Quantum Gravity in the Lab

Event Date:
2021-07-22T16:00:00
2021-07-22T17:00:00
Event Location:
Connect via zoom
Speaker:
Philip Stamp (zoom)
Related Upcoming Events:
Intended Audience:
Undergraduate
Local Contact:

Douglas Scott

Event Information:

It has long been assumed that gravity and quantum mechanics can only be confronted at very high energies ~ 1.2 x 10^28 eV (enough to boil 5 tons of water, and 15 orders of magnitude above the range of particle accelerators). However, recent theory indicates that gravity may cause a breakdown of quantum mechanics at much lower energies, for large masses. This has led to a new experimental field in which such a breakdown is sought in earth-based labs.
    I will review the theory which has made such predictions, and their history, which begins with speculations by Feynman in 1957. I will focus on the Correlated Worldline (CWL) theory, which is the only one so far to make definite quantitative predictions. I will then discuss some of the optomechanical experiments that are trying to test the theory, and where they are right now. These experiments are pushing the boundaries of our understanding of quantum mechanics at the macroscopic scale; as such they have implications for everything from quantum computation to future gravitational wave detectors.

Add to Calendar 2021-07-22T16:00:00 2021-07-22T17:00:00 Quantum Gravity in the Lab Event Information: It has long been assumed that gravity and quantum mechanics can only be confronted at very high energies ~ 1.2 x 10^28 eV (enough to boil 5 tons of water, and 15 orders of magnitude above the range of particle accelerators). However, recent theory indicates that gravity may cause a breakdown of quantum mechanics at much lower energies, for large masses. This has led to a new experimental field in which such a breakdown is sought in earth-based labs.     I will review the theory which has made such predictions, and their history, which begins with speculations by Feynman in 1957. I will focus on the Correlated Worldline (CWL) theory, which is the only one so far to make definite quantitative predictions. I will then discuss some of the optomechanical experiments that are trying to test the theory, and where they are right now. These experiments are pushing the boundaries of our understanding of quantum mechanics at the macroscopic scale; as such they have implications for everything from quantum computation to future gravitational wave detectors. Event Location: Connect via zoom