Gravitational Self-force from Quantized Linear Metric Perturbations in Curved Space

Foundations of Physics 37 (4-5):460-479 (2007)
  Copy   BIBTEX

Abstract

We present a formal derivation of the Mino–Sasaki–Tanaka–Quinn–Wald (MSTQW) equation describing the self-force on a (semi-) classical relativistic point mass moving under the influence of quantized linear metric perturbations on a curved background space–time. The curvature of the space–time implies that the dynamics of the particle and the field is history-dependent and as such requires a non-equilibrium formalism to ensure the consistent evolution of both particle and field, viz., the worldline influence functional and the closed- time-path (CTP) coarse-grained effective action. In the spirit of effective field theory, we regularize the formally divergent self-force by smearing the local part of the retarded Green’s function and employing a quasi-local expansion. We derive the MSTQW–Langevin equations describing the perturbations of the particle’s worldline about its semi-classical trajectory resulting from interactions with the quantum fluctuations of the linear metric perturbations. Finally, we demonstrate that the quantum fluctuations of the field could, in principle, leave imprints on gravitational waveforms expected to be observed by gravitational interferometers, thereby encoding information about tree-level perturbative quantum gravity

Categories

Keywords

Reprint years

DOI

10.1007/s10701-007-9111-2

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 93,069

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

Gravitational Quantum Dynamics: A Geometrical Perspective.Ivano Tavernelli - 2021 - Foundations of Physics 51 (2):1-24.
Uniformly Accelerated Charge in a Quantum Field: From Radiation Reaction to Unruh Effect. [REVIEW]Philip R. Johnson & B. L. Hu - 2005 - Foundations of Physics 35 (7):1117-1147.
Black Hole Fluctuations and Backreaction in Stochastic Gravity.Sukanya Sinha, Alpan Raval & B. L. Hu - 2003 - Foundations of Physics 33 (1):37-64.
The motion of charged test particles in general relativity.Peter A. Hogan & Ivor Robinson - 1985 - Foundations of Physics 15 (5):617-627.
Is Gravitational Entanglement Evidence for the Quantization of Spacetime?André Großardt & M. Kemal Döner - 2022 - Foundations of Physics 52 (5):1-27.
Gravitational Perturbations of a Radiating Spacetime.Manasse R. Mbonye & Ronald L. Mallett - 2000 - Foundations of Physics 30 (5):747-774.
Quantum mechanics and the equivalence principle.Paul Davies - manuscript
Local and Non-Local Aspects of Quantum Gravity.H. -H. V. Borzeszkowski, B. K. Datta, V. De Sabbata, L. Ronchetti & H. -J. Treder - 2002 - Foundations of Physics 32 (11):1701-1716.
SU(3) Local Gauge Field Theory as Effective Dynamics of Composite Gluons.Thomas Fuß - 2002 - Foundations of Physics 32 (11):1737-1755.
Local and Non-Local Aspects of Quantum Gravity.H.-H. V. Borzeszkowski, B. K. Datta, V. De Sabbata, L. Ronchetti & H.-J. Treder - 2002 - Foundations of Physics 32 (11):1701-1716.

Analytics

Added to PP
2013-11-22

Downloads
52 (#315,029)

6 months
3 (#1,045,901)

Historical graph of downloads
How can I increase my downloads?

Citations of this work

No citations found.

Add more citations

References found in this work

Add more references