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Measuring electrical interfacial resistance of metal using modified transfer length method

Authors
Park, JunyoungPark, SangyeunKim, HyunwooYoo, HyeonnamKoo, DoheonKim, WondoNa, Hye SeokKim, JangwooPark, Hyun SungSo, Hongyun
Issue Date
Sep-2026
Publisher
ELSEVIER SCI LTD
Keywords
Electrical interface resistance; Transfer length method; Thin-film metal-metal interfaces; Contact resistivity
Citation
MEASUREMENT, v.286, pp 1 - 11
Pages
11
Indexed
SCIE
SCOPUS
Journal Title
MEASUREMENT
Volume
286
Start Page
1
End Page
11
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/219166
DOI
10.1016/j.measurement.2026.122344
ISSN
0263-2241
1873-412X
Abstract
With advances in device miniaturization, the electrical interfacial resistance (EIR) between contacting metals has become a critical factor governing the electrical and thermal performance of high-density electronic and display systems. However, accurate quantification of the EIR remains challenging because of its relatively small magnitude and strong dependence on process-induced interfacial characteristics. In this study, an EIR measurement methodology based on a modified transfer length method (TLM) and a metallic bilayer structure (MBS) is proposed, enabling the realistic replication of thin-film metal–metal interfaces formed during device fabrication. By developing an analytical model that integrates the resistance of the two contacting metals with a spatially distributed current transfer across the contact area, the EIR can be extracted as a function of the contact length. The model was validated through finite element simulations, which demonstrated excellent agreement over a wide range of normalized contact lengths. Additionally, the critical contact length required for reliable EIR measurements was determined. Experimentally, MBS was fabricated using a lift-off process, and the EIR was measured using a four-wire method. The extracted contact resistivity was on the order of 10−10 Ω·m2. The proposed approach provides a robust and quantitative framework for evaluating the EIR in realistic metal–metal interfaces, offering a practical utility and scalable framework for the design and optimization of next-generation microelectronic and display devices.
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