The discussion centers on the relationship between fermions and coherent states, exploring the implications of quantum mechanics on classical physics. Participants examine the limitations of fermions in forming coherent states, the implications of the univalence superselection rule, and the existence of coherent states in various contexts, including quantum field theory.
Participants express differing views on the existence and nature of coherent states for fermions, with some asserting limitations while others propose alternative frameworks. The discussion remains unresolved regarding the applicability and definition of coherent states in the context of fermions.
Limitations include the dependence on the definitions of coherent states and the unresolved implications of the univalence superselection rule on the superposition of fermionic states.
Demystifier said:Coherent states contain many particles in the same state, which is impossible for fermions.
DrDu said:Due to the univalence superselection rule, superpositions of states with different numbers of fermions don't exist, hence there are also no fermion coherent states made up from states with different numbers of particles.
But for a connection with classical physics this isn't important:For photons, position and momentum operators are non-diagonal in particle number while for fermions, position and momentum are diagonal in particle number.
Hence the coherent states relevant for fermions for discussing the classical limit are wave packets with sharp particle numbers.
As I said,What about one particle(fermion) problems?Coherent states contain many particles in the same state, which is impossible for fermions.
Well,I was looking for the reason that why it seems impossible at first and then a change of view makes it OK!There indeed exists a definition for coherent states for fermions which is quite important for the path-integral formulation of (non-relativistic as well as relativistic) quantum field theory. The complication noted by Demystifier needs to be overcome by introducing Grassmann valued c-number fields. See, e.g., my QFT manuscript
Taking the definition of "coherent state" as one of "minimal uncertainty" is too restrictive. Generalized coherent states can be constructed group-theoretically, and the construction is applicable to a surprisingly large number of cases.Shyan said:I was looking for the reason that why it seems impossible at first and then a change of view makes it OK!
Demystifier said:Coherent states contain many particles in the same state, which is impossible for fermions.
DrDu said:That depends. You can also construct coherent states for e.g. a harmonic oscillator.
The original question in the first post, referring to fermions, suggested that one had the many-particle field-theoretic notion of coherent state in mind.Shyan said:Also,in a one particle problem,the issues you mentioned can't arise!
As I said,What about one particle(fermion) problems?
True. Or from a mathematical point of view, Grassmannian coherent states are not states in the (physical) complex Hilbert space.DrDu said:The Grassmannian coherent states mentioned by van Hees are indeed an important formal concept in QFT, but they can't be prepared as actual states. So you can't think of classical states of fermions as limits of Grassmannian coherent states.