High‐Temperature Oxidation‐Resistant Printed Copper Conductors

Saurabh Khuje; Firas Alshatnawi; Mohammed Alhendi; Jian Yu; Aaron Sheng; Yulong Huang; Cheng‐Gang Zhuang; Jason Armstrong; Chi Zhou; Mark Poliks; Shenqiang Ren

doi:10.1002/aelm.202200979

Advanced Electronic Materials (Mar 2023)

High‐Temperature Oxidation‐Resistant Printed Copper Conductors

Saurabh Khuje,
Firas Alshatnawi,
Mohammed Alhendi,
Jian Yu,
Aaron Sheng,
Yulong Huang,
Cheng‐Gang Zhuang,
Jason Armstrong,
Chi Zhou,
Mark Poliks,
Shenqiang Ren

Affiliations

Saurabh Khuje: Department of Mechanical and Aerospace Engineering University at Buffalo The State University of New York Buffalo New York 14260 United States
Firas Alshatnawi: Department of Systems Science and Industrial Engineering Binghamton University The State University of New York Binghamton New York 13902 United States
Mohammed Alhendi: Department of Systems Science and Industrial Engineering Binghamton University The State University of New York Binghamton New York 13902 United States
Jian Yu: Army Research Laboratory Aberdeen Proving Ground Maryland 21005 United States
Aaron Sheng: Department of Chemistry University at Buffalo The State University of New York Buffalo New York 14260 United States
Yulong Huang: Department of Mechanical and Aerospace Engineering University at Buffalo The State University of New York Buffalo New York 14260 United States
Cheng‐Gang Zhuang: Corning Research and Development Corporation New York 14830 United States
Jason Armstrong: Department of Mechanical and Aerospace Engineering University at Buffalo The State University of New York Buffalo New York 14260 United States
Chi Zhou: Department of Industrial and Systems Engineering The State University of New York at Buffalo Buffalo NY 14260 United States
Mark Poliks: Department of Systems Science and Industrial Engineering Binghamton University The State University of New York Binghamton New York 13902 United States
Shenqiang Ren: Department of Mechanical and Aerospace Engineering University at Buffalo The State University of New York Buffalo New York 14260 United States

DOI: https://doi.org/10.1002/aelm.202200979
Journal volume & issue: Vol. 9, no. 3
pp. n/a – n/a

Abstract

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Abstract Advanced materials, electrically conductive and oxidation resistant, are frontrunners for technological advancements in cutting‐edge high‐temperature electronics. Rational design and manufacturing of hierarchical material structures is indispensable to achieve such disparate functionalities. Here, high‐temperature copper–graphene conductors, through additive manufacturing, which prohibits oxygen adsorbates and serves as the barrier for oxygen migration to enable electric stability and reliability at high temperatures, are reported. The combination of graphene and alumina surface passivation enables the electric stability of copper–graphene under thermal impact above 1000 °C. The findings shown here, the synergistic combination of high conductivity and oxidation resistance, enunciate the passivation capabilities for additively manufactured flexible electronics operating under harsh conditions.

Published in Advanced Electronic Materials

ISSN: 2199-160X (Online)
Publisher: Wiley-VCH
Country of publisher: Germany
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Electric apparatus and materials. Electric circuits. Electric networks; Science: Physics
Website: https://onlinelibrary.wiley.com/journal/2199160x

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