Quantum Beam Scattering—Beam’s Coherence Length, Which-Path Information andWeak Values

IF 1.3 Q3 INSTRUMENTS & INSTRUMENTATION

Quantum Beam Science Pub Date : 2023-08-15 DOI:10.3390/qubs7030026

C. Chatzidimitriou-Dreismann

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Abstract

The conventional theory of neutron beams interacting with many-body systems treats the beam as a classical system, i.e., with its dynamical variables appearing in the quantum dynamics of the scattering process not as operators but only as c-numbers. Moreover, neutrons are described with plane waves, i.e., the concept of a neutron’s (finite) coherence length is here irrelevant. The same holds for electron, atom or X-ray scattering. This simplification results in the full decoupling of the probe particle’s dynamics from the quantum dynamics of the scatterer—a well-known fact also reflected in the standard formalism of time-correlation functions (see textbooks). Making contact with modern quantum-theoretical approaches (e.g., quantum entanglement, “which-path information” versus interference, von Neumann measurement, Weak Values (WV), etc.), new observable effects of non-relativistic quantum beam scattering may be exposed and/or predicted, for instance, a momentum-transfer deficit and an intensity deficit in neutron scattering from protons of hydrogen-containing samples. A new WV-theoretical treatment is provided, which explains both these “deficit effects” from first principles and on equal footing.

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量子光束散射——光束相干长度、路径信息和弱值

中子束与多体系统相互作用的传统理论将中子束视为经典系统，即其动力学变量在散射过程的量子动力学中不是作为算符而只是作为c数出现。此外，中子是用平面波来描述的，也就是说，中子(有限)相干长度的概念在这里是无关紧要的。这同样适用于电子、原子或x射线散射。这种简化导致探针粒子的动力学与散射体的量子动力学完全解耦——这一众所周知的事实也反映在时间相关函数的标准形式中(参见教科书)。与现代量子理论方法(例如，量子纠缠，“路径信息”与干涉，冯·诺伊曼测量，弱值(WV)等)接触，可能会暴露和/或预测非相对论量子束散射的新可观察效应，例如，含氢样品的质子中子散射的动量转移赤字和强度赤字。提出了一种新的wv理论处理方法，从基本原理和平等的基础上解释了这两种“赤字效应”。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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