Additive manufacturing (AM), also known as 3D printing, has emerged as a transformative technology across various manufacturing sectors. It enables the fabrication of complex geometries, high-volume customization, significant material savings through layer-by-layer manufacturing methods, and the potential for the use of Eco-friendly materials. This technology offers significant freedom in the design and fabrication of complex geometric parts, with the potential to reduce costs in both prototyping and final product manufacturing, as well as reduce waste through the recycling of materials lost during manufacturing processes. Although its adoption in the ceramics industry has lagged that of polymers and metals, its unique capabilities in fabricating complex geometries of high-performance ceramics are receiving significant attention. This review provides a comprehensive overview of the current landscape of AM technologies specifically designed for ceramic materials. It explores the underlying principles of various ceramic 3D printing processes, highlighting their advantages and disadvantages in producing high-density, defect-free components with customized properties. Furthermore, this paper examines the transformative impact of AM on ceramics in various structural and functional industrial applications, including aerospace, biomedicine, electronics, energy, and more. By bringing together the latest developments and addressing the inherent challenges associated with ceramic processing via additive manufacturing, this review highlights the tremendous potential of this technology to revolutionize conventional ceramic manufacturing and enable the production of advanced ceramic components with enhanced performance and functionality.