VI. A determination of “v,” the ratio of the electromagnetic unit of electricity to the electrostatic unit

J. Thomson, G. Searle
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Abstract

The experiments made by one of us in 1883 having given a value of " v " considerably smaller than the one found by several recent researches, it was thought desirable to repeat those experiments. The method used in 1883 was to find the electrostatic and electromagnetic measures of the capacity of a condenser; the electrostatic measure being calculated from the dimensions of the condenser, the electromagnetic measure determined by finding the resistance which would produce the same effect as that produced by the repeated charging of the condenser placed in one arm of a Wheat-stone’s Bridge. In the experiments of 1883 the condenser used in determining the electromagnetic measure of the capacity was not the same as the one for which the electrostatic measure had been calculated, but an auxiliary one, without a guard ring, the equality of the capacity of this condenser and that of the guard ring condenser being tested by the method given in Maxwell’s ‘Electricity and Magnetism,’ vol. 1, p. 324. In repeating the experiment we adopted at first the method used before, using, however, a key of different design for testing the equality of the capacity of the two condensers by Maxwell’s method. We got very consistent results, practically identical with the previous ones. We may mention here, since it has been suggested that the capacity of the leads might account for the small values of " v " obtained, that this capacity is allowed for by the way the comparison between the capacities of the auxiliary and guard ring condensers is made, for the same leads are used both in this comparison and in the determination of the electromagnetic measure of the capacity of the auxiliary condenser; the capacity of the auxiliary condenser, plus that of its leads, is made equal to the capacity of the guard ring condenser, and it is the capacity of the auxiliary condenser, plus its leads, which is determined in electromagnetic measure. As the introduction of the auxiliary condenser introduced increased possi­bilities of error, we endeavoured to determine directly the electromagnetic measure of the capacity of the guard ring condenser, by using a complicated commutator which worked both the guard ring and the condenser. At first we tried one where the contacts were made by platinum styles attached to a tuning fork, but as the results were not so regular as we desired, we replaced the tuning fork commutator by a rotating one driven by a water motor. A stroboscopic arrangement was fixed to this commu­tator so that its speed might be kept regular and measured. With this arrangement, which worked perfectly, we got values for the electromagnetic measure of the capacity of the condenser distinctly less than those obtained by the old method. We then endeavoured to find out the cause of this difference, and after a good deal of trouble discovered that in the experiments by which the equality of the capacities of the guard ring and auxiliary condensers was tested by Maxwell’s method, the guard ring did not produce its full effect. When the guard ring of the standard condenser was taken off, and its capacity made equal by Maxwell’s method to the capacity of the auxiliary condenser, the two methods gave identical results; but the effect of adding the guard ring was less in the old method than in the new. We found also, by calculation, that the effect produced by the guard ring in the old method was distinctly too small, while that determined by the new method agreed well with its calculated value. As the new method was working perfectly satisfactorily, and as it possesses great advantages over the old one, inasmuch as we get rid entirely of the auxiliary condenser, and can also alter the speed of the rotating commutator with very much greater ease and considerably greater accuracy than in any arrangement where the speed is governed by a tuning fork, we discarded the old method and adopted the new one which we now proceed to describe, beginning by considering the errors to which this method is liable.
确定“v”,即电的电磁单位与静电单位之比
我们中的一个人在1883年所做的实验得出的v值比最近几项研究得出的值要小得多,因此我们认为有必要重复这些实验。1883年使用的方法是找出电容器容量的静电和电磁测量;静电测量是根据电容器的尺寸来计算的,电磁测量是通过找出电阻来确定的,该电阻与放置在麦斯通桥的一只臂上的电容器反复充电所产生的效果相同。在1883年的实验中,用来测定电磁容量的电容器和用来计算静电容量的电容器不是同一种,而是一种没有保护环的辅助电容器,用麦克斯韦的《电与磁》第1卷第324页中给出的方法来检验这种电容器和保护环电容器的容量相等。在重复实验中,我们首先采用了以前使用的方法,然而,使用了不同设计的钥匙,用麦克斯韦方法测试两个冷凝器的容量相等。我们得到了非常一致的结果,与之前的结果几乎相同。由于有人建议引线的容量可以解释所获得的小v值,我们可以在这里提到,这种容量是通过对辅助电容器和保护环电容器的容量进行比较的方式允许的,因为在这种比较中和在确定辅助电容器容量的电磁测量中使用相同的引线;使辅助电容器的容量加上其引线的容量等于保护环电容器的容量,即辅助电容器的容量加上其引线的容量,这是在电磁测量中确定的。由于辅助电容器的引入增加了误差的可能性,我们试图通过使用一个既保护环又工作电容器的复杂换向器来直接确定保护环电容器容量的电磁测量。起初,我们尝试了一种连接音叉的铂金风格的触点,但由于结果不像我们期望的那样规律,我们用一个由水马达驱动的旋转换向器代替了音叉换向器。在这个换向器上固定了频闪装置,使其速度可以保持规律和可测量。这种安排工作得很好,我们得到的电容电磁测量值明显小于用旧方法得到的值。然后,我们努力找出这种差异的原因,经过大量的麻烦,发现在用麦克斯韦的方法测试保护环和辅助冷凝器的容量相等的实验中,保护环没有产生它的全部效果。当取下标准冷凝器的保护环,用麦克斯韦法使其容量与辅助冷凝器的容量相等时,两种方法得到相同的结果;但增加保护环的效果在旧方法中比在新方法中要小。通过计算还发现,旧方法中保护环产生的效果明显太小,而新方法所确定的效果与计算值吻合得很好。由于新方法工作得非常令人满意,而且它比旧方法有很大的优势,因为我们完全摆脱了辅助电容器,并且可以比任何由音叉控制速度的安排更容易和更精确地改变旋转换向器的速度,我们抛弃了旧方法,采用了我们现在继续描述的新方法。首先考虑这种方法容易产生的错误。
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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