A SHORT REVIEW: THE EFFECT OF NANOMATERIALS FOR THERMAL DECOMPOSITION OF SOLID PROPELLANT OXIDIZER AP

Main Article Content

PRAGNESH DAVE
SHALINI CHATURVEDI
RIDDHI THAKKAR
RUKSANA SIRACH

Abstract

This review attempts to discuss data related to the work of kinds of literature on various nanomaterials such as ferrites, oxides, and chromates of transition metals which lead to gain prominent attention in the field of thermal decomposition of solid propellant oxidizer mainly ammonium perchlorate (AP).  The effect of catalysts like metal oxides, inorganic and organic compounds, etc., is discussed for the thermal decomposition of  ammonium perchlorate (AP). This study underscores the experimental effectiveness of these catalysts in the decomposition process of solid propellants which enhances fast decomposition through decreasing their exothermic peak temperature. Such kind of improvements in propellant oxidizer and binder fuel help to increase the efficiency of rocket missiles.

GRAPHICAL ABSTRACT

 This short review includes the discussion on thermolysis of propellant oxidizers and their composite solid propellants from the few prime lists of literature. This aims to understand the behavior of nanomaterials as a catalyst for the thermal decomposition of propellant oxidizer ammonium perchlorate. Ammonium perchlorate has a polyhedron-like shape that undergoes decomposition upon heating from room temperature to ~420 ℃ with gaseous by-products. In the presence of catalyst, the decomposition occurred at a lower temperature than the pure ammonium perchlorate. Thus, it can be used in the formulation of propulsion systems that mainly improve their burn rate ultimately helpful in rocketry.

GA.PNG

Keywords:
Nanomaterials, solid propellant oxidizer, thermal analysis, catalyst

Article Details

How to Cite
DAVE, P., CHATURVEDI, S., THAKKAR, R., & SIRACH, R. (2022). A SHORT REVIEW: THE EFFECT OF NANOMATERIALS FOR THERMAL DECOMPOSITION OF SOLID PROPELLANT OXIDIZER AP. Journal of Applied Chemical Science International, 13(4), 1-13. Retrieved from https://ikpresse.com/index.php/JACSI/article/view/7625
Section
Review Article

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