Thermal Properties | Metric | English | Comments |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 0% cold reduction Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 10% cold reduction Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 10% cold reduction, 925°C for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 10% cold reduction, 980°C (1800°F) for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 20% cold reduction Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 30% cold reduction, 1095°C (2000°F) for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 30% cold reduction, 925°C for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 40% cold reduction Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 40% cold reduction, 1095°C (2000°F) for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 40% cold reduction, 980°C (1800°F) for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 50% cold reduction Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 50% cold reduction, 1095°C (2000°F) for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 50% cold reduction, 925°C for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 50% cold reduction, 980°C (1800°F) for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 100 hours exposure at 760°C (1400°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 100 hours exposure at 870°C (1600°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 100 hours exposure at 980°C (1800°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 1000 hours exposure at 870°C (1600°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 1000 hours exposure at 980°C (1800°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 32 hours exposure at 760°C (1400°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 32 hours exposure at 870°C (1600°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, sheet, 32 hours exposure at 980°C (1800°F) Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.741 J/g-°C | 0.177 BTU/lb-°F | |
Mateck Quartz Crystalline (SiO2) Optical crystals |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 30% cold reduction Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.742 J/g-°C @Temperature 1000 °C |
0.177 BTU/lb-°F @Temperature 1830 °F |
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Haynes 214® alloy, 30% cold reduction, 980°C (1800°F) for 5 minutes Intended principally for use at temperatures of 955°C and above, exhibits resistance to oxidation that exceeds virtually all conventional heat-resistant wrought alloys. Applications include mesh .. |
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Specific Heat Capacity | 0.740 J/g-°C | 0.177 BTU/lb-°F | |
Schott N-SF10 Glass Information Provided by SCHOTT North America, Inc. |
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Specific Heat Capacity | 0.740 J/g-°C @Temperature 100 - 200 °C |
0.177 BTU/lb-°F @Temperature 212 - 392 °F |
DINV ENV 821-3 |
CeramTec Alunit® Aluminum Nitride Alunit® offers an extremely high thermal conductivity of 180 W/mK and outstanding electrical insulation properties. The thermal expansion coefficient of this material is comparable to silicon. Its .. |
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Specific Heat Capacity | 0.740 J/g-°C @Temperature 100 °C |
0.177 BTU/lb-°F @Temperature 212 °F |
ASTM E1269 |
CoorsTek Hot Pressed Aluminum Nitride Aluminum Nitride Advantages: High heat dissipation with thermal conductivity of 170 W/m K Non-toxic alternative to BeO Thermal expansion coefficient similar to Si, GaN, and GaAs semiconductors H.. |
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Specific Heat Capacity | 0.741 J/g-°C | 0.177 BTU/lb-°F | |
Ceramic Process Systems AlSiC-8, 70 vol% SiC Aluminum alloy A356.2 used. Hermeticity < 1x109 atm-cc/s He.CPS fabricates AlSiC by preparing an SiC preform which is subsequently infiltrated by molten aluminum metal. After infiltration, compone.. |
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Specific Heat Capacity | 0.741 J/g-°C | 0.177 BTU/lb-°F | |
Ceramic Process Systems AlSiC-9, 63 vol% SiC Aluminum alloy A356.2 used. Hermeticity < 1x109 atm-cc/s He.CPS fabricates AlSiC by preparing an SiC preform which is subsequently infiltrated by molten aluminum metal. After infiltration, compone.. |