Wednesday, May 8, 2019

anticommutator - A problem with indistinguishable fermions and the order of applying operators


This question comes in consequence of another one.


I want to stress a problem that none of the answers addressed it. For making my problem more understandable let me first remind a well-known state, the spin-singlet of spin $1/2$ fermions,


$$|S\rangle = \frac {|\uparrow\rangle |\downarrow\rangle - |\downarrow\rangle |\uparrow\rangle}{\sqrt {2}}. \tag{1}$$


The two fermions are completely identical, though, we try to keep track of their identity by writing in each product first the fermion 1 and second the fermion 2. The position of the fermion in the product keeps track of the identity of the fermion. If we interchange the fermions,


$$|S\rangle = -\frac {|\downarrow\rangle |\uparrow\rangle - |\uparrow\rangle |\downarrow\rangle}{\sqrt {2}}, \tag{2}$$


the state changes sign.


Now, to my problem. Let's begin with a state comprising a single fermion with spin up


$$\psi_0 = |\uparrow \rangle \tag{3}$$



A) To this state I add a new fermion. From now on, I will refer to the old fermion as fermion 1, and to the newly added fermion as fermion 2. If the twob fermions were distinguishable, their positions in any product should be according to their names, $a_{\downarrow}^{\ \dagger} \psi_0 = |\uparrow \rangle |\downarrow\rangle$. But they are not independent. They arrange themselves anti-symmetrically, in the state $|S\rangle$. None of them has anymore a well-defined spin-projection, we can't say anymore that the fermion 1 (old fermion) is in the spin-up state.


In continuation I apply the annihilation operator $a_{\uparrow}$. Note again, it is not clear which one of the fermions will be destroyed, 1 or 2. So the state we get, rigorously speaking, is something like this


$$|\psi_1\rangle = \frac {|0_{\uparrow}\rangle |\downarrow\rangle - |\downarrow\rangle |0_{\uparrow}\rangle}{\sqrt {2}}. \tag{4}$$


There is no such Fock state, the Fock state is


$$|\psi_1\rangle = |\downarrow\rangle \tag{5}$$.


The form $(4)$ just stresses that we don't know which one of the fermions was destroyed.


B) However, starting from the state $\psi_0$ and applying the two operations in inverse order, the situation is totally different. First of all one creates vacuum,


$$a_{\uparrow} \psi_0 = |0\rangle . \tag{6}$$


So, fermion 1 is destroyed. Applying the creation operator $a_{\downarrow}^{\ \dagger}$ to the vacuum, one obtains the fermion 2.


$$ |\psi_2\rangle = a_{\downarrow}^{\ \dagger}|0\rangle = |\downarrow\rangle . \tag{7}$$



Obviously, it's a different situation because here we have full knowledge of which one of the fermions was present and when. Also, it's not clear where from should appear the minus sign in $(7)$ to the difference from $(5)$.


What can be wrong here?


Please notice that I tried to stick to the phenomenology. I am against introducing manipulations with vacuum which are not involved in the sequence of events described above. Also, please don't send me other questions about fermions.



Answer



I will formalise my comments into an answer, and try to introduce a notation that might avoid some of the confusions in the OP. The correct way to think about creation and annihilation operators, Fock spaces and so on, is in the occupation-number representation, where we write the basis states in terms of the number of quanta $n_i$ carrying a given value of all possible quantum numbers, denoted collectively as $i$. These states are written as: $$ \lvert n_a n_b n_c \cdots \rangle = \left(\prod_i \frac{1}{\sqrt{n_i!}} \right)(c_a^\dagger)^{n_a} (c_b^\dagger)^{n_b} (c_c^\dagger)^{n_c} \cdots \lvert 0\rangle. \tag{1}$$ For bosons, the numbers $n_a$ can take any value, in the absence of other constraints. When one is dealing with fermions, the Pauli principle tells you that $n_a = 0,1$ for all quantum numbers $a, b, c, \ldots$. The exchange symmetry is enforced by defining the ladder operators to obey canonical (anti-)commutation relations $[c_a,c_b^\dagger] = \delta_{ab}$ ($\{c_a,c_b^\dagger\} = \delta_{ab}$). Some people like to call this representation "second quantisation". It differs from the "first quantised" representation, where one writes the states as $$ \lvert n_a n_b n_c \cdots \rangle = \mathcal{S}_\pm \left[\lvert a\rangle^{\otimes n_a} \otimes \lvert b\rangle^{\otimes n_b} \otimes\lvert c\rangle^{\otimes n_c} \otimes \cdots \right], \tag{2}$$ where each factor in the tensor product corresponds to a distinguished particle, and we thence apply a combined (anti-)symmetrisation and subsequent normalisation operation $\mathcal{S}_\pm$ to get the correct exchange statistics for identical particles. The advantage of representation (1) over representation (2) becomes crystal clear as soon as you try to write down any non-trivial many-body state.


Now, to the main part of the question. The definition of the Fermi operators $c_a \lvert 0 \rangle = 0$, combined with the canonical anti-commutation relations, imply that these operators do not simply "annihilate" particles, unlike the bosonic case. There are also some tricky phase factors which must be tracked carefully. This is taken care of automatically using the form on the right-hand side of (1). However, if you insist on using the form on the left-hand side, you should find that $$ c_d\lvert n_a \ldots n_d \ldots \rangle = \delta_{n_d,1}(-1)^{\sum_{i

Specifying to to the example from the OP, one would like to "prove" the canonical anti-commutation relations (although they are actually part of the definition of $c_a$), by considering the action of $\{c_\uparrow,c_\downarrow^\dagger\}$ on the state $\lvert \uparrow \rangle = |0_\downarrow 1_\uparrow \rangle$ (these are the "first" and "second quantised" representations, respectively). These manipulations will go via the intermediate states $(\lvert\downarrow \rangle \lvert\uparrow\rangle - \lvert\uparrow \rangle \lvert\downarrow\rangle)/\sqrt{2} = \lvert 1_\downarrow 1_\uparrow \rangle $ and $\lvert \downarrow \rangle = |1_\downarrow 0_\uparrow \rangle$ . We have $$c_\uparrow c_\downarrow^\dagger \lvert 0_\downarrow 1_\uparrow \rangle = c_\uparrow|1_\downarrow 1_\uparrow \rangle = -|1_\downarrow 0_\uparrow \rangle, $$ where in the last step we used (3). On the other hand, one has $$ c_\downarrow^\dagger c_\uparrow \lvert 0_\downarrow 1_\uparrow \rangle = c_\downarrow^\dagger \lvert 0_\downarrow 0_\uparrow \rangle = \lvert 1_\downarrow 0_\uparrow \rangle. $$ Therefore, we have confirmed that $\{c_\uparrow,c_\downarrow^\dagger\} = 0$ in this case.


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