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Specifications
| Appearance | Yellow powder |
| Purity (HPLC) | 95% min |
| Melting Point | 178 to 184 °C |
Transport Information
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Parameter |
Specification |
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UN Number |
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Class |
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Packing Group |
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H.S. Code |
2908999090 |
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Stability & Reactivity |
The product is chemically stable under standard ambient conditions. |
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Storage |
Store the container tightly closed in a dry, cool and well-ventilated place. Recommended storage temperature 2-8 deg.C. |
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Condition to Avoid |
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Package |
Applications
DIDNTB is primarily used as an intermediate in the synthesis of energetic materials, explosives, and propellants. It is employed in the production of high-energy compounds such as nitroaromatic derivatives, nitrogen-rich heterocycles, and polymer-bonded explosives. Beyond military and defense applications, DIDNTB is also utilized in specialized pyrotechnic formulations and in laboratory research for designing novel energetic materials. Its role in chemical research includes serving as a precursor for synthesizing compounds with enhanced detonation velocity, thermal stability, and controlled energy release, making it valuable for both practical applications and fundamental studies in energetic chemistry.
Benefits
DIDNTB offers high nitrogen content and a stable molecular framework, which enhances its energetic potential while allowing safer handling compared to some other high-energy intermediates. Its structure facilitates functionalization, enabling chemists to incorporate it into more complex energetic molecules or modify its properties for tailored performance. The compound supports predictable decomposition and controlled energy release, which is critical for optimizing safety and effectiveness in propellant and explosive formulations. Additionally, its versatility in synthetic chemistry allows the creation of advanced energetic polymers and hybrid materials, broadening its application in modern energetic research.
Conclusion
DIDNTB is a key intermediate in the development of high-performance energetic materials, providing both high energy potential and structural versatility. Its chemical stability, functional adaptability, and predictable reactivity make it indispensable in propellant, explosive, and pyrotechnic applications, while also supporting innovative research in nitrogen-rich energetic compounds and advanced material design.
