Environmentally Friendly Chemical Time Delays Based on Interrupted Reaction of Reactive Nanolaminates

Arlington, Shane Q.; Chen, Joey; Weihs, Timothy P.

doi:10.1021/acssuschemeng.0c06238

ACS Sustainable Chem. Eng.

2020

DOI: 10.1021/acssuschemeng.0c06238

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Environmentally Friendly Chemical Time Delays Based on Interrupted Reaction of Reactive Nanolaminates

Shane Q. Arlington

Joey Chen

Timothy P. Weihs

Abstract: Chemical time delays, devices that burn over specific times from under a millisecond to several seconds, are widely used in mining as well as civilian and military pyrotechnics and generally are composed of environmentally hazardous materials. Reactive nanolaminates are energetic materials composed of two or more reactants organized in an alternating layered structure, which may be fabricated with environmentally friendly components. Many traits of reactive nanolaminates are desirable for time delay applicatio… Show more

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Cited by 10 publications

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References 33 publications

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“…[29] Moreover, the nanocomposite powders do not include any of the environmentally hazardous materials which are frequently found in chemical time delays. As such, they show potential promise as an environmentallyfriendly alternative to current formulations, which is an area of active research, including form factors such as traditional powder-packed tubes, [30] reactive nanolaminate coated polymeric meshes, [31] as well as 3D printed filaments. [10] Explorations of printed chemical time delays are still quite limited, as most of the reactive materials printed to date either react too quickly or produce too much gas to be feasible in time delay applications.…”

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Multifunctional Reactive Nanocomposites via Direct Ink Writing

Arlington

Barron

DeLisio

et al. 2021

Adv Materials Technologies

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3D printing of reactive materials has, to date, primarily focused on controlling reaction velocities and energy release rates by printing novel architectures, which during reaction typically form gaseous and oxide powder products. The utility of printed reactive materials can be increased by designing the material such that its reaction produces both a controlled energy release and a functional product phase without gaseous products. Here, we report the direct ink writing of reactive materials composed of ternary nanocomposite powders that exhibit gasless, exceptionally low velocity reactions. The printed features can be patterned in arbitrary form factors and are brittle and electrically insulating as‐printed. Using a self‐propagating synthesis reaction, these features can be transformed into a mechanically robust, electrically conductive cermet that is capable of handling high currents. This study provides a new paradigm for printing multifunctional reactive materials in which both the energy release of the reaction, as well as the reaction products themselves, are useful for potential applications ranging from printed electronic devices to controlled, directed energy release.

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confidence: 99%

Multifunctional Reactive Nanocomposites via Direct Ink Writing

Arlington

Barron

DeLisio

et al. 2021

Adv Materials Technologies

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Influence of Increasing Density of Microstructures on the Self‐Propagating Reaction of Al/Ni Reactive Nanoscale Multilayers

Jaekel,

Riegler,

Sauni Camposano

et al. 2024

Adv Eng Mater

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Surface structuring methods are crucial in semiconductor manufacturing, as they enable the creation of intricate structures on the semiconductor surface, influencing the material’s electrical, mechanical, and chemical properties. This study employs one such structuring method known as reactive ion etching to create black Si structures on silicon substrates. After thermal oxidation, their influence on the reaction of Al/Ni nanoscale multilayers is. For this purpose, various densities of thermally oxidized black Si structures are investigated. It reveals distinct reactive behaviors without corresponding differences in energy release during differential scanning calorimetry measurements. Higher oxidized black Si structure densities result in elevated temperatures and faster reaction propagation, showing fewer defects and reduced layer connections in cross‐sectional analyses. The properties of the reactive multilayers on high structure density show the same performance as a reaction on flat thermal SiO2, causing delamination when exceeding 23 structures per µm2. Conversely, lower structure density ensures attachment of reactive multilayers to the substrate due to an increased number of defects, acting as predetermined breaking points for the AlNi alloy. By establishing the adhesion between the reacted multilayer and the substrate, surface structuring could lead to a potential increase in bond strength when using reactive multilayers for bonding.This article is protected by copyright. All rights reserved.

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Impact of Substrate Thickness and Surface Roughness on Al/Ni Multilayer Reaction Kinetics

Vardo,

Sauni Camposano,

Matthes

et al. 2024

Adv Eng Mater

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Reactive multilayers comprising alternating nanoscale layers of Al and Ni, exhibit potential across various applications, including localized heating for welding and joining. Control over reaction properties is pivotal for emerging applications, such as chemical time delays or neutralization of biological or chemical weapons. This research offers insights into the intricate interplay between substrate thickness, surface roughness, and the behavior of Al/Ni reactive multilayers, opening avenues for tailored applications in various domains. To observe this interplay, silica with various thicknesses from 0.4 µm to 1.6 µm was deposited on polished single crystalline Si and rough poly‐Si base substrates. Additionally, to analyze the impact of varying silica thickness along the sample length on reaction behavior, silica in step‐like shape was fabricated. Subsequently, Al/Ni multilayers with 5 µm total thickness and 20 or 50 nm bilayer periodicities were deposited. Reaction velocity and temperature were monitored with a high‐speed camera and pyrometer. Results indicate that silica thickness significantly affects self‐propagation in multilayers. The reaction is not self‐sustained for silica layers ≤ 0.4 µm, depending on bilayer periodicity and substrate roughness. The velocity increases or decreases based on the direction of reaction propagation, whether it moves upwards or downwards, in relation to the thickness of silica.This article is protected by copyright. All rights reserved.

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Environmentally Friendly Chemical Time Delays Based on Interrupted Reaction of Reactive Nanolaminates

Cited by 10 publications

References 33 publications

Multifunctional Reactive Nanocomposites via Direct Ink Writing

Multifunctional Reactive Nanocomposites via Direct Ink Writing

Influence of Increasing Density of Microstructures on the Self‐Propagating Reaction of Al/Ni Reactive Nanoscale Multilayers

Impact of Substrate Thickness and Surface Roughness on Al/Ni Multilayer Reaction Kinetics

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