Litcius/Paper detail

Multi-material additive manufacturing of low sintering temperature Bi<sub>2</sub>Mo<sub>2</sub>O<sub>9</sub>ceramics with Ag floating electrodes by selective laser burnout

Reza Gheisari, Henry Chamberlain, George Chi‐Tangyie, Shiyu Zhang, Athanasios Goulas, Chih‐Kuo Lee, Tom Whittaker, Dawei Wang, Annapoorani Ketharam, Avishek Ghosh, Bala Vaidhyanathan, William G. Whittow, Darren Cadman, Yiannis Vardaxoglou, Ian M. Reaney, Daniel S. Engstrøm

2020Virtual and Physical Prototyping35 citationsDOIOpen Access PDF

Abstract

Additive manufacturing (AM) of co-fired low temperature ceramics offers a unique route for fabrication of novel 3D radio frequency (RF) and microwave communication components, embedded electronics and sensors. This paper describes the first-ever direct 3D printing of low temperature co-fired ceramics/floating electrode 3D structures. Slurry-based AM and selective laser burnout (SLB) were used to fabricate bulk dielectric, Bi2Mo2O9 (BMO, sintering temperature = 620–650°C, εr = 38) with silver (Ag) internal floating electrodes. A printable BMO slurry was developed and the SLB optimised to improve edge definition and burn out the binder without damaging the ceramic. The SLB increased the green strength needed for shape retention, produced crack-free parts and prevented Ag leaching into the ceramic during co-firing. The green parts were sintered after SLB in a conventional furnace at 645°C for 4 h and achieved 94.5% density, compressive strength of 4097 MPa, a relative permittivity (εr) of 33.8 and a loss tangent (tan δ) of 0.0004 (8 GHz) for BMO. The feasibility of using SLB followed by a post-printing sintering step to create BMO/Ag 3D structures was thus demonstrated.

Topics & Concepts

Materials scienceCeramicSinteringElectrodeSelective laser sinteringLaserBurnoutComposite materialMetallurgyOpticsEngineeringAutomotive engineeringPhysical chemistryPhysicsChemistryFerroelectric and Piezoelectric MaterialsMicrowave Dielectric Ceramics SynthesisLuminescence Properties of Advanced Materials