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My question is whether two electrons can be entangled only with respect to their spins but not with respect to some other observable, such as position.

I initially believed that spin-entanglement doesn't entail position or momentum entanglement. But if particles $a$ and $b$ have a composite state given by $|\Psi\rangle_{ab} = \frac{1}{\sqrt2}(|1\rangle|0\rangle + |0\rangle|1\rangle)$, where $|0\rangle$ and $|1\rangle$ are distinct z-spin eigenstates, then it would mean that a single particle, say, $a$, does not have a quantum state in the single-particle Hilbert space for $a$, $\mathscr{H}_a$.

Since the state of the particle $a$ can only be represented by a reduced density matrix and does not correspond to any vector in $\mathscr{H}_a$, its position or momentum would not be expressible in terms of position or momentum eigenstates in $\mathscr{H}_a$. It seems that this can only mean that $a$ and $b$ are entangled with respect to any (single-particle) observable.

Is this correct? If so, however, what about their mass or charge? It seems weird to think that the particle doesn't have an eigenstate concerning mass and charge in $\mathscr{H}_a$.

Mauricio
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Lory
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    I'm not going to write a full answer because I expect someone will do a much better job than I am capable of. But when I represent a single electron wave function, don't I usually need to include both a spatial part and a spin part, if I'm working in position space? And for two electrons I can for instance imagine both electrons sharing the same spatial part of the wave function (symmetric in space) but antisymmetric in their spin parts. – Marius Ladegård Meyer Apr 21 '23 at 18:17
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    @MariusLadegårdMeyer this goes even further: electrons, being fermions, must have an overall antisymmetric state, so if the spatial (spin) part is symmetric (antisymmetric) then the spin (spatial) part must be antisymmetric (symmetric). We know that the antisymmetric part must be entangled (see the singlet state for spins), while a symmetric part may or may not be entangled (contrast the states $|x\rangle|x\rangle$ vs $(|x\rangle|y\rangle+|y\rangle|x\rangle)/\sqrt{2}$). – Quantum Mechanic Apr 21 '23 at 20:25
  • may be my answer here will help https://physics.stackexchange.com/questions/439450/how-do-we-know-quantum-entanglement-works-no-matter-the-distance/439469#439469 – anna v Apr 22 '23 at 05:57

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There is no particular requirement that spin entangled electrons - or photons or other quantum particles/systems - ever be entangled on another basis initially. Obviously, there are many cases where there is both spin and momentum entanglement from the get-go.

The most clear cut scenario for creating spin-only entangled pairs is through entanglement swapping. In these scenarios, entanglement is created between pairs that do not interact directly. Instead, a pair of photons is used to as an intermediary "catalyst" to entangle the target pair (which are usually electrons or photons). This is done by subjecting the photon pair to a Bell State Analyzer (BSA), also called a Bell State Measurement (BSM). Certain outcomes of this measurement project the targets into a known spin entangled state - even though the targets have not interacted. The target pair is not entangled on any other basis other than spin.

Spin entangled electrons: https://arxiv.org/abs/1508.05949 Polarization entangled photons:https://arxiv.org/abs/quant-ph/0409093

DrChinese
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