Talk:Schrödinger field

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Reason For Being

Latest comment: 16 years ago1 comment1 person in discussion

I added this page because this sort of thing is discussed in dozens of places, each place with a different name. Theres the "Coherent state path integral" in Negele and Orland, there is the "Gross Pitaevski equation" in BEC theory. There is the "Bogoliubov DeGennes Equation" in superconductivity and the "nonlinear Schrodinger equation" in fiber-optics. It's all the same thing. It confuses people, because there's very little conceptual relation to the equation for the quantum mechanical wavefunction, other than obeying the same equation.Likebox 19:06, 8 October 2007 (UTC)Reply

On Pair potentials

Latest comment: 15 years ago5 comments2 people in discussion

In the section on Pair potentials there's written that the non relativistic limit of for example QED is the following action:

${\displaystyle S=\int _{xt}\psi ^{\dagger }\left(i{\partial \over \partial t}+{\nabla ^{2} \over 2m}\right)\psi -\int _{xy}\psi ^{\dagger }(x)\psi (x)V(x,y)\psi ^{\dagger }(y)\psi (y)}$ 

with

${\displaystyle V(x,y)={q^{2} \over |x-y|}}$ 

and that this describes nearly all of condensed matter physics.

That's ok, but in condesed matter I'm used the following expression for the pair potential in the hamiltonian:

${\displaystyle H_{int}=\int _{xy}\psi ^{\dagger }(x)\psi ^{\dagger }(y)V(x,y)\psi (y)\psi (x)\,}$ 

This is different from the previous one...could someone comment about the difference. Dave (talk) 17:54, 28 March 2009 (UTC)Reply

It's the same expression.Likebox (talk) 21:16, 28 March 2009 (UTC)Reply

Up to some normal ordering stupidities. There might be some difference for singular potentials, like the one in the example. Drat. You should think of the potential as smoothed out in some way near r=0. But you're right, the article should be more careful about operator ordering.Likebox (talk) 18:49, 30 March 2009 (UTC)Reply

Yep, I was exactly thinking to this small difference for divergent potentials. I was wandering how this difference could be linked to the self-interaction renormalization and the Lamb shift. In fact the expression you wrote seems to be the right non relativistic limit of QED (isn't it), and has to be renormilized, while the expression I wrote is what one obtains from second quantization of Shroedinger equation, and does not present divergences. Am I missing something? Dave (talk) 20:55, 30 March 2009 (UTC)Reply

This article is all about second quantization of the Schrodinger equation, because this case is free from the conceptual difficulties of particles going backwards in time. The Lamb shift in QED is caused by loops involving virtual electrons and photons, and will be absent in this approximation.

The ordering ambiguity you noticed is real: use the commutation relation for psi and psi-dagger to sort it out. The different between the two orders is a local term psi*(x)psi(x)V(x,x), which, when V is regular at x=0 is just a constant potential everywhere in space. This can be removed by a time-dependent redefinition of the phase of psi, it's not physically important because the zero of energy is only relative to a reference. But it is annoying that the particular V of physical interest is divergent when the electrons are sitting right on top of each other.Likebox (talk) 01:19, 2 April 2009 (UTC)Reply