Neutron Interferometry

Let

R_{\hat{n}}(\theta) = e^{-i \theta \hat{J}_{\hat{n}} / \hbar}

This is how you rotate a quantum state by an angle $\theta$ around $\hat{n}$ where $\hat{J}_{\hat{n}}$ is the angular momentum operator along $\hat{n}$ .

We experimentally observed that

R_x(2\pi) = e^{-i 2\pi \hat{S}_x / \hbar} = -I, \qquad R_x(4\pi) = I

Given a $\hat{S_x}$ operation, turning it $\theta=2\pi$ causes there to be a negative sign infront of the $I$ . Rotating it another $2\pi$ causes it to return to the same state. This is definitely not how it works in classical physics, where if you rotate something $2\pi$ you’d get right back to where it started. This actually means we live in a $4\pi$ -world through experimental verification.

This was tested by using a neutron interferometer. Basically, imagine if a neutron at $\left\lvert \psi \right\rangle$ hits a silicon crystal beam splitter. The state of the neutron is its position $\{u,l\}$ tensor product its spin $\{+, -\}$ . This is just how we define it.

Basis: $\{\left\lvert n,+ \right\rangle,\ \left\lvert n,- \right\rangle,\ \left\lvert \ell,+ \right\rangle,\ \left\lvert \ell,- \right\rangle\}$

\left\lvert \psi \right\rangle = \left\lvert \text{position} \right\rangle \otimes \left\lvert \text{spin} \right\rangle

Neutron beam splitter (silicon crystal): $\left\lvert n,s \right\rangle$ splits into transmitted $\left\lvert n,s \right\rangle$ and reflected $\left\lvert \ell,s \right\rangle$ .

(B \otimes I)\left\lvert n,s \right\rangle = \tfrac{1}{\sqrt{2}}\bigl(\left\lvert n \right\rangle + \left\lvert \ell \right\rangle\bigr) \otimes \left\lvert s \right\rangle

(B \otimes I)\left\lvert \ell,s \right\rangle = \tfrac{1}{\sqrt{2}}\bigl(\left\lvert n \right\rangle - \left\lvert \ell \right\rangle\bigr) \otimes \left\lvert s \right\rangle

B = \frac{1}{\sqrt{2}} \begin{pmatrix} 1 & 1 \\ 1 & -1 \end{pmatrix}

The lower path passes through a static magnetic field $B$ , which applies a spin rotation $R_x(\theta)$ . The two paths recombine at a second beam splitter, with detectors $D_0$ and $D_1$ on the two outputs.

The full evolution is

\left\lvert \psi_{\text{out}} \right\rangle = (B \otimes I)\, U\, (B \otimes I)\, \left\lvert u, s \right\rangle

where the magnetic field implements the conditional rotation

U = \left\lvert u \right\rangle\left\langle u \right\rvert \otimes I + \left\lvert \ell \right\rangle\left\langle \ell \right\rvert \otimes R_x(\theta).

Case $\theta = 2\pi$ :

\left\lvert u, s \right\rangle \xrightarrow{B \otimes I} \tfrac{1}{\sqrt{2}}\bigl(\left\lvert u \right\rangle + \left\lvert \ell \right\rangle\bigr) \otimes \left\lvert s \right\rangle

\xrightarrow{R_x(2\pi) = -I} \tfrac{1}{\sqrt{2}}\bigl(\left\lvert u \right\rangle - \left\lvert \ell \right\rangle\bigr) \otimes \left\lvert s \right\rangle \xrightarrow{B \otimes I} \left\lvert \ell, s \right\rangle

$\Rightarrow$ neutron at $D_1$ .

Case $\theta = 4\pi$ :

\left\lvert u, s \right\rangle \longrightarrow \left\lvert u, s \right\rangle \quad\Rightarrow\text{ neutron at } D_0.

This is fully deterministic as in general, the probability $P(D_0) = \cos^2(\theta/4)$ and $P(D_1) = \sin^2(\theta/4)$ , so $\theta = 2\pi, 4\pi$ are the special tunings where one probability hits $1$ .

This is the physical consequence of $R_{\hat{n}}(2\pi) = -I \neq I$ .

This experimentally proves that we live in a $4\pi$ -world.