Rotational wave velocity of protons

Science Advance Pub Date : 2023-03-06 DOI:10.59208/sa-2023-03-06-1

Melissa B. Blau

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Abstract

The angular momentum of particles is the result of rotational waves, which are believed not to rotate in a classical sense. Therefore, the rotational wave properties of protons or nucleons, which should be comparable to De Broglie matter waves, have never been attributed to a wavelength, frequency or energy, but solely to their spin, which is a quantized property and probably does not reflect the true angular momentum as the product of radius and rotational impulse of a particle. Using data that originates from the hadron accelerator CERN in Switzerland, the true, not quantized velocity of the rotational wave of protons could be, however, measured. Thereby, its frequency is 2072.18 Hz, hence, it is unexpectedly low. The spike in the polarizability curve of protons at Q^2 = 0.33 GeV^2, published currently in the journal Nature, together with the rotational wave frequency obtained from CERN data, provides reliable evidence that this might be an interference in terms of superposition of the particle wave of the scattered electrons with the rotational wave of the protons at the same energy level, doubling the expected curve value, which, since there are no other possible explanations, proves the determined rotating wave velocity of protons.

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质子的旋转波速

粒子的角动量是旋转波的结果，而旋转波在经典意义上被认为是不旋转的。因此，质子或核子的旋转波性质，本应与德布罗意物质波相媲美，却从未归因于波长、频率或能量，而仅仅归因于它们的自旋，这是一种量子化性质，可能不能反映粒子半径与旋转冲量乘积的真实角动量。然而，利用来自瑞士欧洲核子研究中心强子加速器的数据，可以测量质子旋转波的真实速度，而不是量子化的速度。因此，它的频率是2072.18 Hz，因此，它是出乎意料的低。目前发表在《自然》杂志上的Q^2 = 0.33 GeV^2处质子极化曲线的峰值，以及从CERN数据中获得的旋转波频率，提供了可靠的证据，表明这可能是散射电子的粒子波与相同能级的质子的旋转波叠加的干扰，使预期的曲线值增加了一倍，由于没有其他可能的解释，证明了确定的质子旋转波速。

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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Science Advance

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