Superconducting Niobium-Titanium: Enabler for Affordable MRI and the Search for the Higgs Boson

IF 0.1 3区哲学 Q4 HISTORY & PHILOSOPHY OF SCIENCE

Physics in Perspective Pub Date : 2015-12-14 DOI:10.1007/s00016-015-0172-x

T. G. Berlincourt

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引用次数: 2

Abstract

In 1961, Bell Telephone Laboratories researchers startled the world of physics by reporting that, at temperatures near absolute zero, a superconducting niobium-tin compound could support enormous electric current densities without resistance in the presence of very high magnetic fields. Suddenly, it became possible to fabricate supermagnets that generate high magnetic fields with unprecedented efficiency and economy. Scientists raced to find additional such materials and also to account theoretically for their behavior. Disregarded early on as unpromising, niobium-titanium alloys eventually emerged from among thousands of superconductors to become the most widely used, finding application in many thousands of MRI medical imaging systems and in huge particle accelerator magnets. In 1962, at Atomics International, experiments that revealed the supermagnet promise of niobium-titanium alloys also made essential contributions to the confirmation of the initially overlooked superconductivity theories of Soviet scientists Ginzburg, Landau, Abrikosov, and Gor'kov as the appropriate framework for understanding the physics of high magnetic field superconductivity.

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超导铌钛:可负担的核磁共振成像和寻找希格斯玻色子的推动者

1961年，贝尔电话实验室的研究人员震惊了物理界，他们报告说，在接近绝对零度的温度下，一种超导铌锡化合物可以在非常高的磁场存在下支持巨大的电流密度而没有电阻。突然之间，以前所未有的效率和经济制造产生高磁场的超级磁铁成为可能。科学家们竞相寻找更多这样的材料，并从理论上解释它们的行为。早期被认为前途渺茫的铌钛合金最终从成千上万的超导体中脱颖而出，成为应用最广泛的材料，在成千上万的核磁共振医学成像系统和巨大的粒子加速器磁体中得到了应用。1962年，在国际原子学会(Atomics International)上，揭示铌钛合金超级磁铁前景的实验，也为证实最初被忽视的苏联科学家金兹堡(Ginzburg)、朗道(Landau)、阿布里科索夫(Abrikosov)和戈科夫(Gor’kov)的超导理论做出了重要贡献，这些理论是理解高磁场超导物理学的适当框架。

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

Physics in Perspective 物理-科学史与科学哲学

CiteScore

0.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Physics in Perspective seeks to bridge the gulf between physicists and non-physicists through historical and philosophical studies that typically display the unpredictable as well as the cross-disciplinary interplay of observation, experiment, and theory that has occurred over extended periods of time in academic, governmental, and industrial settings and in allied disciplines such as astrophysics, chemical physics, and geophysics. The journal also publishes first-person accounts by physicists of significant contributions they have made, biographical articles, book reviews, and guided tours of historical sites in cities throughout the world. It strives to make all articles understandable to a broad spectrum of readers – scientists, teachers, students, and the public at large. Bibliographic Data Phys. Perspect. 1 volume per year, 4 issues per volume approx. 500 pages per volume Format: 15.5 x 23.5cm ISSN 1422-6944 (print) ISSN 1422-6960 (electronic)