Metal nitrides are attracting renewed attention because they combine strong bonds, high chemical stability and useful electronic properties—features that underpin technologies ranging from light-emitting devices and high-power electronics to hard coatings and biomedical implants. Yet producing crystalline metal nitride nanomaterials is often difficult: early transition-metal nitrides bind strongly to nitrogen, and that covalency typically demands extreme temperatures. Conventional fabrication methods—solid-state nitridation, supercritical ammonia routes, molecular-beam epitaxy, reactive sputtering and chemical vapour deposition—tend to be energy-intensive and sometimes incompatible with scalable, solution-based processing.
A new study reports a strategy to bypass this bottleneck by using a molten-salt environment and pressurized ammonia. The approach starts from metal halides, which are dissolved or dispersed in inorganic molten salts. Ammonia is introduced in a way that exploits elevated pressure, enabling it to dissolve and react effectively without requiring the solvent-stability limits that typically constrain “wet-chemistry” synthesis. By tuning ammonia pressure, the researchers control key reaction conditions that govern nucleation and growth of nitride phases.
The chemical logic is straightforward but powerful: molten salts act as a reactive medium that can stabilize metal-containing species, while ammonia serves as the nitrogen source. Pressure helps shift ammonia’s availability and reactivity, promoting metal–nitrogen bond formation and enabling formation of ultrahigh-temperature-resembling products under comparatively manageable conditions. The result is colloidal nanocrystals with well-defined metal nitride compositions.
Using this framework, the team synthesizes a broad range of refractory nanocrystals, including colloidal TiN, VN and GaN, as well as NbN, Mo₂N, Ta₃N₅ and TaN. They also demonstrate tungsten nitride nanocrystals (W₂N) and extend the method to ternary systems such as Ti₁₋ₓVₓN. This breadth is crucial because refractory nitrides vary in bonding character and reaction kinetics, often making them hard to obtain by one-size-fits-all methods.
Importantly, the study highlights ammonia pressure as a controllable “knob” that regulates synthesis outcomes. Adjusting pressure can influence how much reactive nitrogen is available and how rapidly metal–nitrogen networks form, which in turn affects phase purity and particle formation. In practical terms, this means that synthesis can be optimized toward desired stoichiometry and nanocrystal characteristics rather than relying on trial-and-error temperature extremes.
Together, the work reframes solution synthesis for materials once thought to be too refractory for colloidal chemistry. If the method can be adapted to additional compositions and scaled reliably, it could accelerate access to nitride nanocrystals for catalysis, electronics and emerging energy applications where solution processability is a major advantage.
Subject of Research: Ammonia pressure–controlled synthesis of colloidal refractory metal nitride nanocrystals in molten salts
Article Title: Ammonia pressure controls colloidal metal nitride synthesis in molten salts
Article References: Lin, R., Khokhar, V., Jiang, N. et al. Nature (2026). https://doi.org/10.1038/s41586-026-10801-3
Image Credits: AI Generated
DOI: https://doi.org/10.1038/s41586-026-10801-3
Keywords: metal nitrides; colloidal nanocrystals; molten salts; ammonia pressure; refractory materials; TiN; VN; GaN; TaN; catalysis

