The e/m experiment: Student exploration into systematic uncertainty

IF 0.8 4区教育学 Q3 EDUCATION, SCIENTIFIC DISCIPLINES

American Journal of Physics Pub Date : 2024-07-01 DOI:10.1119/5.0190546

Nicholas P. Gray, Tanisha K. Rutledge, Leigh Parrott, Christopher A. Barns, K. Aptowicz

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引用次数: 0

Abstract

In this work, we convert a common verification lab in the physics curriculum, measuring the charge-to-mass ratio of the electron (e/m), into an investigative lab on systematic uncertainty. The Bainbridge apparatus, commonly used to measure e/m, can have significant systematic uncertainties, leading to large discrepancies with the accepted value. Students were asked to quantify possible systematic uncertainties in the apparatus and correct them. Building upon each other's work from semester to semester, students characterized multiple sources of systematic uncertainty. Not only did the students learn about uncertainty analysis techniques that reveal systematic uncertainties, but they also dramatically improved the accuracy of the apparatus, reducing the discrepancy from 15% to 0.5%. This paper describes a pedagogical approach to exploring unknown systematic uncertainties in an intermediate laboratory setting and the student-learning benefits of such an approach. In addition, it provides detailed information about untangling and correcting the sources of systematic uncertainty in the Bainbridge apparatus.

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e/m 实验：学生对系统不确定性的探索

在这项工作中，我们将物理课程中一个常见的验证性实验--测量电子的电荷质量比（e/m）--转换成了一个关于系统不确定性的探究性实验。常用于测量 e/m 的班布里奇仪器可能存在显著的系统不确定性，从而导致与公认值之间的巨大差异。学生们被要求量化仪器中可能存在的系统不确定性，并对其进行修正。在各学期相互学习的基础上，学生们确定了系统不确定性的多种来源。学生们不仅学到了揭示系统不确定性的不确定性分析技术，还极大地提高了仪器的精确度，将偏差从 15% 降低到 0.5%。本文介绍了在中级实验室环境中探索未知系统不确定性的教学方法，以及这种方法对学生学习的益处。此外，它还提供了有关解开和纠正班布里奇仪器中系统不确定性来源的详细信息。

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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来源期刊

American Journal of Physics 物理-物理：综合

CiteScore

1.80

自引率

11.10%

发文量

146

审稿时长

3 months

期刊介绍： The mission of the American Journal of Physics (AJP) is to publish articles on the educational and cultural aspects of physics that are useful, interesting, and accessible to a diverse audience of physics students, educators, and researchers. Our audience generally reads outside their specialties to broaden their understanding of physics and to expand and enhance their pedagogical toolkits at the undergraduate and graduate levels.