The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity

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Standard

The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity. / Knolle, Johannes; Joas, Christian.

Boston Studies in the Philosophy and History of Science. Springer, 2014. s. 119-132 (Boston Studies in the Philosophy and History of Science, Bind 299).

Publikation: Bidrag til bog/antologi/rapportBidrag til bog/antologiForskningfagfællebedømt

Harvard

Knolle, J & Joas, C 2014, The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity. i Boston Studies in the Philosophy and History of Science. Springer, Boston Studies in the Philosophy and History of Science, bind 299, s. 119-132. https://doi.org/10.1007/978-94-007-7199-4_7

APA

Knolle, J., & Joas, C. (2014). The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity. I Boston Studies in the Philosophy and History of Science (s. 119-132). Springer. Boston Studies in the Philosophy and History of Science Bind 299 https://doi.org/10.1007/978-94-007-7199-4_7

Vancouver

Knolle J, Joas C. The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity. I Boston Studies in the Philosophy and History of Science. Springer. 2014. s. 119-132. (Boston Studies in the Philosophy and History of Science, Bind 299). https://doi.org/10.1007/978-94-007-7199-4_7

Author

Knolle, Johannes ; Joas, Christian. / The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity. Boston Studies in the Philosophy and History of Science. Springer, 2014. s. 119-132 (Boston Studies in the Philosophy and History of Science, Bind 299).

Bibtex

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title = "The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity",
abstract = "Superconductivity—the loss of resistance in various materials close to absolute zero temperature—was a hot topic after World War II. Advances in nuclear reactor technology led to the discovery of the isotope effect in 1950 (Maxwell 1950; Reynolds et al. 1950), which brought about crucial insights about the role of electron-lattice interactions in superconductors that ultimately led to the formulation of a microscopic theory of this phenomenon. Generations of physicists had been struggling to find an explanation of superconductivity ever since its discovery in 1911 by Heike Kamerlingh Onnes.",
keywords = "Absolute Zero Temperature, Eliashberg Equation, Hughes Aircraft, Nonlinear Integral Equation, Quantitative Theory",
author = "Johannes Knolle and Christian Joas",
year = "2014",
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language = "English",
series = "Boston Studies in the Philosophy and History of Science",
publisher = "Springer",
pages = "119--132",
booktitle = "Boston Studies in the Philosophy and History of Science",
address = "Switzerland",

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RIS

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T1 - The Physics of Cold in the Cold War—“On-Line Computing” Between the ICBM Program and Superconductivity

AU - Knolle, Johannes

AU - Joas, Christian

PY - 2014

Y1 - 2014

N2 - Superconductivity—the loss of resistance in various materials close to absolute zero temperature—was a hot topic after World War II. Advances in nuclear reactor technology led to the discovery of the isotope effect in 1950 (Maxwell 1950; Reynolds et al. 1950), which brought about crucial insights about the role of electron-lattice interactions in superconductors that ultimately led to the formulation of a microscopic theory of this phenomenon. Generations of physicists had been struggling to find an explanation of superconductivity ever since its discovery in 1911 by Heike Kamerlingh Onnes.

AB - Superconductivity—the loss of resistance in various materials close to absolute zero temperature—was a hot topic after World War II. Advances in nuclear reactor technology led to the discovery of the isotope effect in 1950 (Maxwell 1950; Reynolds et al. 1950), which brought about crucial insights about the role of electron-lattice interactions in superconductors that ultimately led to the formulation of a microscopic theory of this phenomenon. Generations of physicists had been struggling to find an explanation of superconductivity ever since its discovery in 1911 by Heike Kamerlingh Onnes.

KW - Absolute Zero Temperature

KW - Eliashberg Equation

KW - Hughes Aircraft

KW - Nonlinear Integral Equation

KW - Quantitative Theory

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DO - 10.1007/978-94-007-7199-4_7

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AN - SCOPUS:85101959988

T3 - Boston Studies in the Philosophy and History of Science

SP - 119

EP - 132

BT - Boston Studies in the Philosophy and History of Science

PB - Springer

ER -

ID: 259042124