Mechanical shock-induced self-propagating exothermic reaction in Ti/Si multilayer nanofilms for low-power reactive bonding

Kuntani, Yasuhiro; Goto, Daiki; Maekawa, Kana; Kanetsuki, Shunsuke; Miyake, Shugo; Namazu, Takahiro

doi:10.35848/1347-4065/ab827f

Jpn. J. Appl. Phys.

2020

DOI: 10.35848/1347-4065/ab827f

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Mechanical shock-induced self-propagating exothermic reaction in Ti/Si multilayer nanofilms for low-power reactive bonding

Yasuhiro Kuntani¹,

Daiki Goto²,

Kana Maekawa³

et al.

Abstract: In this study, we describe the development of a new solder bonding technique using a Ti/Si multilayer film, which can be conducted by mechanical shock only. A Ti/Si multilayer film is a self-propagating exothermic reactive material that can be ignited by applying both mechanical and electrical shocks (e.g. a spark in the latter case). The influence of bilayer thickness on film ignition was investigated by means of mechanical impact testing. The threshold energy for the exothermic reaction gradually decreased w… Show more

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Cited by 6 publications

References 31 publications

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Mechanical Ignition of Al/Ni Reactive Multilayer Systems: Influence of Impacting Material, Its Properties, and Geometric Characteristics

Graske,

Sauni Camposano,

Vardo

et al. 2024

Adv Eng Mater

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Al/Ni reactive multilayer systems (RMS) with a bilayer thickness of Λ=50nm and total thickness th=5μm on a SiO2 substrate exhibit a self‐propagating reaction after ignition. A common method to initiate the self‐propagating reaction is by electric spark ignition. In this work, RMS are ignited by a mechanical impact using various materials with indeterminate geometries to investigate the basic mechanisms. SiO2, glass, PMMA and resin‐bonded SiC particles are used as impacting material with different geometrical impact areas. The used materials are placed on top of the RMS and a mechanical impulse is applied. The ignition behavior of the RMS is subsequently evaluated and classified. Additionally, the impacted RMS are examined by microscopy to reveal the damage pattern. By correlating particle size and spacing of the penetrating materials, an ignition threshold can be established. Moreover, the results demonstrate that the energy input threshold can be reduced through a strategic distribution of particles within the impacting and penetrating geometry. This provides valuable insights into the mechanical ignition fundamental and support future applications of mechanical ignition of RMS.This article is protected by copyright. All rights reserved.

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Mechanical Ignition of Al/Ni Reactive Multilayer Systems: Influence of Impacting Material, Its Properties, and Geometric Characteristics

Graske,

Sauni Camposano,

Vardo

et al. 2024

Adv Eng Mater

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Deformation mode dependence of an exothermic chemical reaction in Ti/Si multilayered nanofilms

Hirakata

Shiraishi

Shimada

2020

Materials Science and Engineering: A

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Influence of Zeta potential on pore arrangement in porous oxide particles produced using ultrasonic atomization method

Kumakiri¹,

Shindo²,

Namazu³

2021

Jpn. J. Appl. Phys.

Self Cite

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This paper describes the influence of Zeta potential on pore arrangement in porous silica and alumina particles. The ultrasonic atomization method is utilized to produce silica or alumina porous particles from the slurry including the oxide nanoparticles and polystyrene latex (PSL) particles. The whole particle shape and pore arrangement are determined by the combination of the sign of Zeta potential between the oxide nanoparticles and PSL particles as well as the mixture ratio of the oxide to PSL. The mechanism is discussed through observation with cross-sectional scanning electron microscopy.

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Mechanical shock-induced self-propagating exothermic reaction in Ti/Si multilayer nanofilms for low-power reactive bonding

Cited by 6 publications

References 31 publications

Mechanical Ignition of Al/Ni Reactive Multilayer Systems: Influence of Impacting Material, Its Properties, and Geometric Characteristics

Mechanical Ignition of Al/Ni Reactive Multilayer Systems: Influence of Impacting Material, Its Properties, and Geometric Characteristics

Deformation mode dependence of an exothermic chemical reaction in Ti/Si multilayered nanofilms

Influence of Zeta potential on pore arrangement in porous oxide particles produced using ultrasonic atomization method

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