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Journal articles on the topic 'High temperature'

Author: Grafiati
Published: 4 June 2021
Last updated: 7 July 2024

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1

Uludag, Alper, and Dilek Turan. "SiAlON Ceramics for the High Temperature Applications: High Temperature Creep Behavior." International Journal of Materials, Mechanics and Manufacturing 3, no. 2 (2015): 105–9. http://dx.doi.org/10.7763/ijmmm.2015.v3.176.

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2

V.Seryotkin, Yurii, Werner Joswig, Vladimir V. Bakakin, Igor A. Belitsky, and Boris A. Fursenko. "High-temperature crystal structure of wairakite." European Journal of Mineralogy 15, no. 3 (June 10, 2003): 475–84. http://dx.doi.org/10.1127/0935-1221/2003/0015-0475.

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3

Leszczyński, Juliusz, Piotr Klimczyk, Krzysztof Wojciechowski, and Andrzej Koleżyński. "Studies on high pressure-high temperature synthesis of carbon clathrates." Mechanik, no. 5-6 (May 2016): 512–13. http://dx.doi.org/10.17814/mechanik.2016.5-6.62.

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4

Singh, Hempal, Anu Singh, Vinod Ashokan, and B. D. Indu B. D. Indu. "Signature of Anharmonicities in High Temperature Superconductors." Indian Journal of Applied Research 3, no. 4 (October 1, 2011): 35–38. http://dx.doi.org/10.15373/2249555x/apr2013/134.

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5

Dombal, Richard F. De, and Michael A. Carpenter. "High-temperature phase transitions in Steinbach tridymite." European Journal of Mineralogy 5, no. 4 (July 22, 1993): 607–22. http://dx.doi.org/10.1127/ejm/5/4/0607.

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6

Morris, D. G., and M. A. Muñoz-Morris. "High temperature mechanical properties of iron aluminides." Revista de Metalurgia 37, no. 2 (April 30, 2001): 230–39. http://dx.doi.org/10.3989/revmetalm.2001.v37.i2.471.

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7

Mikheenko, P. N. "Discrete temperatures in high-temperature superconductors." Physica C: Superconductivity 311, no. 1-2 (January 1999): 1–10. http://dx.doi.org/10.1016/s0921-4534(98)00620-0.

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8

Kim. "A Comparison of Residual Tensile Properties of GFRP Reinforcing Bar at High Temperature and after Exposure to High Temperature." Journal of the Korean Society of Civil Engineers 35, no. 1 (2015): 77. http://dx.doi.org/10.12652/ksce.2015.35.1.0077.

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9

Lansdown, A. R. "High-Temperature Lubrication." Proceedings of the Institution of Mechanical Engineers, Part C: Mechanical Engineering Science 204, no. 5 (September 1990): 279–91. http://dx.doi.org/10.1243/pime_proc_1990_204_109_02.

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The maximum temperature at which a mechanical system can operate is often determined by the need for lubrication. The paper considers the various heat sources, ambient temperature, mechanical or chemical inputs, and flash temperatures, and discusses their influence on different types of lubrication. The actual temperature limitations are imposed by physical or chemical changes in the lubricant itself, or by changes in a specific lubrication mechanism such as adsorption. The nature of these types of change is described, together with the dominant importance of residence time on the extent of deterioration. Some actual temperature limits for particular lubricants are listed, and the paper suggests some possible design techniques for extending the upper temperature limits for lubrication.
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10

Thiéblot, Laurent, Jacques Roux, and Pascal Richet. "High-temperature thermal expansion and decomposition of garnets." European Journal of Mineralogy 10, no. 1 (January 26, 1998): 7–16. http://dx.doi.org/10.1127/ejm/10/1/0007.

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11

Irwin, Patricia C., Daniel Qi Tan, Yang Cao, Norberto Silvi, Mark Carter, Mark Rumler, and Christophe Garet. "Development of High Temperature Capacitors for High Density, High Temperature Applications." SAE International Journal of Aerospace 1, no. 1 (November 11, 2008): 817–21. http://dx.doi.org/10.4271/2008-01-2851.

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12

Bridger, K., A. Cooke, D. Kohlhafer, R. Strite, W. Schulze, S. Arrasmith, J. Weigner, and F. Duva. "High-Temperature, High-Power Performance of Ceramic Filter Capacitors." Additional Conferences (Device Packaging, HiTEC, HiTEN, and CICMT) 2011, HITEN (January 1, 2011): 000027–29. http://dx.doi.org/10.4071/hiten-paper5-kbridger.

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Power conversion electronics in military vehicles and aircraft are currently experiencing high temperatures and future generations will see these temperatures rise even higher. The high temperatures arise not only from the environment but also from high power dissipation in the components themselves. Capacitors can occupy almost 50% of the real estate in some power converters and these capacitors are subjected to very high currents at high frequencies in dc-dc converters or 60-Hz 120 VAC in the output stage of an inverter. Dissipation resulting from the high power levels can lead to internal capacitor temperatures at least 50°C above their ambient and so for military hybrid electric vehicles (HEVs) capacitors are expected to reach at least 150°C and possibly 200°C, while future aircraft component temperatures are expected to exceed 250°C. A new family of high-temperature dielectrics based on sodium bismuth titanate has been developed by these authors and capacitors are now available from Novacap under the trade name “Type H” or “Type HA”. This paper examines the high-frequency, high-current and 60-Hz, 120-VAC performance of these capacitors including an estimate of internal heating. The primary operating temperature range studied is −40 to +150°C, although some higher temperature data are also presented.
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13

Molander, Paal, Espen Ommundsen, and Tyge Greibrokk. "High temperature injection in capillary high temperature liquid chromatography." Journal of Microcolumn Separations 11, no. 8 (1999): 612–19. http://dx.doi.org/10.1002/(sici)1520-667x(1999)11:8<612::aid-mcs7>3.0.co;2-6.

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14

Sedlmajer, Martin, Jiri Zach, Jitka Peterková, and Lenka Bodnárová. "Temperature Control in High Performance Concrete." Advanced Materials Research 1100 (April 2015): 162–65. http://dx.doi.org/10.4028/www.scientific.net/amr.1100.162.

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The paper addresses the methodology of temperature observation of cement composites, such as concrete. It is mainly the monitoring of the course of hydration temperature and the possibilities of its regulation. Subsequently, the observation of temperature within samples which are exposed to high temperatures. Attention is paid to a variety of temperatures of a concrete segment which is being acted upon by a high-temperature source, e.g. fire. Temperature distribution at a varied distance from the heat source is observed.
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15

Savvova, Oksana, Hennadii Voronov, Oleksii Fesenko, Sviatoslav Riabinin, and Vadym Tymofieiev. "High-Strength Glass-Ceramic Material with Low Temperature Formation." Chemistry & Chemical Technology 16, no. 2 (June 15, 2022): 337–44. http://dx.doi.org/10.23939/chcht16.02.337.

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Prospects for development of glass-ceramic materials on the lithium aluminosilicates base in order to increase the reliability of armor protection elements have been analyzed. Compositions of lithium aluminosilicate glasses with low content of lithium oxide have been developed, spodumene glass-ceramic materials were obtained on their base in conditions of low-temperature thermal treatment. Formation of structure of glass-ceramic materials based on model glasses after thermal treatment has been investigated and the influence of phase composition on mechanical properties has been established. It was determined that the developed glass-ceramic materials are feasible for the application against the action of high-energy munitions with significant penetrating ability, especially when used in combination with ceramic elements.
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16

Lashkarev, G. V. "Diluted magnetic layered semiconductor InSe:Mn with high Curie temperature." Semiconductor Physics Quantum Electronics and Optoelectronics 14, no. 3 (September 25, 2011): 263–68. http://dx.doi.org/10.15407/spqeo14.03.263.

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17

Bayarjargal, Lkhamsuren, Tatyana G. Shumilova, Alexandra Friedrich, and Björn Winkler. "Diamond formation from CaCO3 at high pressure and temperature." European Journal of Mineralogy 22, no. 1 (March 18, 2010): 29–34. http://dx.doi.org/10.1127/0935-1221/2010/0021-1986.

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18

Ershova, Natalia I., and Irina Yu Kelina. "High-temperature wear-resistant materials based on silicon nitride." Epitoanyag - Journal of Silicate Based and Composite Materials 61, no. 2 (2009): 34–37. http://dx.doi.org/10.14382/epitoanyag-jsbcm.2009.6.

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19

Sharpe, W. N. Jr, and C. S. Oh. "OS06W0394 High-Temperature Strain Measurement at the Micrometer Scale." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2003.2 (2003): _OS06W0394. http://dx.doi.org/10.1299/jsmeatem.2003.2._os06w0394.

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20

Zhang, Zhe, Yingying Wang, Min Zhou, Jun He, Changrui Liao, and Yiping Wang. "Recent advance in hollow-core fiber high-temperature and high-pressure sensing technology [Invited]." Chinese Optics Letters 19, no. 7 (2021): 070601. http://dx.doi.org/10.3788/col202119.070601.

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21

Lei, Che. "Research on ultrasonic vibration assisted repair technology of high temperature and high pressure parts." Functional materials 25, no. 4 (December 19, 2018): 809–17. http://dx.doi.org/10.15407/fm25.04.809.

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22

Zhao, Xueying, Aiqin Shen, and Baofu Ma. "Temperature Adaptability of Asphalt Pavement to High Temperatures and Significant Temperature Differences." Advances in Materials Science and Engineering 2018 (July 8, 2018): 1–16. http://dx.doi.org/10.1155/2018/9436321.

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Temperature adaptability of asphalt pavements is very important, due to their potential influence on pavement structure design, particularly in areas that experience significant temperature differences. In this paper, a finite element (FE) model was developed, and Turpan-Xiaocao Lake Highway in southern Xinjiang was taken as a case study engineering, which tends to experience this adverse environmental condition (temperature difference: 25.5°C; July 14, 2008). In this model, the generalized Kelvin model and the Burgers model were used. The time-dependent tire pressure was considered. To guide pavement structure design and control pavement distresses in this area, seven alternative pavement structures were selected to simulate and analyze pavement temperature fields and the mechanical responses. It was observed that the influence of air temperature had the greatest impact on Str-1, possibly due to the thinnest asphalt course. Moreover, when rutting depth, maximum shear stress of the asphalt course, deflection on the pavement surface, and compressive strains at the subgrade top surface were taken as the evaluation indices, the adaptability of asphalt pavements using compound base courses had obvious advantage due to their strong absorption and reflection of load impact. The adaptability of seven structures analyzed in this paper decreased in the following order: Str-5 > Str-6 > Str-4 > Str-2 > Str-m > Str-1 > Str-3. In addition, it broke the traditional view that asphalt pavement with a flexible base had the poor ability on rutting resistance. Besides, it also suggests that when the thickness of asphalt courses was equivalent, increasing the thickness of chemical-treated base courses would help with the deformation resistance, and vice versa.
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23

Liu, Zhangquan, Xiaohui Shi, Min Zhang, and Junwei Qiao. "High-Temperature Mechanical Properties of NbTaHfTiZrV0.5 Refractory High-Entropy Alloys." Entropy 25, no. 8 (July 26, 2023): 1124. http://dx.doi.org/10.3390/e25081124.

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The NbTaHfTiZrV0.5 is a refractory multi-principal-element alloy with high strength and good ductility at room temperature. It is important for possible high-temperature applications to investigate the deformation mechanism of the NbTaHfTiZrV0.5 alloy at different temperatures using tensile tests. In this investigation, the tensile tests were conducted at room temperature to 1273 K on sheet materials fabricated by cold rolling combined with annealing treatments. At 473 K, the NbTaHfTiZrV0.5 alloy exhibited a high tensile ductility (12%). At a testing temperature range of 673~873 K, the ductility was reduced, but the yield strength remained above 800 MPa, which is rare in most other alloys. The TEM investigations revealed that a dislocation slip controlled the plastic deformation, and the degree of deformation was closely related to the dislocation density. The true stress–strain curves of the alloy under different deformation conditions were obtained by tensile deformation at different deformation temperatures (673~873 K) and strain rates (0.001~0.0005 s−1). Experimental results were utilized to construct the parameters of a constitutive model based on a traditional mathematical model to predict the flow behavior at high temperatures. The excellent high-temperature mechanical properties of the NbTaHfTiZrV0.5 alloy will enable it to be used in several engineering applications.
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24

Kwon, Kiseok, and Ohsang Kweon. "Time-temperature Analysis of High-strength Concrete Exposed to High Temperatures." Journal of the Korean Society of Hazard Mitigation 18, no. 7 (December 31, 2018): 227–32. http://dx.doi.org/10.9798/kosham.2018.18.7.227.

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25

Johnson, Arden P., John S. Miller, and Yufei Wang. "High Power Lithium Primary Cells for High Temperature Downhole Applications." Additional Conferences (Device Packaging, HiTEC, HiTEN, and CICMT) 2012, HITEC (January 1, 2012): 000266–71. http://dx.doi.org/10.4071/hitec-2012-wp23.

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The power demands of downhole tools used in petroleum exploration continue to increase as new instrumentation is added for measurement and for communicating data to the surface. At the same time there is increasing demand for higher temperature capabilities that will allow exploration in hotter formations. As the use of high temperature electronic devices expands, new types of batteries are needed that can provide the necessary power at the higher temperatures. Here we describe a new lithium alloy primary battery technology that can power downhole tools and other high temperature devices up to 200°C under significantly higher loads than has been possible previously. The higher rate capability of the cell also enables sufficient operation at surface ambient temperatures to allow the functioning of the tool to be assessed at the surface before it is deployed downhole. Cell discharge results over a broad range of temperatures and rates are presented.
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26

Gawalek, Wolfgang, Tatyana Prikhna, Tobias Habisreuther, Peter Görnert, Victor Moshchil, Pavel Diko, Vyacheslav Solovyov, Vladimir Melnikov, Sergey Dub, and Peter Nagorny. "High pressure/high temperature treatment of melt textured YBCO high temperature superconductors." Czechoslovak Journal of Physics 46, S3 (March 1996): 1405–6. http://dx.doi.org/10.1007/bf02562817.

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27

Bybee, Karen. "High-Pressure/High-Temperature Cementing." Journal of Petroleum Technology 54, no. 08 (August 1, 2002): 58–61. http://dx.doi.org/10.2118/0802-0058-jpt.

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28

Angel, R. J., R. T. Downs, and L. W. Finger. "High-Temperature-High- Pressure Diffractometry." Reviews in Mineralogy and Geochemistry 41, no. 1 (January 1, 2000): 559–97. http://dx.doi.org/10.2138/rmg.2000.41.16.

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29

Hancox, N. L. "HIGH TEMPERATURE HIGH PERFORMANCE COMPOSITES." Advanced Materials and Manufacturing Processes 3, no. 3 (January 1988): 359–89. http://dx.doi.org/10.1080/08842588708953211.

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30

Lemkey, F. D., S. G. Fishman, A. G. Evans, and J. R. Strife. "HIGH TEMPERATURE - HIGH PERFORMANCE COMPOSITES." Materials and Manufacturing Processes 6, no. 4 (January 1991): 727–29. http://dx.doi.org/10.1080/10426919108934800.

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31

Deng, Zhifang, Ruoze Xie, Yixia Yan, Sizhong Li, and Xicheng Huang. "Temperature in high temperature SHPB experiments." Transactions of Tianjin University 14, S1 (October 2008): 536–39. http://dx.doi.org/10.1007/s12209-008-0092-9.

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32

Berthou, Maxime, Philippe Godignon, Bertrand Vergne, and Pierre Brosselard. "High Temperature Capability of High Voltage 4H-SiC JBS." Materials Science Forum 711 (January 2012): 124–28. http://dx.doi.org/10.4028/www.scientific.net/msf.711.124.

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This paper presents the high blocking capability of the 4H-SiC tungsten Schottky and junction barrier Schottky (JBS) diodes at room temperature as well as at high operating temperature. First, we present the design of the proposed devices and the process employed for their fabrication. In a second part, their forward and reverse characteristics at room temperature will be presented. Our rectifiers exhibit blocking capability up to 9kV at room temperature. Then, we investigate the reverse current behaviour at 5kV from room temperature to 250°C under vacuum. JBS and Schottky devices that are capable to block 8kV at room temperature, show leakage current inferior to 100µA at 250°C when reverse biased at 5kV. It confirms the capability of Silicon Carbide to produce devices capable of operation at temperatures and voltages above the Silicon limits.
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33

Gumyusenge, Aristide, and Jianguo Mei. "High Temperature Organic Electronics." MRS Advances 5, no. 10 (2020): 505–13. http://dx.doi.org/10.1557/adv.2020.31.

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ABSTRACTThe emerging breakthroughs in space exploration, smart textiles, and novel automobile designs have increased technological demand for high temperature electronics. In this snapshot review we first discuss the fundamental challenges in achieving electronic operation at elevated temperatures, briefly review current efforts in finding materials that can sustain extreme heat, and then highlight the emergence of organic semiconductors as a new class of materials with potential for high temperature electronics applications. Through an overview of the state-of-the art materials designs and processing methods, we will layout molecular design principles and fabrication strategies towards achieving thermally stable operation in organic electronics.
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34

Pimentel, Carlos. "Plant Responses to High-Temperature Stress." Archives of Agriculture Research and Technology (AART) 3, no. 3 (December 30, 2022): 1–2. http://dx.doi.org/10.54026/aart/1043.

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Temperature above optimal for the specie will reduce photosynthesis and increase dark respiration and photorespiration in part due to increased solubility of O2 compared to CO2 but also due to the decrease in CO2 mesophyll conductance to the chloroplast. In addition, night temperature has a great impact on carbohydrates balance because high night temperature reduces the efficiency of the generation of ATP from respiration consuming more sugars to maintain growth. Another effect on species that have their cycle sensitive to temperature, inducing the reproductive phase soon or later depending on air temperature. The majority of plants adapted to high temperatures above their optimum synthesize small HSPs, which will maintain the integrity and reactivity of bigger enzymes and membranes. Therefore, plant adaptation to high temperatures is a multigenic characteristic depending on biochemical, physiological, and morphological traits.
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35

Zhou, Xingjiang, Wei-Sheng Lee, Masatoshi Imada, Nandini Trivedi, Philip Phillips, Hae-Young Kee, Päivi Törmä, and Mikhail Eremets. "High-temperature superconductivity." Nature Reviews Physics 3, no. 7 (May 28, 2021): 462–65. http://dx.doi.org/10.1038/s42254-021-00324-3.

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36

Spear, Karl, Eric Wuchina, and Eric D. Wachsman. "High Temperature Materials." Electrochemical Society Interface 15, no. 1 (March 1, 2006): 48–51. http://dx.doi.org/10.1149/2.f14061if.

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37

YOMO, Shusuke, and Nobuo MORI. "High temperature superconductivity." Journal of Advanced Science 2, no. 2 (1990): 98–102. http://dx.doi.org/10.2978/jsas.2.98.

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38

Dow, John D., and Dale R. Harshman. "High-temperature superconductivity." Brazilian Journal of Physics 33, no. 4 (December 2003): 681–85. http://dx.doi.org/10.1590/s0103-97332003000400008.

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39

Maruyama, Kouichi. "High Temperature Strength." Materia Japan 36, no. 9 (1997): 877–80. http://dx.doi.org/10.2320/materia.36.877.

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40

Taniguchi, Shigeji. "High Temperature Corrosion." Materia Japan 36, no. 9 (1997): 904–7. http://dx.doi.org/10.2320/materia.36.904.

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41

McDougall, Ian, Colin Gough, and Andrew Mackenzie. "High-temperature superconductivity." Physics World 9, no. 9 (September 1996): 17–18. http://dx.doi.org/10.1088/2058-7058/9/9/12.

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42

Tamborski, Christ. "HIGH TEMPERATURE ADDITIVES." Annals of the New York Academy of Sciences 125, no. 1 (December 16, 2006): 242–48. http://dx.doi.org/10.1111/j.1749-6632.1965.tb45394.x.

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43

Anonymous. "High-Temperature Superconductivity." Physical Review Letters 59, no. 18 (November 2, 1987): 1985. http://dx.doi.org/10.1103/physrevlett.59.1985.

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44

Male, S. E. "High temperature superconductivity." Science and Public Policy 14, no. 6 (December 1987): 362–64. http://dx.doi.org/10.1093/spp/14.6.362.

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45

Wang, Meitian, and Arthur Mar. "High-temperature LaAs2." Acta Crystallographica Section C Crystal Structure Communications 56, no. 2 (February 15, 2000): 138–39. http://dx.doi.org/10.1107/s0108270199015553.

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46

Nicholls, J. R. "High temperature corrosion." British Corrosion Journal 25, no. 1 (January 1990): 15–16. http://dx.doi.org/10.1179/bcj.1990.25.1.15.

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47

Bullock, E. "High Temperature Topics." High Temperature Technology 7, no. 3 (August 1989): 152–58. http://dx.doi.org/10.1080/02619180.1989.11753428.

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48

Lieber, Charles M., and Peidong Yang. "High-Temperature Superconductors." Science 277, no. 5334 (September 26, 1997): 1909.3–1914. http://dx.doi.org/10.1126/science.277.5334.1909-c.

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49

Lieber, C. M. "High-Temperature Superconductors." Science 277, no. 5334 (September 26, 1997): 1909b—1914. http://dx.doi.org/10.1126/science.277.5334.1909b.

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50

Timusk, Tom. "High-temperature uncertainty." Physics World 18, no. 7 (July 2005): 31–35. http://dx.doi.org/10.1088/2058-7058/18/7/35.

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