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Use this tag when having questions concerning expressions with the trace of a matrix/operator.

0 votes
1 answer
432 views

Positive Semi-Definiteness of a Density Matrix - can the eigenvalues be larger than 1?

I know that one of the requirements for a density matrix is that it is positive-semidefinite. This means that the eigenvalues are non-negative (and sum to 1, so we can assign them the meaning of proba …
QuantumEyedea's user avatar
1 vote
1 answer
718 views

Tracing over a Fock space?

If you were to compute a trace using these states as a basis, how would you do this? …
QuantumEyedea's user avatar
5 votes
0 answers
206 views

Open Quantum Systems: Born-Approximation and the preservation of Trace, Hermicity and Positi...

My Question: Suppose $\sigma(0)$ is trace 1, Hermitian and positive. This means that $\varrho(0)$ is also trace 1, Hermitian and positive. Are these properties preserved for $\varrho(t)$ with $t>0$? … Here are my thoughts: Preservation of Trace: taking the trace of the above evolution equation yields $\mathrm{Tr}[\dot{\varrho}_I(t)]=0$ because the equation contains commutators of finite-dimensional …
QuantumEyedea's user avatar
0 votes
1 answer
42 views

How to show that $0 \leq \mathrm{tr}[\rho P] \leq 1$ for a density matrix $\rho$ and a proje... [closed]

Let $\rho$ be a density matrix for hilbert space of dimension $n$ (satisfying $\rho^\dagger = \rho$ and $\mathrm{tr}[\rho] =1$ and $\rho \geq 0$). Let $P$ be a projection operator. This means $P^2 = P …
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