开放源代码未来的物理化学教育与研究

IF 3.7 Q2 CHEMISTRY, PHYSICAL
Jeffrey T. DuBose, Soren. B Scott, Benjamin Moss
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引用次数: 0

摘要

熟练掌握物理化学需要广泛的技能。成功的受训人员通常会得到资深同事(研究顾问、博士后等)的指导。导师会向学员介绍实验设计、仪器设置和复杂的数据解释。在实验室环境中,受训人员通常通过定制实验装置和开发新的数据分析方法来学习。与专家一起学习可以强化这些基础知识,并将重点放在清晰地交流研究问题上。然而,这种投入水平无法扩展,也不容易与所有研究人员或学生共享,特别是那些在获得指导方面面临社会经济障碍的人。因此,新的培训方法将推动物理化学领域的发展。技术正在颠覆科学教育和研究,并使之民主化。免费在线课程和视频资源的出现使学生能够以适合自己的方式学习。更高的自动化程度消除了学习新技术的繁琐、有时甚至是武断的技术障碍,使人们能够快速收集高质量的数据。数据和分析工具的开源提高了透明度,降低了使用门槛,加快了科学传播。然而,这些进步也可能导致以 "黑箱 "方式获取和分析数据,在这种情况下,方便取代了理解,错误和误导变得更加普遍。其风险在于教育的崩溃:如果一个人不了解某种技术或分析的基本原理,就很难正确辨别实验的实际限制、区分信号与噪声、排除故障或充分利用强大的分析程序。我们对物理化学未来的愿景是建立在民主化学习的基础上,即免费提供物理化学家的深厚技术和分析专业知识。通过专家生成的教育资源和基于人工智能的工具推进技术教育,将丰富物理化学教育。全面的教育方法将为 2050 年的物理化学家做好准备,以适应快速发展的技术工具,加快研究步伐。技术教育将通过可访问的开源仪器和分析程序得到加强,这些仪器和分析程序将提供专为教育设计的仪器和分析脚本。来自标准化开源仪器的高质量可比数据将输入可访问的数据库和分析项目,为其他人提供存储和分析失败和成功实验的机会。开源教育、硬件和分析的结合将使物理化学民主化,同时解决与 "黑箱 "方法相关的风险。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Physical Chemistry Education and Research in an Open-Sourced Future

Physical Chemistry Education and Research in an Open-Sourced Future
Proficiency in physical chemistry requires a broad skill set. Successful trainees often receive mentoring from senior colleagues (research advisors, postdocs, etc.). Mentoring introduces trainees to experimental design, instrumental setup, and complex data interpretation. In lab settings, trainees typically learn by customizing experimental setups, and developing new ways of analyzing data. Learning alongside experts strengthens these fundamentals, and places a focus on the clear communication of research problems. However, this level of input is not scalable, nor can it easily be shared with all researchers or students, particularly those that face socioeconomic barriers to accessing mentoring. New approaches to training will therefore progress the field of physical chemistry. Technology is disrupting and democratising scientific education and research. The emergence of free online courses and video resources enables students to learn in a style that suits them. Higher degrees of automation remove cumbersome and sometimes arbitrary technical barriers to learning new techniques, allowing one to collect high quality data quickly. Open sourcing of data and analysis tools has increased transparency, lowered barriers to access, and accelerated scientific dissemination. However, these advances also can lead to “black box” approaches to acquiring and analyzing data, where convenience replaces understanding and errors and misrepresentations become more common. The risk is a breakdown in education: if one does not understand the fundamentals of a technique or analysis, it is difficult to correctly discern the practical limits of an experiment, distinguish signal from noise, troubleshoot problems, or take full advantage of powerful analytical procedures. Our vision of the future of physical chemistry is built around democratized learning, where deep technical and analytical expertise from physical chemists is made freely available. Advancements in technical education through expert-generated educational resources and AI-based tools will enrich physical chemistry education. A holistic approach to education will prepare the physical chemists of 2050 to adapt to rapidly advancing technological tools, which accelerate the pace of research. Technical education will be enhanced by accessible open-source instrumentation and analysis procedures, which will provide instruments and analysis scripts specifically designed for education. High quality, comparable data from standardized open-source instruments will feed into accessible databases and analysis projects, providing others the opportunity to store and analyze both failed and successful experiments. The coupling of open-source education, hardware, and analysis will democratize physical chemistry while addressing risks associated with “black box” approaches.
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来源期刊
CiteScore
3.70
自引率
0.00%
发文量
0
期刊介绍: ACS Physical Chemistry Au is an open access journal which publishes original fundamental and applied research on all aspects of physical chemistry. The journal publishes new and original experimental computational and theoretical research of interest to physical chemists biophysical chemists chemical physicists physicists material scientists and engineers. An essential criterion for acceptance is that the manuscript provides new physical insight or develops new tools and methods of general interest. Some major topical areas include:Molecules Clusters and Aerosols; Biophysics Biomaterials Liquids and Soft Matter; Energy Materials and Catalysis
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