Measure for momentum in curved space

Judithku
Messages
4
Reaction score
0
When I write down a quantum field (for instance to compute T^00 or some expectation value)

I write it as an integral over momentum space.

If I am working in curved space
should this be divided by sqrt [g]?

(and why or why not?)
 
Physics news on Phys.org
The answer is - no. The "momentum" space can be thought of just as a Fourier transform, which has nothing to do with a metric structure of spacetime.

Moreover, expansion of the field in terms of plane waves is not a natural thing to do in curved spacetime, because plane waves are not solutions of the Klein-Gordon equation in curved spacetime.
 
Thanks -
I realize in general plane waves are inappropriate but I thought in dealing with a very weak potential that they could be used.

In papers written about the density of states in curved space, they say
\int d^3 x \int d^3 p
is invariant.
I thought this meant that the \sqrt g in the space integral cancels out
with its inverse in the momentum integral.
Do you think that is incorrect?
See for instance
http://www.sciencedirect.com/science/article/pii/0375960189905628
and on the arxiv
http://arxiv.org/abs/1012.5421
 

Thread 'Why Entangled Photon-Polarization Qubits Violate Bell’s Inequality'

Insights auto threads is broken atm, so I'm manually creating these for new Insight articles. In her YouTube video Bell’s Theorem Experiments on Entangled Photons, Dr. Fugate shows how polarization-entangled photons violate Bell’s inequality. In this Insight, I will use quantum information theory to explain why such entangled photon-polarization qubits violate the version of Bell’s inequality due to John Clauser, Michael Horne, Abner Shimony, and Richard Holt known as the...
View full post »

Thread 'Schrödinger equation and classical wave equation'

Not an expert in QM. AFAIK, Schrödinger's equation is quite different from the classical wave equation. The former is an equation for the dynamics of the state of a (quantum?) system, the latter is an equation for the dynamics of a (classical) degree of freedom. As a matter of fact, Schrödinger's equation is first order in time derivatives, while the classical wave equation is second order. But, AFAIK, Schrödinger's equation is a wave equation; only its interpretation makes it non-classical...
View full post »

Thread 'Is a table levitating possible, even at a minuscule probability?'

I am not sure if this falls under classical physics or quantum physics or somewhere else (so feel free to put it in the right section), but is there any micro state of the universe one can think of which if evolved under the current laws of nature, inevitably results in outcomes such as a table levitating? That example is just a random one I decided to choose but I'm really asking about any event that would seem like a "miracle" to the ordinary person (i.e. any event that doesn't seem to...
View full post »

Similar threads

I Quantum particle's state in momentum eigenfunctions basis
Replies
16
Views
2K
A Method of calculating the vacuum energy divergence
Replies
2
Views
1K
I Mean values of observables
Replies
2
Views
994
I More information on the momentum eigenstate in the position basis
Replies
1
Views
564
A Converting momentum sums to integrals in curved spacetime
Replies
1
Views
2K
B Energy-time uncertainty relation for a volume and macroscopic objects?
Replies
2
Views
417
I Infinite momentum is impossible, boundary term in integration by parts
Replies
24
Views
2K
I Measurements and uncertainty principle
Replies
12
Views
2K
A Probability flux integrated over all space is mean momentum?
Replies
2
Views
2K
A Hard-Core Boson Model in K space
Replies
0
Views
1K

Hot Threads

Recent Insights

Back
Top