Boron Carbide-Zirconium Boride In Situ Composites by the Reactive Pressureless Sintering of Boron Carbide-Zirconia Mixtures

The heating of B4C–YTZP (where YTZP denotes yttria‐stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generates B4C–ZrB2 composites, because of a low‐temperature (<1500°C) carbide–oxide reaction. Composites derived from mixtures that include ≥15% YTZP are better sintered than...

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Published in	Journal of the American Ceramic Society Vol. 84; no. 3; pp. 642 - 644
Main Authors	Goldstein, Adrian, Geffen, Ygal, Goldenberg, Ayala
Format	Journal Article
Language	English
Published	Westerville, Ohio American Ceramics Society 01.03.2001 Blackwell Wiley Subscription Services, Inc
Subjects	Applied sciences boron carbide Building materials. Ceramics. Glasses Ceramic industries Chemical industry and chemicals Exact sciences and technology sinter/sintering Structural ceramics Technical ceramics zirconia: yttria-stabilized tetragonal polycrystal Reaction sintering Yttrium Oxides Boron Carbides Stabilized zirconia Manufacturing Experimental study Composite material Non oxide ceramics Structural ceramic Zirconium Borides
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Abstract	The heating of B4C–YTZP (where YTZP denotes yttria‐stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generates B4C–ZrB2 composites, because of a low‐temperature (<1500°C) carbide–oxide reaction. Composites derived from mixtures that include ≥15% YTZP are better sintered than monolithic B4C that has been fired under the same conditions. Firing to ∼2160°C (1 h dwell) generates specimens with a bulk density of ≥91% of the theoretical density (TD) for cases where the initial mixture includes ≥15% YTZP. Mixtures that include 30% YTZP allow a fired density of ≥97.5% TD to be attained. The behavior of the B4C–YTZP system is similar to that of the B4C–TiO2 system. Dense B4C–ZrB2 composites attain a hardness (Vickers) of 30–33 GPa.
AbstractList	The heating of B4C–YTZP (where YTZP denotes yttria‐stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generates B4C–ZrB2 composites, because of a low‐temperature (<1500°C) carbide–oxide reaction. Composites derived from mixtures that include ≥15% YTZP are better sintered than monolithic B4C that has been fired under the same conditions. Firing to ∼2160°C (1 h dwell) generates specimens with a bulk density of ≥91% of the theoretical density (TD) for cases where the initial mixture includes ≥15% YTZP. Mixtures that include 30% YTZP allow a fired density of ≥97.5% TD to be attained. The behavior of the B4C–YTZP system is similar to that of the B4C–TiO2 system. Dense B4C–ZrB2 composites attain a hardness (Vickers) of 30–33 GPa. The heating of B 4 C–YTZP (where YTZP denotes yttria‐stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generates B 4 C–ZrB 2 composites, because of a low‐temperature (<1500°C) carbide–oxide reaction. Composites derived from mixtures that include ≥15% YTZP are better sintered than monolithic B 4 C that has been fired under the same conditions. Firing to ∼2160°C (1 h dwell) generates specimens with a bulk density of ≥91% of the theoretical density (TD) for cases where the initial mixture includes ≥15% YTZP. Mixtures that include 30% YTZP allow a fired density of ≥97.5% TD to be attained. The behavior of the B 4 C–YTZP system is similar to that of the B 4 C–TiO 2 system. Dense B 4 C–ZrB 2 composites attain a hardness (Vickers) of 30–33 GPa. The heating of B sub 4 C-TYZP (where YTZP denotes yttria-stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generated B sub 4 C-ZrB sub 2 composites, because of a low-temperature ( < 1500 deg C) carbide-oxide reaction. Composites derived from mixtures that include > =15% YTZP are better sintered than monolithic B sub 4 C that has been fired udner the same conditions. Fring to approx2160 deg C (1 h dwell) generates specimens with a bulk density of > =91% of the theoretical density (TD) for cases where the initial mixture includes > =15% YTZP. Mixtures that include 30% YTZP allow a fired density of > =97.5% TD to be attained. The behavior of the B sub 4 C-YTZP system is similar to that of the B sub 4 C-TiO sub 2 system. Dense B sub 4 C-ZrB sub 2 composites attain a hardness (Vickers) of 30-33 GPa.
Author	Goldstein, Adrian Goldenberg, Ayala Geffen, Ygal
Author_xml	– sequence: 1 givenname: Adrian surname: Goldstein fullname: Goldstein, Adrian organization: Israel Ceramic and Silicate Institute, Haifa 32000, Israel – sequence: 2 givenname: Ygal surname: Geffen fullname: Geffen, Ygal organization: Israel Ceramic and Silicate Institute, Haifa 32000, Israel – sequence: 3 givenname: Ayala surname: Goldenberg fullname: Goldenberg, Ayala organization: Israel Ceramic and Silicate Institute, Haifa 32000, Israel
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Cites_doi	10.1111/j.1151-2916.1995.tb08671.x 10.1016/0025-5416(88)90485-5 10.1007/BF00240800 10.1111/j.1151-2916.1969.tb11975.x 10.1016/S0955-2219(98)00071-5 10.1007/s11661-999-0230-6
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Keywords	Reaction sintering Yttrium Oxides Boron Carbides Stabilized zirconia Manufacturing Experimental study Composite material Non oxide ceramics Structural ceramic Zirconium Borides
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Snippet	The heating of B4C–YTZP (where YTZP denotes yttria‐stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generates B4C–ZrB2 composites,... The heating of B 4 C–YTZP (where YTZP denotes yttria‐stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generates B 4 C–ZrB 2 composites,... The heating of B sub 4 C-TYZP (where YTZP denotes yttria-stabilized zirconia polycrystals) mixtures, under an argon atmosphere, generated B sub 4 C-ZrB sub 2...
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SubjectTerms	Applied sciences boron carbide Building materials. Ceramics. Glasses Ceramic industries Chemical industry and chemicals Exact sciences and technology sinter/sintering Structural ceramics Technical ceramics zirconia: yttria-stabilized tetragonal polycrystal
Title	Boron Carbide-Zirconium Boride In Situ Composites by the Reactive Pressureless Sintering of Boron Carbide-Zirconia Mixtures
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