The Role of Infiltration Temperature in the Reaction Bonding of Boron Carbide by Silicon Infiltration

Zhang, Cuiping; Ru, Hongqiang; Wang, Wei; Yue, Xinyan; Zhao, Jing

doi:10.1111/jace.13085

Cited by 29 publications

(18 citation statements)

References 32 publications

(50 reference statements)

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“…In the present study we couldn't notice on any influence of the tretmant temperature on the hardness values. This finding is opposite to the results obtained in conventional method [18] where the influence of the infiltration temperature on the hardness values is strong. We used this data to modeling with Nemrodw software.…”

Section: Mechanical Propertycontrasting

confidence: 99%

Infiltration of Molten Silicon in a Porous Body of B ₄ C Under Microwave Heating

Dutto

Gœuriot

Saunier

et al. 2017

Ceramic Transactions Series

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Boron Carbide is an attractive material for various applications that require high hardness and neutron absorption. Fully dense boron carbide bodies are usually fabricated using hot pressing at temperatures above 2000 °C. Therefore, the production cost is very high, that constitutes the major drawback for widespread applications in the fields of defense and nuclear energy. An alternative route to decrease the production costs is the reactionbonded technique (RBBC). In this latter, a preform of porous B 4 C is obtained by compaction and partial densification. Then the material is infiltrated by molten metal or alloy. The metal can react with residual carbon and boron carbide to form carbide. This technique was extensively studied using conventional furnace but the use of microwave as a source of heating, as not used for this purpose so far, or only in a very few attempts. In the present study, the microstructure and mechanical properties of reaction bonding B 4 C infiltrated by silicon using microwave (2.45GHz) heating will be presented. The results will be discussed in the light of conventional RBBC.

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Section: Mechanical Propertycontrasting

confidence: 99%

Infiltration of Molten Silicon in a Porous Body of B ₄ C Under Microwave Heating

Dutto

Gœuriot

Saunier

et al. 2017

Ceramic Transactions Series

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“…It might cause the formation of “Necks” between neighboring boron carbide particles. As a result, the neighboring boron carbide particles further grew together and led to some coarsened boron carbide particles in the infiltrated sample . In contrast, the I‐GC composite shows much more uniform microstructures (Figure D‐F).…”

Section: Resultsmentioning

confidence: 99%

Gel‐casting process‐derived 3D‐interconnected porous carbon/B₄C preform for reaction‐bonded boron carbide composites

Long

et al. 2017

Int J Applied Ceramic Tech

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A novel kind of 3D interconnected porous carbon-bonded B 4 C preform with flexural strength of about 20MPa is fabricated by gel-casting method. As the control, the B 4 C/C preforms via molding-produced method are fabricated. The B 4 C/C preforms own the same carbon content and almost the same porosity with different molding method. Compared with the conventional compression molding-produced B 4 C/C preform, the 3D-interconnected porous carbon-bonded boron carbide preforms afford three-fold advantages in the fabrication of reaction-bonded boron carbide (RBBC) composite via the liquid silicon infiltration (LSI) process, including induced formation of continuous SiC-bonded boron carbide skeleton structure, a reduction in the size of residual silicon, and prevented the coarsening of ceramic grains as well. As a result, the RBBC composite fabricated by gel-casting appears as a more refined structure resulting in enhanced mechanical properties: the Vickers hardness, flexural strength, and fracture toughness of I-GC composites fabricated from 3D-interconnected porous carbon/B 4 C preforms are 19.4 AE 1.3 GPa, 389 AE 17 MPa, and 4.37 AE 0.1 MPaÁm 1/2 , respectively, which are statistically higher than those of RBBC fabricated by the conventional compression moldingproduced B 4 C/C preform. K E Y W O R D Sboron carbide, gel-casting, infiltration, mechanical properties, refined structure

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“…The silicon used for the infiltration was in the form of lumps furnished by Alfa Aesar with the purity of 98.4% (0.45% of Fe, 0.08% of Al and 0.008% of Ca). According to the literature, conventional RBBC is usually fabricated under high vacuum (1.3 × 10 −2 ‐1.3 × 10 −3 Pa). This low pressure is incompatible with microwave heating because it promotes plasma formation into the microwave cavity.…”

Section: Methodsmentioning

confidence: 99%

Reaction‐bonded B₄C/SiC composites synthesized by microwave heating

Dutto

Gœuriot

Saunier

et al. 2019

Int J Applied Ceramic Tech

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The reaction‐bonding technique was used to synthesize boron carbide (B4C) ‐ silicon carbide (SiC) composites by microwave heating. Preforms of porous B4C were obtained by compaction followed or not by partial densification. Then, the material was infiltrated by molten silicon under a microwave heating. The influence of the thermal cycles (T: 1400‐1500°C, t: 5‐120 minutes) is low. The hardness of boron carbide is comparable to that of alumina (15‐19 GPa) for a much lower density (≈2.5 g/cm3 for B4C‐based material instead of 3.95 g/cm3 for alumina). These properties make this composite, obtained by microwave heating, a good candidate for ballistic applications.

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The Role of Infiltration Temperature in the Reaction Bonding of Boron Carbide by Silicon Infiltration

Cited by 29 publications

References 32 publications

Infiltration of Molten Silicon in a Porous Body of B ₄ C Under Microwave Heating

Infiltration of Molten Silicon in a Porous Body of B ₄ C Under Microwave Heating

Gel‐casting process‐derived 3D‐interconnected porous carbon/B₄C preform for reaction‐bonded boron carbide composites

Reaction‐bonded B₄C/SiC composites synthesized by microwave heating

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The Role of Infiltration Temperature in the Reaction Bonding of Boron Carbide by Silicon Infiltration

Cited by 29 publications

References 32 publications

Infiltration of Molten Silicon in a Porous Body of B 4 C Under Microwave Heating

Infiltration of Molten Silicon in a Porous Body of B 4 C Under Microwave Heating

Gel‐casting process‐derived 3D‐interconnected porous carbon/B4C preform for reaction‐bonded boron carbide composites

Reaction‐bonded B4C/SiC composites synthesized by microwave heating

Contact Info

Product

Resources

About

Infiltration of Molten Silicon in a Porous Body of B ₄ C Under Microwave Heating

Infiltration of Molten Silicon in a Porous Body of B ₄ C Under Microwave Heating

Gel‐casting process‐derived 3D‐interconnected porous carbon/B₄C preform for reaction‐bonded boron carbide composites

Reaction‐bonded B₄C/SiC composites synthesized by microwave heating