经典极限
动作(物理)
路径积分公式
量子纠缠
物理
经典力学
Dirac(视频压缩格式)
波函数
量子
自由度(物理和化学)
量子特性法
歧管(流体力学)
经典容量
数学
量子力学
奇点
量子动力学
经典物理学
动量(技术分析)
费曼图
波函数崩溃
职位(财务)
最小作用原理
功能(生物学)
操作员(生物学)
张量积
数学物理
动量算符
量子态
第一量子化
正规化(语言学)
运动方程
量子混沌
产品(数学)
时间演化
自由粒子
公制(单位)
作者
Winfried Lohmiller,Jean-Jacques Slotine
标识
DOI:10.1098/rspa.2025.0413
摘要
Abstract We show that the Schrödinger equation can be solved exactly based only on classical least action. Fundamental postulates of quantum mechanics can in turn be derived directly from this construction. The results extend to the relativistic Klein-Gordon, Pauli, and Dirac equations, and suggest a smooth transition between physics across scales. Most quantum mechanics problems have classical versions which involve multiple least action solutions. The associated classical multipaths stem either from the initial position or momentum distribution, or from branch points, generated, e.g. by a multiply connected manifold (double slit experiment), by spatial inequality constraints (particle in a box), or by a singularity (Coulomb potential). We show that the exact Schrödinger wave function ψ can be constructed by combining this classical multi-valued action ϕ with the classical density ρ, computed analytically from ϕ along each extremal action path. The construction is general and does not involve any semi-classical approximation. Quantum wave collapse at measurement can be derived from the classical density change. Entanglement corresponds to a sum of classical particle actions mapping to a tensor product of spinors. The results also provide a simpler computational alternative to Feynman path integrals, as they use only a minimal subset of classical paths.
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