Exotic Inverse Kinetic Isotopic Effect in the Thermal Decomposition of Levitated Aluminum Iodate Hexahydrate Particles

Aluminum iodate hexahydrate ([Al­(H2O)6]­(IO3)3(HIO3)2; AIH) represents a novel, oxidizing material for energetic applications. Recently, AIH was synthesized to replace the aluminum oxide passivation layer of aluminum nanoenergetic materials (ALNEM). The design of reactive coatings for ALNEM-doped h...

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Bibliographic Details
Published in:The journal of physical chemistry letters 2023-03, Vol.14 (11), p.2722-2730
Main Authors: Rizzo, Grace L., Biswas, Souvick, Antonov, Ivan, Miller, Kelsea K., Pantoya, Michelle L., Kaiser, Ralf I.
Format: Article
Language:English
Subjects:
Chemistry
Materials Science
Physical Insights into Chemistry, Catalysis, and Interfaces
Physics
Science & Technology - Other Topics
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Summary:Aluminum iodate hexahydrate ([Al­(H2O)6]­(IO3)3(HIO3)2; AIH) represents a novel, oxidizing material for energetic applications. Recently, AIH was synthesized to replace the aluminum oxide passivation layer of aluminum nanoenergetic materials (ALNEM). The design of reactive coatings for ALNEM-doped hydrocarbon fuels in propulsion systems requires fundamental insights of the elementary steps of the decomposition of AIH. Here, through the levitation of single AIH particles in an ultrasonic field, we reveal a three-stage decomposition mechanism initiated by loss of water (H2O) accompanied by an unconventional inverse isotopic effect and ultimate breakdown of AIH into gaseous elements (iodine and oxygen). Hence, AIH coating on aluminum nanoparticles replacing the oxide layer would provide a critical supply of oxygen in direct contact with the metal surface thus enhancing reactivity and reducing ignition delays, further eliminating decades-old obstacles of passivation layers on nanoenergetic materials. These findings demonstrate the potential of AIH to aid in the development of next-generation propulsion systems.
ISSN:1948-7185
1948-7185
DOI:10.1021/acs.jpclett.3c00273