Processing and Properties of Nanograin Silicon Carbide

The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced. Ausführliche Beschreibung

Gespeichert in:

Autor*in:	Vassen, Robert [verfasserIn] Stöver, Detlev [verfasserIn]

Format:	E-Artikel

Erschienen:	Westerville, Ohio: American Ceramics Society ; 1999

Umfang:	Online-Ressource

Reproduktion:	2004 ; Blackwell Publishing Journal Backfiles 1879-2005
Übergeordnetes Werk:	In: Journal of the American Ceramic Society - American Ceramic Society ; GKD-ID: 6113X, Oxford [u.a.] : Wiley-Blackwell, 1918, 82(1999), 10, Seite 0
Übergeordnetes Werk:	volume:82 ; year:1999 ; number:10 ; pages:0

Links:	Volltext

DOI / URN:	10.1111/j.1151-2916.1999.tb02127.x

Katalog-ID:	NLEJ243480296

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allfields	10.1111/j.1151-2916.1999.tb02127.x doi (DE-627)NLEJ243480296 DE-627 ger DE-627 rakwb Vassen, Robert verfasserin aut Processing and Properties of Nanograin Silicon Carbide Westerville, Ohio American Ceramics Society 1999 Online-Ressource nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced. 2004 Blackwell Publishing Journal Backfiles 1879-2005 \|2004\|\|\|\|\|\|\|\|\|\| Stöver, Detlev verfasserin aut In American Ceramic Society ; GKD-ID: 6113X Journal of the American Ceramic Society Oxford [u.a.] : Wiley-Blackwell, 1918 82(1999), 10, Seite 0 Online-Ressource (DE-627)NLEJ243927835 (DE-600)2008170-4 1551-2916 nnns volume:82 year:1999 number:10 pages:0 http://dx.doi.org/10.1111/j.1151-2916.1999.tb02127.x text/html Verlag Deutschlandweit zugänglich Volltext GBV_USEFLAG_U ZDB-1-DJB GBV_NL_ARTICLE AR 82 1999 10 0
spelling	10.1111/j.1151-2916.1999.tb02127.x doi (DE-627)NLEJ243480296 DE-627 ger DE-627 rakwb Vassen, Robert verfasserin aut Processing and Properties of Nanograin Silicon Carbide Westerville, Ohio American Ceramics Society 1999 Online-Ressource nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced. 2004 Blackwell Publishing Journal Backfiles 1879-2005 \|2004\|\|\|\|\|\|\|\|\|\| Stöver, Detlev verfasserin aut In American Ceramic Society ; GKD-ID: 6113X Journal of the American Ceramic Society Oxford [u.a.] : Wiley-Blackwell, 1918 82(1999), 10, Seite 0 Online-Ressource (DE-627)NLEJ243927835 (DE-600)2008170-4 1551-2916 nnns volume:82 year:1999 number:10 pages:0 http://dx.doi.org/10.1111/j.1151-2916.1999.tb02127.x text/html Verlag Deutschlandweit zugänglich Volltext GBV_USEFLAG_U ZDB-1-DJB GBV_NL_ARTICLE AR 82 1999 10 0
allfields_unstemmed	10.1111/j.1151-2916.1999.tb02127.x doi (DE-627)NLEJ243480296 DE-627 ger DE-627 rakwb Vassen, Robert verfasserin aut Processing and Properties of Nanograin Silicon Carbide Westerville, Ohio American Ceramics Society 1999 Online-Ressource nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced. 2004 Blackwell Publishing Journal Backfiles 1879-2005 \|2004\|\|\|\|\|\|\|\|\|\| Stöver, Detlev verfasserin aut In American Ceramic Society ; GKD-ID: 6113X Journal of the American Ceramic Society Oxford [u.a.] : Wiley-Blackwell, 1918 82(1999), 10, Seite 0 Online-Ressource (DE-627)NLEJ243927835 (DE-600)2008170-4 1551-2916 nnns volume:82 year:1999 number:10 pages:0 http://dx.doi.org/10.1111/j.1151-2916.1999.tb02127.x text/html Verlag Deutschlandweit zugänglich Volltext GBV_USEFLAG_U ZDB-1-DJB GBV_NL_ARTICLE AR 82 1999 10 0
allfieldsGer	10.1111/j.1151-2916.1999.tb02127.x doi (DE-627)NLEJ243480296 DE-627 ger DE-627 rakwb Vassen, Robert verfasserin aut Processing and Properties of Nanograin Silicon Carbide Westerville, Ohio American Ceramics Society 1999 Online-Ressource nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced. 2004 Blackwell Publishing Journal Backfiles 1879-2005 \|2004\|\|\|\|\|\|\|\|\|\| Stöver, Detlev verfasserin aut In American Ceramic Society ; GKD-ID: 6113X Journal of the American Ceramic Society Oxford [u.a.] : Wiley-Blackwell, 1918 82(1999), 10, Seite 0 Online-Ressource (DE-627)NLEJ243927835 (DE-600)2008170-4 1551-2916 nnns volume:82 year:1999 number:10 pages:0 http://dx.doi.org/10.1111/j.1151-2916.1999.tb02127.x text/html Verlag Deutschlandweit zugänglich Volltext GBV_USEFLAG_U ZDB-1-DJB GBV_NL_ARTICLE AR 82 1999 10 0
allfieldsSound	10.1111/j.1151-2916.1999.tb02127.x doi (DE-627)NLEJ243480296 DE-627 ger DE-627 rakwb Vassen, Robert verfasserin aut Processing and Properties of Nanograin Silicon Carbide Westerville, Ohio American Ceramics Society 1999 Online-Ressource nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced. 2004 Blackwell Publishing Journal Backfiles 1879-2005 \|2004\|\|\|\|\|\|\|\|\|\| Stöver, Detlev verfasserin aut In American Ceramic Society ; GKD-ID: 6113X Journal of the American Ceramic Society Oxford [u.a.] : Wiley-Blackwell, 1918 82(1999), 10, Seite 0 Online-Ressource (DE-627)NLEJ243927835 (DE-600)2008170-4 1551-2916 nnns volume:82 year:1999 number:10 pages:0 http://dx.doi.org/10.1111/j.1151-2916.1999.tb02127.x text/html Verlag Deutschlandweit zugänglich Volltext GBV_USEFLAG_U ZDB-1-DJB GBV_NL_ARTICLE AR 82 1999 10 0
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title_sort	processing and properties of nanograin silicon carbide
title_auth	Processing and Properties of Nanograin Silicon Carbide
abstract	The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced.
abstractGer	The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced.
abstract_unstemmed	The manufacture of fine-grained SiC ceramics by using nanophase SiC powders with particle sizes of about 20 nm is described. Conventional sintering of these powders led to extreme grain growth and hence the nanophase microstructure was destroyed. Pressure-assisted sintering was applied to reduce the sintering temperature and also grain growth. Hot isostatic pressing (HIPing) of samples with about 1 wt% carbon and 1 wt% boron addition at temperatures below 1700°C and with pressures up to 350 MPa resulted in densities of more than 95% of the theoretical density (TD) and grain sizes of 150 nm. A further reduction of grain size became possible by an optimized high-temperature heat treatment of the samples prior to HIP. This procedure removed at least partially the oxygen layer on the surface of the nanophase SiC particles. Samples with densities of more than 97% TD and grain sizes below 80 nm were produced. Grain sizes were measured with scanning and transmission electron microscopes; both methods gave similar values. Grain sizes determined from the peak broadening of X-ray diffraction peaks showed in some cases lower values. This was attributed to the relatively high amount of twinning boundaries and stacking faults produced during crystal growth. The influence of the grain size on different mechanical and thermal properties was investigated. Vickers hardness and indentation fracture toughness were measured for samples with different densities and grain sizes. The results revealed that besides grain size features like density and/or oxygen content can strongly influence hardness and fracture toughness. Similar results have been found for the wear resistance of fine-grained materials. Results of pin-on-disk type experiments showed the importance of a high density of the samples for high wear resistance. Thermal diffusivity measurements were performed for samples with different grain sizes up to 1400°C. A large decrease with decreasing grain size was found at room temperature. At higher temperatures the difference in the thermal diffusivity of fine- and large-grained materials was reduced.
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title_short	Processing and Properties of Nanograin Silicon Carbide
url	http://dx.doi.org/10.1111/j.1151-2916.1999.tb02127.x
remote_bool	true
author2	Stöver, Detlev
author2Str	Stöver, Detlev
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doi_str	10.1111/j.1151-2916.1999.tb02127.x
up_date	2024-07-06T05:35:47.296Z
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