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wiki:demag_papers [2022/11/11 23:17] henri.godfrin@neel.cnrs.fr [Nuclear Cooling] |
wiki:demag_papers [2022/12/15 13:56] (current) henri.godfrin@neel.cnrs.fr |
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====== Articles on Nuclear Demagnetization ====== | ====== Articles on Nuclear Demagnetization ====== | ||
- | ==== Nuclear Cooling ==== | ||
* Nuclear Cooling, N. Kurti, F. N. H. Robinson, F. Simon, D. A. Spohr, Nature 178 (1956) 450, [[https:// | * Nuclear Cooling, N. Kurti, F. N. H. Robinson, F. Simon, D. A. Spohr, Nature 178 (1956) 450, [[https:// | ||
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* Cooling of 3He to 1 mK by nuclear demagnetization of PrNi5, K.Andres, S.Darack, Physica B+C 86–88 (1977) 1071-1076, [[https:// | * Cooling of 3He to 1 mK by nuclear demagnetization of PrNi5, K.Andres, S.Darack, Physica B+C 86–88 (1977) 1071-1076, [[https:// | ||
+ | * Nuclear Demagnetization of PrS and PrNi5, C. Buchal, K. J. Fischer, M. Kubota, R. M. Mueller, F. Pobell, Journal de Physique Lettres 39 (1978) L457-L458, [[https:// | ||
- | * Nuclear Demagnetization of PrS and PrNi5, C. Buchal, K. J. Fischer, M. Kubota, R. M. Mueller, F. Pobell, Journal de Physique Lettres 39 (1978) L457-L458, [[https:// | ||
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* Two Stage Nuclear Demagnetization Experiments, | * Two Stage Nuclear Demagnetization Experiments, | ||
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* Direct demagnetization cooling of high-density solid 3He, T. Okamoto, H. Fukuyama, H. Akimoto, H. Ishimoto, S. Ogawa, Physical Review Letters 72 (1994) 868-871, [[https:// | * Direct demagnetization cooling of high-density solid 3He, T. Okamoto, H. Fukuyama, H. Akimoto, H. Ishimoto, S. Ogawa, Physical Review Letters 72 (1994) 868-871, [[https:// | ||
- | * A compact copper nuclear demagnetization refrigerator, | + | * A compact copper nuclear demagnetization refrigerator, |
* Nuclear demagnetization refrigerator with automatic control, pick up and data process system, A. A. Golub, V. A. Goncharov, V. R. Litvinov, V. A. Mikheev, E. Y. Rudavskii, Y. A. Tokar, A. M. Usenko, V. A. Shvarts, Fizika Nizkih Temperatur 21 (1995) 974-982 | * Nuclear demagnetization refrigerator with automatic control, pick up and data process system, A. A. Golub, V. A. Goncharov, V. R. Litvinov, V. A. Mikheev, E. Y. Rudavskii, Y. A. Tokar, A. M. Usenko, V. A. Shvarts, Fizika Nizkih Temperatur 21 (1995) 974-982 | ||
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* The new grenoble 100 μK refrigerator, | * The new grenoble 100 μK refrigerator, | ||
- | * Thermodynamic description of nuclear demagnetization experiments, | + | * Thermodynamic description of nuclear demagnetization experiments, |
- | * Košice nuclear demagnetization refrigerator, | + | * Košice nuclear demagnetization refrigerator, |
- | * Nuclear magnetic properties of aluminium, W. Wendler, P. Smeibidl, F. Pobell, Journal of Low Temperature Physics 108 (1997) 291–304, https:// | + | * Nuclear magnetic properties of aluminium, W. Wendler, P. Smeibidl, F. Pobell, Journal of Low Temperature Physics 108 (1997) 291–304, |
- | * Simple Nuclear Demagnetization Stage, V. V. Dmitriev, I. V. Kosarev, D. V. Ponarin, R. Scheibel, Journal of Low Temperature Physics 113 (1998) 945–949, https:// | + | * Simple Nuclear Demagnetization Stage, V. V. Dmitriev, I. V. Kosarev, D. V. Ponarin, R. Scheibel, Journal of Low Temperature Physics 113 (1998) 945–949, |
- | * Nuclear cooling and spin properties of rhodium down to picokelvin temperatures, | + | * Nuclear cooling and spin properties of rhodium down to picokelvin temperatures, |
- | * A Versatile Nuclear Demagnetization Cryostat for Ultralow Temperature Research, W. Yao, T. A. Knuuttila, K. K. Nummila, J. E. Martikainen, | + | * A Versatile Nuclear Demagnetization Cryostat for Ultralow Temperature Research, W. Yao, T. A. Knuuttila, K. K. Nummila, J. E. Martikainen, |
- | * Cryostat for optical observations below 1 mK and in strong magnetic fields, R. van Rooijen, A. Marchenkov, H. Akimoto, O. Andreeva, P.van de Haar, R. Jochemsen, G. Frossati, Journal of Low Temperature Physics 124 (2001) 497-511, https:// | + | * Cryostat for optical observations below 1 mK and in strong magnetic fields, R. van Rooijen, A. Marchenkov, H. Akimoto, O. Andreeva, P.van de Haar, R. Jochemsen, G. Frossati, Journal of Low Temperature Physics 124 (2001) 497-511, |
- | * Nuclear orientation and nuclear cooling experiments in Oxford and Helsinki, part 1, Progress before 1940, B. Bleaney, O. V. Lounasmaa, | + | * Nuclear orientation and nuclear cooling experiments in Oxford and Helsinki, part 1, Progress before 1940, B. Bleaney, O. V. Lounasmaa, |
- | * Nuclear orientation and nuclear cooling experiements in Oxford and Helsinki Part 2. Progress from 1945 to 1970, B. Bleaney, O. V. Lounasmaa, Notes and Records: the Royal Society Journal of the History of Science 57 (2003), 323-330, https:// | + | * Nuclear orientation and nuclear cooling experiements in Oxford and Helsinki Part 2. Progress from 1945 to 1970, B. Bleaney, O. V. Lounasmaa, Notes and Records: the Royal Society Journal of the History of Science 57 (2003), 323-330, |
- | * Study of heat leaks to copper nuclear demagnetization stage, H. Nakagawa, H. Yano, O. Ishikawa, T. Hata, Physica B: Condensed Matter 329–333 (2003) 1606-1607, https:// | + | * Study of heat leaks to copper nuclear demagnetization stage, H. Nakagawa, H. Yano, O. Ishikawa, T. Hata, Physica B: Condensed Matter 329–333 (2003) 1606-1607, |
- | * Direct Nuclear Demagnetization of Two Dimensional Solid 3He Adsorbed on Graphite, R. Masutomi, Y. Karaki, H. Ishimoto, Journal of Low Temperature Physics 134 (2004) 49–54, https:// | + | * Direct Nuclear Demagnetization of Two Dimensional Solid 3He Adsorbed on Graphite, R. Masutomi, Y. Karaki, H. Ishimoto, Journal of Low Temperature Physics 134 (2004) 49–54, |
* Construction of an ultra low temperature cryostat with an automated He-3 melting pressure thermometer, | * Construction of an ultra low temperature cryostat with an automated He-3 melting pressure thermometer, | ||
- | * Construction of a Nuclear Cooling Stage, P. Strehlow, H. Nuzha, E. Bork, Journal of Low Temperature Physics 147 (2007) 81-93, https:// | + | * Construction of a Nuclear Cooling Stage, P. Strehlow, H. Nuzha, E. Bork, Journal of Low Temperature Physics 147 (2007) 81-93, |
- | * Method for cooling nanostructures to microkelvin temperatures, | + | * Method for cooling nanostructures to microkelvin temperatures, |
- | * Setting up of a microKelvin refrigerator facility at TIFR, H. R. Naren, R. S. Sannabhadti, | + | * Setting up of a microKelvin refrigerator facility at TIFR, H. R. Naren, R. S. Sannabhadti, |
- | * The Vienna Nuclear Demagnetization Refrigerator, | + | * The Vienna Nuclear Demagnetization Refrigerator, |
- | * A microkelvin cryogen-free experimental platform with integrated noise thermometry, | + | * A microkelvin cryogen-free experimental platform with integrated noise thermometry, |
- | * Nuclear demagnetization for ultra-low temperatures, | + | * Nuclear demagnetization for ultra-low temperatures, |
- | * Dry demagnetization cryostat for sub-millikelvin helium experiments: | + | * Dry demagnetization cryostat for sub-millikelvin helium experiments: |
- | * On-chip magnetic cooling of a nanoelectronic device, D. I. Bradley, A. M. Guénault, D. Gunnarsson, R. P. Haley, S. Holt, A. T. Jones, Yu. A. Pashkin, J. Penttilä, J. R. Prance, M. Prunnila, L. Roschier, Scientific Reports 7 (2017) 45566, https:// | + | * On-chip magnetic cooling of a nanoelectronic device, D. I. Bradley, A. M. Guénault, D. Gunnarsson, R. P. Haley, S. Holt, A. T. Jones, Yu. A. Pashkin, J. Penttilä, J. R. Prance, M. Prunnila, L. Roschier, Scientific Reports 7 (2017) 45566, |
- | * Magnetic cooling for microkelvin nanoelectronics on a cryofree platform, M. Palma, D. Maradan, L. Casparis, T.-M. Liu, F. N. M. Froning, D. M. Zumbühl, Review of Scientific Instruments 88 (2017) 043902, https:// | + | * Magnetic cooling for microkelvin nanoelectronics on a cryofree platform, M. Palma, D. Maradan, L. Casparis, T.-M. Liu, F. N. M. Froning, D. M. Zumbühl, Review of Scientific Instruments 88 (2017) 043902, |
- | * Sub-millikelvin station at Synergetic Extreme Condition User Facility, Z. G. Cheng, J. Fan, X. Jing, L. Lu, Chinese Physics B 27 (2018) 070702, https:// | + | * Sub-millikelvin station at Synergetic Extreme Condition User Facility, Z. G. Cheng, J. Fan, X. Jing, L. Lu, Chinese Physics B 27 (2018) 070702, |
- | * Design and expected performance of a compact and continuous nuclear demagnetization refrigerator for sub-mK applications, | + | * Design and expected performance of a compact and continuous nuclear demagnetization refrigerator for sub-mK applications, |
- | * Development of a Sub-mK Continuous Nuclear Demagnetization Refrigerator, | + | * Development of a Sub-mK Continuous Nuclear Demagnetization Refrigerator, |
- | * Indium as a High-Cooling-Power Nuclear Refrigerant for Quantum Nanoelectronics, | + | * Indium as a High-Cooling-Power Nuclear Refrigerant for Quantum Nanoelectronics, |
- | * Progress in Cooling Nanoelectronic Devices to Ultra-Low Temperatures, | + | * Progress in Cooling Nanoelectronic Devices to Ultra-Low Temperatures, |
- | * Design evaluation of serial and parallel sub-mK continuous nuclear demagnetization refrigerators, | + | * Design evaluation of serial and parallel sub-mK continuous nuclear demagnetization refrigerators, |
- | * Cryogen-free one hundred microkelvin refrigerator, J. Yan, J. Yao, V. Shvarts, R.-R. Du, X. Lin, Review | + | * Progress in Cooling Nanoelectronic Devices to Ultra‑Low Temperatures, A. T. Jones, C. P. Scheller, J. R. Prance, Y. B. Kalyoncu, D. M. Zumbühl, R. P. Haley, Journal |
- | * Construction of Continuous Magnetic Cooling Apparatus with Zinc-Soldered PrNi5 Nuclear Stages, S. Takimoto, R. Toda, S. Murakawa, H. Fukuyama, Journal of Low Temperature Physics 208 (2022) 492–500, https:// | + | |
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