Why all operators in QM have a Hermitian Matrices

In summary: But then something happened which caused the entropy to increase. This increase in entropy is what we see happening in our universe today.In summary, the entropy of the universe has increased over time.yes entropy has increased over time.Entropy is a measure of disorder in a system.
  • #1
mwalmasri
23
0
Why all operators in QM have a Hermitian Matrices ?
 
Physics news on Phys.org
  • #3
yes so all operators have a self-adjoint Matrices, which operator can be Represented as anti-Hermitian operators?
 
  • #4
mwalmasri said:
yes so all operators have a self-adjoint Matrices, which operator can be Represented as anti-Hermitian operators?

It's not true that all operators are Hermitian, The simplest example would be i times any Hermitian operator, it's anti-Hermitian.
You may be asking why any operator representing observable is Hermitian. There is no proof for this because this is simply one of the postulates of QM. But if it's not true, you will have an observable that has complex-value eigenvalue, which doesn't make any physical sense.
 
  • #5
yes,when I asked the question I mean a physical operator like a Hamiltonian... maybe I must be clear enough in my question. Hermitian is used because its have a real eigenvalue that is right...
Thanks
 
  • #6
The eigenvalues of a hermitian operator are real,like hamiltonian which should be hermitian operator because it's eigenvalues are simply energy,which should be a real quantity.So all observables are associated with hermitian operator.
Assume a hermitian operator,and the eigenvalue eqn
A|a>=a|a>,assuming normalization of eigenstates,multiplying by <a|
<a|A|a>=a
taking complex conjugate of both sides,
<a|A|a>*=a*,
By hermiticity condition,<a|A|a>=<a|A|a>*,so a=a* implying reality of eigenvalues.
 
Last edited:
  • #7
Basically it's a postulate of QM.

The way I like to look at it however is as follows. Suppose we have some observational apparatus with n possible outcomes that have some real number yi assigned to each outcome. List them out as a vector and write it as sum yi |bi>. Now we come to a problem - its not basis independent - change to another basis and the yi change - but since the choice of basis is entirely arbitrary we expect nature to be independent of that choice. To get around that problem QM simply replaces the |bi> by |bi><bi| to give sum yi |bi><bi| which is the same regardless of basis. It is a Hermitian operator whose eigenvalues are the possible outcomes of the observation.

Thanks
Bill
 

Why do all operators in quantum mechanics have Hermitian matrices?

The reason for this is that Hermitian matrices represent observables in quantum mechanics. This means that the eigenvalues of the matrix correspond to the possible outcomes of a measurement of that observable, and the eigenvectors represent the states in which the observable is well-defined.

What is the physical significance of Hermitian matrices in quantum mechanics?

Hermitian matrices are important in quantum mechanics because they correspond to observables, which are physical quantities that can be measured. The Hermitian property ensures that the eigenvalues and eigenvectors are real, which is necessary for a physically meaningful measurement.

How do Hermitian matrices relate to the uncertainty principle in quantum mechanics?

The uncertainty principle states that certain pairs of observables cannot be measured simultaneously with arbitrary precision. Hermitian matrices play a role in this principle by representing compatible observables, which can be measured with arbitrary precision at the same time. Non-compatible observables, on the other hand, do not have Hermitian matrices and cannot be measured simultaneously with arbitrary precision.

Are there any exceptions to the rule that all operators in quantum mechanics have Hermitian matrices?

Yes, there are exceptions. Some operators, such as the time evolution operator, do not have Hermitian matrices. However, even in these cases, the operator can be written as a linear combination of Hermitian matrices.

Can two different Hermitian matrices represent the same observable in quantum mechanics?

No, two different Hermitian matrices cannot represent the same observable. This is because the eigenvalues and eigenvectors of a Hermitian matrix uniquely determine the observable it represents. Therefore, any two Hermitian matrices representing the same observable must be equal.

Similar threads

I A strange definition for Hermitian operator
    • Quantum Physics
Replies
3
Views
698
I Is the product of two hermitian matrices always hermitian?
    • Quantum Physics
3
Replies
93
Views
9K
B Is the Momentum Operator Hermitian? A Proof
    • Quantum Physics
Replies
7
Views
980
I Completeness of Eigenfunctions of Hermitian Operators
    • Quantum Physics
Replies
20
Views
358
A How can we measure these Hermitian operators?
    • Quantum Physics
Replies
9
Views
1K
I Hermitian operators in QM and QFT
    • Quantum Physics
Replies
7
Views
2K
I Hermitian Operators in QM
    • Quantum Physics
Replies
3
Views
1K
I QM: I as an Observable & Its Eigenvectors & Eigenvalue
    • Quantum Physics
Replies
3
Views
1K
I Understanding Quantum Operators: Exploring Hermitian Matrices and Degeneracy
    • Quantum Physics
Replies
10
Views
2K
I Dirac Notation for Operators: Ambiguity in Expectation Values?
    • Quantum Physics
Replies
5
Views
955

Hot Threads

Recent Insights

Back
Top