Why is sintering important in crystalline electrolyte materials?

In this process, samples are heated by convection and/or radiation techniques in furnaces. Sintering is a crucial step for crystalline electrolyte materials as it enhances mechanical strength, reduces porosity, and lowers grain boundary resistance, consequently improving ionic conductivity.

What are the different sintering techniques?

Several advanced sintering techniques for solid electrolytes include hot pressing, field-assisted sintering, flash sintering, microwave sintering, and spark plasma sintering.

Why is sintering driven by Gibbs free energy?

The process of sintering is intrinsically driven by the Gibbs free energy because both the densification and grain growth steps require a thermodynamic driving force, which is the reduction of the total Gibbs free energy of the system, making them thermodynamically favorable.

What is a fast sintering process?

This method is a re-visit of traditional fast firing, using carbon foils under resistance heating to rapidly sinter multiple small pellets (∼5 mm diameter), sandwiched between foil layers. Typical process duration is less than 30 s, reaching temperatures of up to 3000 °C.

How can a sintering process improve density and conductivity?

Faster and lower temperature sintering processes are suggested to reduce processing costs and volatilisation, and to increase energy efficiency. Maintaining high density and conductivity can be achieved through mitigation strategies which include lowering the sintering temperature and time . Li loss from the system impedes densification .

What is liquid phase sintering?

Liquid-phase sintering is a viable technique to improve the density of sintered electrolytes . Commonly used sintering aids with a low melting point are oxides such as ZnO, MgO, and B 2 O 3 or lithium salts such as Li 2 O, Li 3 PO 4, Li 3 BO 3 , LiBO 2 or LIF [, , ].