Talk:Fluctuation-dissipation theorem

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Depending on which convention one uses for the Fourier transform, the FDT adopts different signs.

Definition (1):

${\displaystyle {\hat {A}}(\omega )=\int \limits _{-\infty }^{\infty }\mathrm {e} ^{i\omega t}A(t)\,dt}$

gives

${\displaystyle S_{x}(\omega )={\frac {2k_{B}T}{\omega }}\,\mathrm {Im} [{\hat {\chi }}(\omega )].}$

Definition (2):

${\displaystyle {\hat {A}}(\omega )=\int \limits _{-\infty }^{\infty }\mathrm {e} ^{-i\omega t}A(t)\,dt}$

gives

${\displaystyle S_{x}(\omega )=-{\frac {2k_{B}T}{\omega }}\,\mathrm {Im} [{\hat {\chi }}(\omega )].}$

The article uses the first form of the FDT, but in its derivation a Fourier transform of form (2) is used. This inconsistency should be corrected, but I wanted to discuss this first. Benjamin.friedrich (talk) 22:30, 6 December 2017 (UTC)[reply]

I've changed the headline paragraph for the FDT entry to correct misleading text. The rest of the introductory section is problematic. Please see my Talk page.

-- Pwfen (talk) 14:26, 25 January 2015 (UTC)[reply]

I started a major rewrite of this article.

What was the state before: IMO, the second part of the original version was not very clear.

• 'General applicability' did not give a formula of a general FDT
• 'Derivation' did not make it clear to may what actually is the aim of this computation

What I have done: I included a section 'General form' where I give a general FDT in its simplest form; I also included a derivation.

What can be done next:

• remove redundancies
• compare different versions of general FDT (there's a whole plethora in the literature)
• derive the examples from the general form of the FDT

I would appreciate your help.

--Benjamin.friedrich (talk) 12:18, 18 December 2007 (UTC)[reply]

Sure, Benjamin, I'll be glad to help you, although I'm apt to over-commit myself. I appreciate all your work so far in shaping up this little article; most of it was just dashed off quickly while I was researching the equipartition theorem. I meant to return to it, but I got distracted... :( I just added some references and touched up the wording in the lead and my derivation section. I think both derivations should go at the end, similar to what I did at Laplace-Runge-Lenz vector. I'll need to read up on the fluctuation dissipation theorem a lot more, though, before I can really give you much help — sorry! I learn pretty fast, though. :) Willow (talk) 01:13, 19 December 2007 (UTC)[reply]

"Citation needed" / "Violations in glassy systems": "In the mid 1990s, in the study of non-equilibrium dynamics of spin glass models, a generalization of the fluctuation-dissipation theorem was discovered": I suspect you really intended one of the references you've listed in "Further reading", Cristani A, Ritort F (2003), as your citation for this point? - but I'm not familiar with it so I don't feel free to edit quite so boldly as to just put it in!! SquisherDa (talk) 03:19, 9 April 2012 (UTC)[reply]

I actually miss the theorem itself. Only examples, derivation and applications..--85.146.199.125 (talk) 20:22, 20 February 2008 (UTC)[reply]

Perhaps nitpicking, but: In "general formulation," the perturbing field f seems to be off a minus sign: dp/dt = -dH/dx = -dH0/dx - f(t) as written. So then f is *minus* the applied force. This should be changed to be consistent with the definition of susceptibility in that wikipedia article. Dstrozzi (talk) 00:02, 27 March 2017 (UTC)[reply]

The old definition is not correct:

${\displaystyle \langle x(t)\rangle =\langle x\rangle _{0}+\int _{-\infty }^{t}\chi (\tau )f(t-\tau )d\tau \,}$ (incorrect)

Rather ${\displaystyle f}$ and ${\displaystyle \chi }$ are swapped. It should be:

${\displaystyle \langle x(t)\rangle =\langle x\rangle _{0}+\int _{-\infty }^{t}f(\tau )\chi (t-\tau )d\tau \ }$

such that ${\displaystyle \langle x(t)\rangle }$ only depends on the perturbation ${\displaystyle f}$ before ${\displaystyle t}$. 76.199.99.43 (talk) 10:41, 21 April 2009 (UTC)[reply]

(Note: This is my first attempt at editing a Wikipedia page; I'm still unsure of syntax and etiquette. Advice and/or guidance will be very much appreciated.)

Equation (**) implies a discontinuous step-function response for ${\displaystyle \langle x(t)\rangle -\langle x\rangle _{0}}$ at t=0, which is incorrect. As t approaches zero from minus infinity, ${\displaystyle \langle x(t)\rangle -\langle x\rangle _{0}}$ adiabatically approaches ${\displaystyle \ \beta f_{0}A(0)}$. Equation (**) can be corrected by removing the outer parentheses on the right-hand side. As a consequence of this change, the outer parentheses in the second term on the right-hand side in the final equation of the derivation must also be removed. Thus the derivation beginning with Equation (**) should read:

${\displaystyle (**)-\chi (t)=\beta {\operatorname {d} A(t) \over \operatorname {d} t}\theta (t).}$

For stationary processes, the Wiener-Khinchin theorem states that the power spectrum equals twice the Fourier transform of the auto-correlation function

${\displaystyle S_{x}(\omega )=2{\tilde {A}}(\omega ).}$

The last step is to Fourier transform equation (**) and to take the imaginary part. For this it is useful to recall that the Fourier transform of a real symmetric function is real, while the Fourier transform of a real antisymmetric function is purely imaginary. We can split ${\displaystyle {\operatorname {d} A(t) \over \operatorname {d} t}\theta (t)}$ into a symmetric and an anti-symmetric part

${\displaystyle 2{\operatorname {d} A(t) \over \operatorname {d} t}\theta (t)\ ={\operatorname {d} A(t) \over \operatorname {d} t}+{\operatorname {d} A(t) \over \operatorname {d} t}{\rm {sign}}(t).}$

Now the fluctuation-dissipation theorem follows.

(Remark to reviewer, not to be included in the actual article: Observe that the corrected derivation above does not change the imaginary (absorptive) part of chi, but it does modify the real (dispersive) part.)

PaulH (talk) 01:58, 16 February 2011 (UTC)[reply]

Hi Paul, welcome at Wikipedia, and please feel free to correct, improve, expand this article in whatever way. This entire field suffers from a lack of expert attention. -- Marie Poise (talk) 14:40, 16 February 2011 (UTC)[reply]

Hey Paul, I think you have the etiquette mastered already! Using this Talk page is excellent, and it was especially kind of you to write. :) I replied on my Talk page, but I neglected to mention there that we also need more references. Willow (talk) 18:51, 16 February 2011 (UTC)[reply]

Can you provide a reference why we should have a factor of two between the power spectrum and the Fourier transform of the autocorrelation function? Maybe this is just a matter of defintion, but both this article as well as the article on the Wiener-Khinchin theorem do not have this factor of two. Benjamin.friedrich (talk) 09:44, 7 December 2017 (UTC)[reply]

I don't like to delete the whole section, but don't see another way. The problem is this one: In order to expand in the pertubation, h and H would have to commute. (cf. Baker-Campbell-Hausdorff formula). But if they commute, A(t) is not anymore time-dependent and there will always hold ${\displaystyle {\bar {A}}(t)=\langle A\rangle }$

I don't think one can reconcile that and thus I vote for deleting the entire section.

129.206.196.179 (talk) 10:13, 9 June 2011 (UTC)[reply]

Correction: Now I think, it's right. But there is a huge lack of explanation. I hope, I'll get back to inserting it.

129.206.91.26 (talk) 16:36, 9 June 2011 (UTC)[reply]

Another correction: I checked it, it's definitely wrong. I hope, I'll find the time to point out, why.

129.206.91.26 (talk) 17:49, 9 June 2011 (UTC)[reply]

So, here it comes: The Taylor-expansion in numerator and denominator need the following approximation to hold (which is far from obvious for non-commuting H and h, check Baker-Campbell-Hausdorff formula):

${\displaystyle {\mbox{tr}}(Ae^{-\beta (H+h)}\approx {\mbox{tr}}(Ae^{-\beta H}e^{-\beta h})}$

and in the denominator:

${\displaystyle {\mbox{tr}}(e^{-\beta (H+h)}\approx {\mbox{tr}}(e^{-\beta H}e^{-\beta h})}$

While the second approximation seems to hold (I checked some matrices with oracle), the first approximation is simply wrong. Demanding A to be small is probably a solution, but it's highly unphysical to expect some observable to be small compared to the Hamiltonian. Another possibility is to demand ${\displaystyle H}$ and ${\displaystyle h}$ to commute. But then the time evolution of our equilibrium state is trivial and the FDT states: ${\displaystyle 0=0}$.

For these reasons I will now delete the whole "Derivation in trace notation" - section. Hope, your ok with that. — Preceding unsigned comment added by 129.206.196.143 (talk) 16:10, 12 June 2011 (UTC)[reply]

I am trying to comprehend why the field is always taken to be time-independent. I understand why it is turned off at time zero, but there should be a way to derive this without requiring time independence of the field. 129.255.226.50 (talk) 18:06, 19 August 2013 (UTC)[reply]

There have been edits of this page that delete text in response to old comments about missing citations. An example of this was the deletion of the following statement: "A proof can be found by means of the LSZ reduction, an identity from quantum field theory.[citation needed]"

• There was a partial citation (to the LSZ article in Wikipedia).
• Removing this statement did not improve the quality of the article. It degraded it.
• Please invest the effort find a peer-reviewed article that is missing if that is what bothers you.

This article is not in great shape, and deletions are generally not what is required. The work I did a while back on the Intro was intended to drag the article out of the "catastrophically wrong" category (a quote from a UC Berkeley faculty member, with which I agreed completely at the time).

("Catastrophically wrong" because prior versions of the FDT article had the basis and origin of the theorem completely wrong: e.g. the text appeared to have been written by sitting down with an undergraduate exposition that assumed equilibrium conditions for ease of derivation)

Pwfen (talk) 06:54, 29 August 2018 (UTC)[reply]

The 9 April 2019 version of the FDT page <https://en.wikipedia.org/w/index.php?title=Fluctuation-dissipation_theorem&oldid=891240986) states that "The fluctuation–dissipation theorem was originally formulated by Harry Nyquist in 1928". This is incorrect. Einstein's 1905 Brownian motion paper is the first published example of a fluctuation-dissipation relation. Pwfen (talk) 14:22, 9 April 2019 (UTC)[reply]

The fluctuation-dissipation theorem does not require thermal equilibrium to hold. It requires detailed balance to hold. Please see https://en.wikipedia.org/wiki/User_talk:Pwfen for a discussion of problems with the FDT page. Pwfen (talk) 09:37, 11 April 2019 (UTC)[reply]

There are few things that do not look 100% fine in that section and probably need some adjustment.

• The present strange formula ${\displaystyle {\text{Im}}\left[\chi (t)\right]=(\chi (t)-\chi (-t))/2i}$ comes from equation (2) in the cited paper... where it is stated that ${\displaystyle \chi ^{d}(t)=(\chi (t)-\chi (-t))/2i}$ is the "dissipative part" of the response function. I kind of understand what all this means... since the Fourier transform of ${\displaystyle \chi ^{d}(t)}$ is indeed ${\displaystyle {\text{Im}}\left[\chi (\omega )\right]}$. However, this looks a bit like a misleading formula to me and anyway calling this ${\displaystyle {\text{Im}}\left[\chi (t)\right]}$ is really weird since ${\displaystyle \chi (t)}$ is a real causal funcion and strictly speaking it does not have any imaginary part.

• There seems to be a sign inconsistency between :${\displaystyle \chi (t-t')=i\theta (t-t')\langle [{\hat {x}}(t),{\hat {x}}(t')]\rangle }$ and ${\displaystyle {\text{Im}}\left[\chi (t)\right]=-{\frac {1}{2}}\left[\langle {\hat {x}}(t){\hat {x}}(0)\rangle -\langle {\hat {x}}(0){\hat {x}}(t)\rangle \right]}$

• The final formula with the "+1/2" is just the symmetric part of ${\displaystyle S_{x}(\omega )}$... indeed ${\displaystyle S_{x}(\omega )=2\hbar [n_{BE}(\omega )+1]\chi (\omega )}$... plus 1, not plus 1/2.

• sometimes ${\displaystyle \hbar }$ is dropped, other times it's not... I am ok with ${\displaystyle \hbar =1}$ but then it should be used all the times.

Suggestions[edit]

I am ok with the initial discussion but I would refer to ${\displaystyle {\text{Im}}\left[\chi (\omega )\right]}$ and just drop this strange ${\displaystyle {\text{Im}}\left[\chi (t)\right]}$. Then I am ok with Kubo formula, this is a very good starting point

${\displaystyle \chi (t)={\frac {i\theta (t)}{\hbar }}\langle \left[x(t),x(0)\right]\rangle }$

if we take Kubo for granted then the final result can be derived just by a simple Fourier transform

${\displaystyle \chi (\omega )={\frac {i}{\hbar }}\int _{0}^{\infty }\langle \left[{\hat {x}}(t),{\hat {x}}(0)\right]\rangle e^{i\omega t}dt}$

so

${\displaystyle {\text{Im}}\left[\chi (\omega )\right]={\frac {\chi (\omega )-\chi ^{*}(\omega )}{2i}}={\frac {1}{2\hbar }}\int _{0}^{\infty }\langle \left[{\hat {x}}(t),{\hat {x}}(0)\right]\rangle e^{i\omega t}dt+{\frac {1}{2\hbar }}\int _{0}^{\infty }\langle \left[{\hat {x}}(0),{\hat {x}}(t)\right]\rangle e^{-i\omega t}dt={\frac {1}{2\hbar }}\int _{-\infty }^{+\infty }\langle \left[{\hat {x}}(t),{\hat {x}}(0)\right]\rangle e^{i\omega t}dt}$

then the following part is very correct: "In the canonical ensemble, the second term can be re-expressed as

${\displaystyle \langle {\hat {x}}(0){\hat {x}}(t)\rangle ={\text{Tr }}e^{-\beta {\hat {H}}}{\hat {x}}(0){\hat {x}}(t)={\text{Tr }}{\hat {x}}(t)e^{-\beta {\hat {H}}}{\hat {x}}(0)={\text{Tr }}e^{-\beta {\hat {H}}}\underbrace {e^{\beta {\hat {H}}}{\hat {x}}(t)e^{-\beta {\hat {H}}}} _{{\hat {x}}(t-i\hbar \beta )}{\hat {x}}(0)=\langle {\hat {x}}(t-i\hbar \beta ){\hat {x}}(0)\rangle }$

where in the second equality we re-positioned ${\displaystyle {\hat {x}}(t)}$ using the cyclic property of trace (in this step we have also assumed that the operator ${\displaystyle {\hat {x}}}$ is bosonic, i.e. does not introduce a sign change under permutation). Next, in the third equality, we inserted ${\displaystyle e^{-\beta {\hat {H}}}e^{\beta {\hat {H}}}}$ next to the trace and interpreted ${\displaystyle e^{-\beta {\hat {H}}}}$ as a time evolution operator ${\displaystyle e^{-{\frac {i}{\hbar }}{\hat {H}}\Delta t}}$ with imaginary time interval ${\displaystyle \Delta t=-i\hbar \beta }$."... and if we plug this in the previous equation we get

${\displaystyle {\text{Im}}\left[\chi (\omega )\right]={\frac {1}{2\hbar }}\int _{-\infty }^{+\infty }\langle {\hat {x}}(t){\hat {x}}(0)-{\hat {x}}(t-i\hbar \beta ){\hat {x}}(0)\rangle e^{i\omega t}dt={\frac {1-e^{-\beta \hbar \omega }}{2\hbar }}\int _{-\infty }^{+\infty }\langle {\hat {x}}(t){\hat {x}}(0)\rangle e^{i\omega t}dt={\frac {1-e^{-\beta \hbar \omega }}{2\hbar }}S_{x}(\omega )}$

and finally, with minor reshuffling of the factors, to

${\displaystyle S_{x}(\omega )=2\hbar \left[n_{\rm {BE}}(\omega )+1\right]{\text{Im}}\left[\chi (\omega )\right]}$

where ${\displaystyle n_{\rm {BE}}(\omega )=1/\left(e^{\beta \hbar \omega }-1\right)}$: note here we have a ${\displaystyle +1}$, not ${\displaystyle +1/2}$. The ${\displaystyle 1/2}$ makes sense but only because the same calculation for ${\displaystyle -\omega }$ yields

${\displaystyle S_{x}(-\omega )=2\hbar \left[n_{\rm {BE}}(\omega )\right]{\text{Im}}\left[\chi (\omega )\right]=e^{-\beta \hbar \omega }S_{x}(\omega )}$

without the +1. So the cited formula with ${\displaystyle 1/2}$ is just the symmetric part of power spectral density ${\displaystyle (S_{x}(\omega )+S_{x}(-\omega ))/2}$. In quantum noise ${\displaystyle S_{x}(\omega )}$ is not symmetric and, consistently, the autocorrelation ${\displaystyle \langle x(t)x(0)\rangle }$ contains an imaginary part. This is something that is not particularly trivial/intuitive and might deserve a separate discussion... possible reference/examples here^[1]

Wikirod76 (talk) 00:57, 9 January 2021 (UTC)[reply]

The parenthetical statement that "in this step we have also assumed that the operator ${\displaystyle {\hat {x}}}$ is bosonic, i.e. does not introduce a sign change under permutation" appears unnecessary. The cyclic property of the trace is general, and doesn't require this assumption.

WinterSyzygy (talk) 03:33, 10 June 2021 (UTC)[reply]