Determining the Charge-to-Mass Ratio of the Electron

Joaquim Bocresion
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Abstract

The aim of this lab was to determine an experimental value for the charge-to-mass ratio e/me of the electron. In order to do this, an assembly consisting of Helmholtz coils and a helium-filled fine beam tube containing an electron gun was used. Electrons were accelerated from rest by the electron gun at a voltage of 201.3 V kept constant across trials. When the accelerated electrons collided with the helium atoms in the fine beam tube, the helium atoms entered an excited state and released energy as light. Since the Helmholtz coils put the electrons into centripetal motion, this resulted in a circular beam of light, the radius of which was measured by taking a picture and using photo analysis. This procedure was used to test currents through the Helmholtz coils ranging from 1.3 A to 1.7 A in increments of 0.1 A. Using a linearization of these data, the experimental value for the charge-to-mass ratio of the electron was found to be 1.850 × 1011 C/kg, bounded between 1.440 × 1011 C/kg and 2.465 × 1011 C/kg. This range of values includes the accepted value of 1.759 × 1011 C/kg, and yields a percent error of 5.17%. The rather low percent error is a testament to the accuracy of this procedure. During this experiment, the orientation of the ambient magnetic field due to the Earth at the center of the apparatus was not considered. In the future, it would be worthwhile to repeat this procedure, taking care to position the Helmholtz coils in such a way to negate the effects of the Earth’s magnetic field on the centripetal motion of electrons.
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确定电子的电荷质量比
本实验的目的是确定电子的电荷质量比e/me的实验值。为了做到这一点,使用了由亥姆霍兹线圈和含有电子枪的充氦细束管组成的组件。电子被电子枪以201.3 V的电压从静止状态加速,在试验期间保持恒定。当加速的电子与细电子管中的氦原子碰撞时,氦原子进入激发态并以光的形式释放能量。由于亥姆霍兹线圈使电子向心运动,这就产生了一束圆形光束,其半径可以通过拍照和照片分析来测量。该程序用于测试通过亥姆霍兹线圈的电流,范围从1.3 A到1.7 A,增量为0.1 A。对这些数据进行线性化处理,得到电子电荷质量比的实验值为1.850 × 1011 C/kg,介于1.440 × 1011 C/kg和2.465 × 1011 C/kg之间。该范围的值包括可接受值1.759 × 1011 C/kg,产生5.17%的百分比误差。相当低的错误率证明了这一程序的准确性。在这个实验中,由于地球在仪器中心的环境磁场的方向没有被考虑。将来,重复这一过程是值得的,要注意将亥姆霍兹线圈放置在这样一种方式上,以抵消地球磁场对电子向心运动的影响。
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