Over the last two decades

ceramic binder jetting additive manufacturing (BJAM) has emerged as a revolutionary technique for fabricating complex ceramic components

demonstrating significant potential and value in critical domains such as aerospace

biomedicine

and electronic information. This article comprehensively reviews the fundamental principles

material selection

process methodologies

performance characteristics

and manufacturing defects of this technology

along with an in-depth outlook on future challenges and objectives. Initially

the article elucidates the forming principles of this technology

juxtaposing its advantages and limitations against other additive manufacturing processes. It then synthesizes global research advancements

focusing on ceramic powder treatment and its properties

binder configuration and its dynamical behavior in powder beds

process parameter adjustments

and subsequent densification post-processing

discussing how these factors impact the density

porosity

microstructure

and performance of both green bodies and final components. Lastly

based on existing research outcomes and application limitations

the paper proposes forward-looking recommendations for the development of powder materials

binder design

and process parameter optimization. This review aims to provide comprehensive guidance for understanding and applying ceramic binder jetting additive manufacturing in scientific research and engineering practices.