Space-time-symmetric quantum mechanics in 3+1 dimensions
| Autor: | Dias, Eduardo O. |
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| Rok vydání: | 2023 |
| Předmět: | |
| Druh dokumentu: | Working Paper |
| Popis: | In conventional quantum mechanics (QM), time is treated as a parameter, $t$, and the evolution of the quantum state with respect to time is described by ${\hat {H}}|\psi(t)\rangle=i\hbar \frac{d}{dt}|\psi(t)\rangle$. In a recently proposed space-time-symmetric (STS) extension of QM, position becomes the parameter and a new quantum state, $|\phi(x)\rangle$, is introduced. This state describes the particle's arrival time at position $x$, and the way the arrival time changes with respect to $x$ is governed by ${\hat {P}}|\phi(x)\rangle=-i\hbar \frac{d}{dx} |\phi(x)\rangle$. In this work, we generalize the STS extension to a particle moving in three-dimensional space. By combining the conventional QM with the three-dimensional STS extension, we have a ``full'' STS QM given by the dynamic equation ${\hat { P}}^{\mu}|{\phi }^\mu(x^{\mu})\rangle=- i \hbar~\eta^{\mu\nu}\frac{d}{dx^{\nu}}|{\phi}^\mu (x^{\mu})\rangle$, where $x^{\mu}$ is the coordinate chosen as the parameter of the state. Depending on the choice of $x^\mu$, we can recover either the Schr\"odinger equation (with $x^\mu=x^0=t$) or the three-dimensional STS extension (with $x^\mu=x^i=$ either $x$, $y$, or $z$). By selecting $x^\mu=x$, we solve the dynamic equation of the STS QM for a free particle and calculate the wave function $\langle t,y,z|\phi^1(x)\rangle$. This wave function represents the probability amplitude of the particle arriving at position ($y$,$z$) at instant $t$, given that the detector occupies the entire $yz$-plane located at position $x$. Remarkably, we find that the integral of $|\langle t,y,z|\phi (x)\rangle|^2$ in $y$ and $z$ takes the form of the three-dimensional version of the axiomatic Kijowski distribution. Comment: 7 pages |
| Databáze: | arXiv |
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