domains with measurements was initiated in the speaker\'s thesis: a domain provides a qualitative view of information expressed in part by an \'information order\' and a measurement on a domain expresses a quantitative view of information with respect to the underlying qualitative aspect. The theory of domains and measurements was initially introduced to provide a first order model of computation, one in which a computation is viewed as a process that evolves in a space of informatic objects, where processes have informatic rates of change determined by the manner in which they manipulate information. There is a domain of binary channels with capacity as a measurement. There is a domain of finite probability distributions with entropy as a measurement. There is a domain of quantum mixed states with entropy as a measurement. There is a domain of spacetime intervals with global time as a measurement. In this setting, similarities between QM and GR emerge, but also some important differences. In a domain, if we write x <= y, then it means that x carries information about y, while x << y is a stronger relation that means x carries *essential* information about y. In GR, the domain theoretic relation << can be proven to be timelike causality. It possesses stronger mathematical properties than << does in QM. However, by an application of the maximum entropy principle, we can restrict the mixed states in consideration and this difference is removed: the domains of events and mixed states are both globally hyperbolic -- where globally hyperbolic is a purely order theoretic idea that just happens to coincide with the usual notion in the case of GR. Along the way, we will see domain theoretic ways of distinguishing between the Newtonian and relativistic notions of time, how to reconstruct the topology and geometry of spacetime in a purely order theoretic manner beginning from only a countable set, see that the Holevo capacity of a unital qubit channel is determined by the largest value of its informatic derivative and have reason to wonder if distance can be defined as the amount of information (capacity) that can be transmitted between two points.