Cover Image
Read Now

Quantum gravity in a laboratory?

The characteristic - Planck - energy scale of quantum gravity makes experimental access to the relevant physics apparently impossible. Nevertheless, low energy experiments linking gravity and the quantum have been undertaken: the Page and Geilker quantum Cavendish experiment, and the Colella-Overhau...

Full description

Bibliographic Details
Main Authors: Huggett, Nick, Linnemann, Niels (Author), Schneider, Mike D. (Author)
Format: eBook
Language:English
Published: Cambridge, UK Cambridge University Press 2023
Series:Cambridge elements. Elements in the foundations of contemporary physics
Subjects:
Quantum Gravity
Online Access:
Collection: Cambridge Books Online - Collection details see MPG.ReNa
LEADER 02034nmm a2200277 u 4500
001 EB002199644
003 EBX01000000000000001336847
005 00000000000000.0
007 cr|||||||||||||||||||||
008 240304 ||| eng
020 |a 9781009327541 
050 4 |a QC178 
100 1 |a Huggett, Nick 
245 0 0 |a Quantum gravity in a laboratory?  |c Nick Huggett, University of Illinois Chicago, Niels Linnemann, University of Geneva, Mike D. Schneider, University of Missouri 
260 |a Cambridge, UK  |b Cambridge University Press  |c 2023 
300 |a 89 pages  |b digital 
653 |a Quantum gravity 
700 1 |a Linnemann, Niels  |e [author] 
700 1 |a Schneider, Mike D.  |e [author] 
041 0 7 |a eng  |2 ISO 639-2 
989 |b CBO  |a Cambridge Books Online 
490 0 |a Cambridge elements. Elements in the foundations of contemporary physics 
028 5 0 |a 10.1017/9781009327541 
856 4 0 |u https://doi.org/10.1017/9781009327541  |x Verlag  |3 Volltext 
082 0 |a 530.143 
520 |a The characteristic - Planck - energy scale of quantum gravity makes experimental access to the relevant physics apparently impossible. Nevertheless, low energy experiments linking gravity and the quantum have been undertaken: the Page and Geilker quantum Cavendish experiment, and the Colella-Overhauser-Werner neutron interferometry experiment, for instance. However, neither probes states in which gravity remains in a coherent quantum superposition, unlike - it is claimed - recent proposals. In essence, if two initially unentangled subsystems interacting solely via gravity become entangled, then theorems of quantum mechanics show that gravity cannot be a classical subsystem. There are formidable challenges to such an experiment, but remarkably, tabletop technology into the gravity of very small bodies has advanced to the point that such an experiment might be feasible in the near future. This Element explains the proposal and what it aims to show, highlighting the important ways in which its interpretation is theory-laden 

Similar Items