Fabrication and properties of symmetrical W/Si3N4/W functionally graded materials by spark plasma sintering

Si3N4 ceramics have shown promising application prospects as the sealing materials for liquid metal batteries (LMBs). However, the joining of Si3N4 to the metal shell of LMBs is rather difficult because of the nonwetting property and mismatch of their thermal expansion coefficients (CTEs). Herein, to solve the above issue, W/Si3N4 functionally graded materials (FGMs) were designed and fabricated via the spark plasma sintering (SPS) process. The effects of layer numbers and layer components on the phase composition, structure, and thermal stress of the FGMs were systematically investigated using both experimental and simulation methods. W/Si3N4 FGMs, with optimal layer numbers, were then utilized for fabricating symmetrical W/Si3N4/W FGMs. The thermal stress of the products can be effectively reduced by adjusting the MgO content of the central Si3N4 layer. As a result, the optimal product displayed good interface bonding between two adjacent layers and also exhibited high flexural strength (943.9 MPa) and electrical resistivity (2.0 x 1012 omega cm). This route for the fabrication of symmetrical W/Si3N4/W FGMs exhibits the advantage of high efficiency, and the products with excellent properties can be used as sealing materials for LMBs. (c) 2021 Elsevier B.V. All rights reserved.

Automated summary

W/Si3N4 functionally graded materials were fabricated via spark plasma sintering for sealing liquid metal batteries. By adjusting the MgO content of the central Si3N4 layer, thermal stress of the products was effectively reduced, leading to good interface bonding and high performance.