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1. • CommentRowNumber1.
   • CommentAuthorDavid_Corfield
   • CommentTimeOct 16th 2009
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   Author: David_Corfield
   Format: HtmlBegan <a href="http://ncatlab.org/nlab/show/matrix+mechanics">entry</a> with that name.

   Began entry with that name.
2. • CommentRowNumber2.
   • CommentAuthorzskoda
   • CommentTimeOct 19th 2009
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   Author: zskoda
   Format: TextSo what kind of 'matrix mechanics' (which rig) applies to the Matsubara formalism ?

   So what kind of 'matrix mechanics' (which rig) applies to the Matsubara formalism ?
3. • CommentRowNumber3.
   • CommentAuthorUrs
   • CommentTimeOct 19th 2009
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   Author: Urs
   Format: MarkdownI am not entirely happy with the terminology here: to me "matrix mechanics" is an old and outdated historical way to look at quantum mechanics. What is outdated about it is that it was an attempt to understand the structures in QM using naive _finite dimensional_ linear algebra. But the operators in QM are in general not matrices, of course, but operators on infinite-dimensional Hilbert spaces. To some extent it is useful to think of these as being just matrices, but just to some extent. I think it would be better to speak about operator algebra _linear over an arbitrary rig_. In examples it makes sense to restrict to the fin dim case and speak of matrix mechanics there, but for the general case I find it a bit anachronistic. Even in fin-dim linear algebra: speaking of matrices is always a bit [[evil]], of course. We don't want to be that evil on the nLab, do we?

   I am not entirely happy with the terminology here:

   to me "matrix mechanics" is an old and outdated historical way to look at quantum mechanics. What is outdated about it is that it was an attempt to understand the structures in QM using naive finite dimensional linear algebra.

   But the operators in QM are in general not matrices, of course, but operators on infinite-dimensional Hilbert spaces. To some extent it is useful to think of these as being just matrices, but just to some extent.

   I think it would be better to speak about operator algebra linear over an arbitrary rig. In examples it makes sense to restrict to the fin dim case and speak of matrix mechanics there, but for the general case I find it a bit anachronistic.

   Even in fin-dim linear algebra: speaking of matrices is always a bit evil, of course. We don't want to be that evil on the nLab, do we?

4. • CommentRowNumber4.
   • CommentAuthorDavid_Corfield
   • CommentTimeOct 19th 2009
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   Author: David_Corfield
   Format: HtmlA name change is fine, but isn't there something snappier than 'operator algebra linear over an arbitrary rig'? How about 'rig mechanics?

   A name change is fine, but isn't there something snappier than 'operator algebra linear over an arbitrary rig'? How about 'rig mechanics?
5. • CommentRowNumber5.
   • CommentAuthorJonAwbrey
   • CommentTimeOct 19th 2009
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   Author: JonAwbrey
   Format: MarkdownExtremism in defense of Jacobins may be morally suspect, but Jacobeans are well and good on balance.

   Extremism in defense of Jacobins may be morally suspect, but Jacobeans are well and good on balance.

6. • CommentRowNumber6.
   • CommentAuthorJonAwbrey
   • CommentTimeOct 19th 2009
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   Author: JonAwbrey
   Format: MarkdownRe: A name change is fine, but isn't there something snappier than "operator algebra linear over an arbitrary rig"? How about "rig mechanics"? Where I come from, a rig mechanic might be regarded as one type of "roughneck". His immediate supervisor would be called a "tool pusher". But maybe "derrick" (= Der(Rig)?) would do the trick?

   Re: A name change is fine, but isn't there something snappier than "operator algebra linear over an arbitrary rig"? How about "rig mechanics"?

   Where I come from, a rig mechanic might be regarded as one type of "roughneck". His immediate supervisor would be called a "tool pusher".

   But maybe "derrick" (= Der(Rig)?) would do the trick?

7. • CommentRowNumber7.
   • CommentAuthorTodd_Trimble
   • CommentTimeOct 19th 2009
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   Author: Todd_Trimble
   Format: MarkdownI think one could keep the page title (since it's a well-known term) but also echo Urs and start with something like "Matrix mechanics is an old-fashioned name for..." and then work one's way into talking about the new-fangled ways of thinking about what this is all about.

   I think one could keep the page title (since it's a well-known term) but also echo Urs and start with something like "Matrix mechanics is an old-fashioned name for..." and then work one's way into talking about the new-fangled ways of thinking about what this is all about.

8. • CommentRowNumber8.
   • CommentAuthorUrs
   • CommentTimeOct 19th 2009
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   Author: Urs
   Format: MarkdownI am fine with Todd's suggestion, but maybe just one more remark to amplify the point even further: in the field of algebraic quantum mechanics and algebraic quantum field theory ([[AQFT]]) there is a strong consensus that QM is all about [[C-star algebra]]s and in particular [[von Neumann algebra]]s. Parts of that is presently be absorbed and re-expressed by [[factorization algebra]] methods, where people do indeed also consider the transition from classical to qm-systems by changing their codomains. Kevin Costello keeps on his web page the pdf file version of a book he writes on this stuff.

   I am fine with Todd's suggestion, but maybe just one more remark to amplify the point even further:

   in the field of algebraic quantum mechanics and algebraic quantum field theory (AQFT) there is a strong consensus that QM is all about C-star algebras and in particular von Neumann algebras. Parts of that is presently be absorbed and re-expressed by factorization algebra methods, where people do indeed also consider the transition from classical to qm-systems by changing their codomains. Kevin Costello keeps on his web page the pdf file version of a book he writes on this stuff.

9. • CommentRowNumber9.
   • CommentAuthorzskoda
   • CommentTimeOct 19th 2009
   • (edited Oct 19th 2009)
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   Author: zskoda
   Format: TextI am not used even to talk "rig", even more rig mechanics. Heisenberg DISCOVERED quantum mechanics doing Fourier modes and calculating with amplitudes. One can always start with bound system and go to the limit of infinite-dimenional system, thus matrix mechanics and discrete spectrum does show the essence. It is like sums vs. integrals. You say that sum is outdated way of thinking of integrating ? I don't think so and will never be. On the other hand, there are infinite matrices all around the place, and I see no reason to forbid matrices once you are in infinite-dimensions. The only thing is one has to be careful with spectral measures once in the continuous spectrum. So how about my question ? Whih "rig" corresponds to Matsubara formalism ? I mean once you talk about formalising finite-temperature and quantum world in the same formalism, why not testing it if one can include the most useful formalism synthesising the two. By the way, Lawvere was never happy with Hilbert space.

   I am not used even to talk "rig", even more rig mechanics.
   
   Heisenberg DISCOVERED quantum mechanics doing Fourier modes and calculating with amplitudes.
   One can always start with bound system and go to the limit of infinite-dimenional system, thus
   matrix mechanics and discrete spectrum does show the essence. It is like sums vs. integrals. You say that sum is outdated way of thinking of integrating ? I don't think so and will never be.
   
   On the other hand, there are infinite matrices all around the place, and I see no reason to forbid matrices once you are in infinite-dimensions. The only thing is one has to be careful with spectral measures once in the continuous spectrum.
   
   So how about my question ? Whih "rig" corresponds to Matsubara formalism ? I mean once you talk about formalising finite-temperature and quantum world in the same formalism, why not testing it if one can include the most useful formalism synthesising the two.
   
   By the way, Lawvere was never happy with Hilbert space.
10. • CommentRowNumber10.
    • CommentAuthorDavid_Corfield
    • CommentTimeOct 20th 2009
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    Author: David_Corfield
    Format: HtmlI've never looked at the Matsubara formalism, but maybe that's why John hinted to us <a href="http://golem.ph.utexas.edu/category/2007/02/quantization_and_cohomology_we_12.html#c007506">here</a> that 'temperature lives on the Riemann sphere'.

    I've never looked at the Matsubara formalism, but maybe that's why John hinted to us here that 'temperature lives on the Riemann sphere'.