Hamiltonian theory: Generalizations to higher dimensions, supersymmetry, and modified gravity

Norbert Bodendorfer; Konstantin Eder; Xiangdong Zhang

doi:10.1007/978-981-99-7681-2_98

Hamiltonian theory: Generalizations to higher dimensions, supersymmetry, and modified gravity

Norbert Bodendorfer^*, Konstantin Eder, Xiangdong Zhang

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

Loop quantum gravity in its Hamiltonian form relies on a connection formulation of the gravitational phase space with three key properties: (1.) a compact gauge group, (2.) real variables, and (3.) canonical Poisson brackets. In conjunction, these properties allow to construct a well-defined kinematical quantization of the holonomy-flux algebra, on top of which the remaining constraints can be implemented. While this idea has traditionally been mainly used for Einstein gravity, any gravitational theory with the above properties can be accommodated. In this chapter, we are going to review three strands of work building on this observation, namely, the study of higher-dimensional loop quantum gravity, supersymmetric extensions of loop quantum gravity, as well as the quantization of modified gravitational theories.

Original language	English
Title of host publication	Handbook of Quantum Gravity
Publisher	Springer Nature
Pages	3829-3873
Number of pages	45
Volume	6-6
ISBN (Electronic)	9789819976812
ISBN (Print)	9789819976805
DOIs	https://doi.org/10.1007/978-981-99-7681-2_98
Publication status	Published - 3 Dec 2024
Externally published	Yes

Keywords

Connection dynamics
Hamiltonian general relativity
Modified gravity
Supergravity
Supersymmetry

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10.1007/978-981-99-7681-2_98

Cite this

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AU - Eder, Konstantin

AU - Zhang, Xiangdong

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N2 - Loop quantum gravity in its Hamiltonian form relies on a connection formulation of the gravitational phase space with three key properties: (1.) a compact gauge group, (2.) real variables, and (3.) canonical Poisson brackets. In conjunction, these properties allow to construct a well-defined kinematical quantization of the holonomy-flux algebra, on top of which the remaining constraints can be implemented. While this idea has traditionally been mainly used for Einstein gravity, any gravitational theory with the above properties can be accommodated. In this chapter, we are going to review three strands of work building on this observation, namely, the study of higher-dimensional loop quantum gravity, supersymmetric extensions of loop quantum gravity, as well as the quantization of modified gravitational theories.

AB - Loop quantum gravity in its Hamiltonian form relies on a connection formulation of the gravitational phase space with three key properties: (1.) a compact gauge group, (2.) real variables, and (3.) canonical Poisson brackets. In conjunction, these properties allow to construct a well-defined kinematical quantization of the holonomy-flux algebra, on top of which the remaining constraints can be implemented. While this idea has traditionally been mainly used for Einstein gravity, any gravitational theory with the above properties can be accommodated. In this chapter, we are going to review three strands of work building on this observation, namely, the study of higher-dimensional loop quantum gravity, supersymmetric extensions of loop quantum gravity, as well as the quantization of modified gravitational theories.

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KW - Hamiltonian general relativity

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KW - Supersymmetry

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Hamiltonian theory: Generalizations to higher dimensions, supersymmetry, and modified gravity

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