发现者和方法论者

IF 0.7 3区 哲学 Q2 HISTORY & PHILOSOPHY OF SCIENCE
George Borg
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引用次数: 0

摘要

二十世纪中叶,地球化学--地球科学的核心之一--经历了一场引人注目的变革,这得益于基于物理原理的电子仪器的问世。在这一过程中,质谱仪成为同位素地球化学的主要分析技术。这篇文章涉及同位素系统的发现及其相对丰度的变化与质谱分析法的发展之间的动态关系--一方面,这些发现成为同位素地质学的基础。明尼阿波利斯明尼苏达大学的物理学家和仪器制造者阿尔弗雷德-O.C.-尼尔(Alfred O.C. Nier)的职业生涯说明了这种关系。尼尔在 1940 年设计的 60o 扇面质谱仪赋予了该仪器强大的新功能,并促进了该仪器在核物理学界以外的应用。在开发和应用该仪器的过程中,尼尔还在同位素的相对丰度方面取得了重要发现,为过去深处的地球化学研究铺平了道路。我的论点是,尼耶的早期职业生涯跨越了 20 世纪 30 年代和 40 年代,体现了科学与技术协同发展的动态关系。这种研究模式超越了尼尔--他在 20 世纪 50 年代后基本上不再从事这项研究--发展成为一种研究传统,最初以芝加哥大学核研究所为基地,随后扩展到其他机构,特别是加州理工学院、华盛顿卡内基研究所、加州大学伯克利分校和圣地亚哥分校。这一传统对历史地质学做出了重要贡献,包括古气候学、太阳系历史和构造革命。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Discoverer and Methodologist
During the mid–twentieth century, geochemistry—one of the core Earth sciences—underwent a spectacular transformation as a result of the introduction of electronic instruments based on physical principles. In this process, mass spectrometry became the workhorse analytical technique in isotope geochemistry. This essay concerns the dynamic relationship between discoveries of isotope systems and the variations in their relative abundances, on the one hand—discoveries that became the foundation of isotope geology—and the development of mass spectrometry, on the other. This relationship is illustrated by the career of physicist and instrument-builder Alfred O.C. Nier, who was based at the University of Minnesota in Minneapolis. Nier’s 60o-sector mass spectrometer design of 1940 endowed the instrument with powerful new capabilities, as well as facilitated its adoption outside the nuclear physics community. In the course of developing and applying the instrument, Nier also made important discoveries, about the relative abundances of isotopes, that paved the way for geochemical research on the deep past. My thesis is that Nier’s early career, spanning the 1930s and 1940s, illustrates a dynamic relationship in which science and technology co-evolved synergistically. This pattern of research spread beyond Nier—who largely moved on from this research after the 1950s—to develop into a research tradition, initially based at the University of Chicago’s Institute for Nuclear Studies and then spreading to other institutions, notably Caltech, the Carnegie Institution of Washington, and the University of California at Berkeley and San Diego. This tradition made crucial contributions to historical geology, including paleoclimatology, solar system history, and the tectonics revolution.
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来源期刊
Historical Studies in the Natural Sciences
Historical Studies in the Natural Sciences 社会科学-科学史与科学哲学
CiteScore
1.00
自引率
0.00%
发文量
24
审稿时长
>12 weeks
期刊介绍: Explore the fascinating world of Historical Studies in the Natural Sciences, a journal that reveals the history of science as it has developed since the 18th century. HSNS offers in-depth articles on a wide range of scientific fields, their social and cultural histories and supporting institutions, including astronomy, geology, physics, genetics, natural history, chemistry, meteorology, and molecular biology. Widely regarded as a leading journal in the historiography of science and technology, HSNS increased its publication to five times per year in 2012 to expand its roster of pioneering articles and notable reviews by the most influential writers in the field.
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