In 1904, the year before Einstein's seminal papers on special relativity, Austrian physicist Fritz Hasen?hrl examined the properties of blackbody radiation in a moving cavity. He calculated the work necessary to keep the cavity moving at a constant velocity as it fills with radiation and concluded that the radiation energy has associated with it an apparent mass such that E = 3/8 mc~2. In a subsequent paper, also in 1904, Hasen?hrl achieved the same result by computing the force necessary to accelerate a cavity already filled with radiation. In early 1905, he corrected the latter result to E = 3/4 mc~2. This result, i.e., m = 4/3 E/c~2, has led many to conclude that Hasen?hrl fell victim to the same "mistake" made by others who derived this relation between the mass and electrostatic energy of the electron. Some have attributed the mistake to the neglect of stress in the blackbody cavity. In this paper, Hasen?hrl's papers are examined from a modern, relativistic point of view in an attempt to understand where he went wrong. The primary mistake in his first paper was, ironically, that he didn't account for the loss of mass of the blackbody end caps as they radiate energy into the cavity. However, even taking this into account one concludes that blackbody radiation has a mass equivalent of m = 4/3 E/c~2 or m = 5/3 E/c~2 depending on whether one equates the momentum or kinetic energy of radiation to the momentum or kinetic energy of an equivalent mass. In his second and third papers that deal with an accelerated cavity, Hasen?hrl concluded that the mass associated with blackbody radiation is m = 4/3 E/c~2, a result which, within the restricted context of Hasen?hrl's gedanken experiment, is actually consistent with special relativity. (If one includes all components of the system, including cavity stresses, then the total mass and energy of the system are, to be sure, related by m = E/c~2.) Both of these problems are non-trivial and the surprising results, indeed, turn out to be relevant to the "4/3 problem" in classical models of the electron. An important lesson of these analyses is that E = m c~2, while extremely useful, is not a "law of physics" in the sense that it ought not be applied indiscriminately to any extended system and, in particular, to the subsystems from which they are comprised. We suspect that similar problems have plagued attempts to model the classical electron.
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机译:1904年,即爱因斯坦关于狭义相对论的开创性论文发表的前一年,奥地利物理学家弗里茨·哈森菲尔(Fritz Hasen?hrl)研究了运动腔中黑体辐射的特性。他计算了在空腔充满辐射时保持空腔以恒定速度运动所需的功,并得出结论,辐射能量与之相关的视在质量为E = 3/8 mc〜2。在随后的论文中(也是在1904年),哈森菲尔通过计算加速已经充满了辐射的空腔所需的力,获得了相同的结果。 1905年初,他将后者的结果校正为E = 3/4 mc〜2。这一结果,即m = 4/3 E / c〜2,使许多人得出结论,哈森菲尔成为了其他推导电子质量和静电能之间关系的“错误”的受害者。有些人将错误归因于忽略了黑体腔内的压力。在本文中,从现代,相对论的角度审视了哈森菲尔的论文,以试图了解他出了错的地方。具有讽刺意味的是,在他的第一篇论文中,主要的错误是他没有考虑黑体端盖在将能量辐射到腔中时质量损失的原因。但是,即使考虑到这一点,也可以得出这样的结论:黑体辐射的质量当量为m = 4/3 E / c〜2或m = 5/3 E / c〜2,具体取决于是否等于辐射的动量或动能等效质量的动量或动能Hasen?hrl在有关加速腔的第二和第三篇论文中得出结论,与黑体辐射有关的质量为m = 4/3 E / c〜2,这一结果在Hasen?hrl的gedanken实验的有限范围内,实际上与狭义相对论一致。 (如果一个包括系统的所有组成部分,包括空腔应力,那么系统的总质量和能量肯定与m = E / c〜2相关。)这两个问题都不是简单的,确实,令人惊讶的结果证明与经典电子模型中的“ 4/3问题”有关。这些分析的一个重要教训是,E = mc〜2虽然非常有用,但不是“物理定律”,因为它不应任意地应用于任何扩展系统,尤其是应用于从中扩展的子系统。他们组成。我们怀疑类似的问题困扰着对经典电子建模的尝试。
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