TRUNNANO Introduces Revolutionary Nano-Boron Nitride Coated Silicon Carbide-Silicon Nitride Composite Ceramic Crucible
LUOYANG, China, Jan. 12, 2026 (GLOBE NEWSWIRE) -- TRUNNANO, a leading global company in advanced ceramic materials, today announced a major breakthrough in high-temperature ceramic crucible technology. The company has successfully developed a silicon carbide-silicon nitride composite ceramic crucible with a nano-boron nitride coating (referred to as the SiC-Si3N4/BN nano-coated crucible). Through unique material composite and surface engineering design, this product significantly improves the crucible's overall performance under extreme environments, solving several bottleneck problems inherent in traditional silicon carbide and mullite crucibles in practical applications. It provides a more efficient and reliable solution for fields such as new energy batteries, magnetic materials, special metallurgy, and high-temperature chemical synthesis.
SiC-Si3N4 crucible with nano BN coating
Industry Pain Points and Technological Innovation Background
In processes such as high-temperature melting, crystal growth, sintering of battery positive and negative electrode materials, and magnetic material preparation, the material of the crucible directly affects production efficiency and product quality. While widely used pure silicon carbide crucibles possess high thermal conductivity and some thermal shock resistance, their surfaces are prone to adhesion to molten materials, and they corrode rapidly in alkaline environments. Furthermore, their internal porous structure reduces their density and lifespan. On the other hand, mullite crucibles, although lower in cost, have relatively insufficient thermal conductivity and limited flexural strength. They are prone to perforation under high-temperature and alkaline conditions, and cracking is especially likely under rapid heating/cooling or high-intensity mechanical loads, making them unsuitable for increasingly demanding high-end manufacturing requirements.
To address these challenges, the TRUNNANO R&D team, focusing on material microstructure control and surface functionalization, innovatively combined the high thermal conductivity and high hardness of silicon carbide (SiC) with the excellent flexural strength and thermal shock resistance of silicon nitride (Si3N4). Using vapor deposition technology, they constructed a dense and uniform nanoscale boron nitride (BN) coating on the inner surface of the crucible. This dual design of “matrix composite + nanocoating” has resulted in significant improvements in several key performance aspects of the new product.
TRUNNANO General Manager Roger Luo stated, “We are always committed to solving practical problems in industry through cutting-edge innovations in materials science. The launch of this nano-boron nitride coated silicon carbide-silicon nitride composite crucible solves the problems of ordinary silicon carbide crucibles easily sticking to the melt and having weak alkali resistance, as well as the problems of mullite crucibles having poor alkali and corrosion resistance.” Roger added, “We will also be showcasing this product at The 18th China International Exhibition for Advanced Ceramics 2026 in Shanghai, China, at booth H022 in Hall 1.”
Performance Comparison of TRUNNANO's New Composite Crucible with Traditional Silicon Carbide and Mullite Crucibles:
Application Performance: High-end Manufacturing Industry
In the field of lithium-ion battery materials, during the high-temperature sintering of cathode materials (such as high-nickel ternary materials), the crucible's excellent alkali resistance and high thermal conductivity ensure the uniformity and crystallinity of the material composition, while avoiding the introduction of impurities, thus contributing to improved battery energy density and cycle stability.
In the preparation of magnetic materials, especially in the melting and heat treatment of rare-earth permanent magnets such as NdFeB, the crucible's anti-sticking properties reduce the adhesion loss of rare-earth metals, while its high thermal conductivity helps control the cooling rate and optimize the magnet's microstructure, thereby improving the consistency of magnetic properties.
Furthermore, in industries such as electronic ceramics, special alloys, and photovoltaic silicon purification, this crucible also demonstrates broad application potential, providing customers with a cleaner, more efficient, and more economical production tool option.
Roger Luo further emphasized, “TRUNNANO will continue to increase its R&D investment, focusing on the application of advanced ceramics in extreme environments, developing more high-performance, customized product series, and exploring the infinite possibilities of material innovation with global partners.”
About TRUNNANO
TRUNNANO is a high-tech enterprise specializing in the development, manufacturing, and commercialization of nanomaterials, high-end ceramic products, and other high-purity chemicals. Driven by technological innovation, its products are widely used in various industrial fields. With its superior product quality and professional technical service, TRUNNANO has earned the trust of customers worldwide. Under the leadership of CEO Roger Luo, TRUNNANO is committed to promoting the advancement of materials science through continuous technological breakthroughs and contributing to global industrial development.
Media Contact: Roger Luo
Email: nanotrun@yahoo.com / sales8@nanotrun.com
Phone/WhatsApp: 0086 18837956556
Photos accompanying this announcement are available at https://www.globenewswire.com/NewsRoom/AttachmentNg/0ffa76dc-fe73-4f2a-b2aa-2105413bf6ec
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SiC-Si3N4 crucible with nano BN coating
Nano BN coated SiC-Si3N4 crucible. Exceptional thermal shock resistance, non-wetting properties, and longevity for demanding high-purity metal and alloy melting applications.
Performance Comparison of TRUNNANO's New Composite Crucible with Traditional Silicon Carbide and Mullite Crucibles
TRUNNANO's composite crucible outperforms traditional silicon carbide and mullite models, delivering superior thermal shock resistance, longevity, and energy efficiency in demanding high-temperature applications.
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