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Werner Heisenberg considered the limits of how accurately one can measure properties of an electron or other microscopic particles. He determined that there is a fundamental limit to how accurately one can measure both a particle’s position and its momentum simultaneously. The more accurate the measurement of the momentum of a particle is known, the less accurate the position at that time is known and vice versa. This is what is now called the Heisenberg uncertainty principle. He...
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In the macroscopic world, objects that are large enough to be seen by the naked eye follow the rules of classical physics. A billiard ball moving on a table will behave like a particle; it will continue traveling in a straight line unless it collides with another ball, or it is acted on by some other force, such as friction. The ball has a well-defined position and velocity or well-defined momentum, p = mv, which is defined by mass m and velocity v at any given moment. This is the typical...
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Shortly after de Broglie published his ideas that the electron in a hydrogen atom could be better thought of as being a circular standing wave instead of a particle moving in quantized circular orbits, Erwin Schrödinger extended de Broglie’s work by deriving what is now known as the Schrödinger equation. When Schrödinger applied his equation to hydrogen-like atoms, he was able to reproduce Bohr’s expression for the energy and, thus, the Rydberg formula governing hydrogen spectra.
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Atoms generally contain the same number of positively and negatively charged particles, protons, and electrons. Hence, they are electrically neutral. However, the centers of the positive and negative charges do not always coincide. In such a scenario, the electric field of an atom may not be zero.
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When magnetic nuclei in a sample achieve resonance and undergo relaxation, the signal detected in NMR is an approximately exponential free induction decay. Fourier transform of an exponential decay yields a Lorentzian peak in the frequency domain. Lorentzian peaks in an NMR spectrum are defined by their amplitude, full width at half maximum, and position, where the peak width is governed by the spin-spin relaxation time alone. In real experiments, however, the applied magnetic field is rendered...
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Measurement of Quantum Interference in a Silicon Ring Resonator Photon Source
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量子测量和通过零范围潜力分散的延迟.

Xabier Gutiérrez1,2, Marisa Pons2,3, Dmitri Sokolovski2,4

  • 1Departamento de Química-Física, Universidad del País Vasco, UPV/EHU, 48940 Leioa, Spain.

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概括
此摘要是机器生成的。

艾森布德-维格纳-史密斯延迟和拉莫尔时间提供了不同的量子散射持续时间. 量子测量理论澄清了哪种方法可以准确地测量具有散射潜力的粒子相互作用时间,特别是对于大的德布罗格利波长.

关键词:
艾森·布德·维格纳·史密斯延迟了时间.拉尔莫尔时钟的时间量子测量是一种量子测量.潜在的零范围潜力.

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科学领域:

  • 量子力学就是量子力学.
  • 散射理论是一种散射理论.
  • 量子测量是一种量子测量.

背景情况:

  • 在估计量子散射事件持续时间时,Eisenbud-Wigner-Smith延迟和Larmor时间之间存在差异.
  • 这些差异在de Broglie波长相对于散射器的大小较大时尤为显著.

研究的目的:

  • 用量子测量理论分析艾森布德-维格纳-史密斯延迟和拉莫尔时间.
  • 为了确定哪种方法可以准确量化粒子在分散潜力区域内的持续时间.

主要方法:

  • 量子测量理论的应用.
  • 散射事件的分析,包括传输,反射和三维弹性散射.

主要成果:

  • 该研究提供了一个理论框架,以区分两个时间延迟估计.
  • 确定每个估计更合适的条件.

结论:

  • 量子测量理论为理解散射事件中的粒子相互作用时间提供了明确的方法.
  • 这些发现澄清了量子散射中的时间延迟的物理解释,特别是在大deBroglie波长极限中.