Transparent and conductive electrodes by large-scale nanostructuring of noble metal thin-films

Jes Linnet, Anders Runge Walther, Christian Wolff, Ole Albrektsen, N. Asger Mortensen, Jakob Kjelstrup-Hansen

Research output: Contribution to conference without publisher/journalPosterResearch


The widespread use of transparent conductive films in modern display and solar technologies calls for engineering solutions with tunable light transmission and electrical characteristics. Currently, considerable effort is put into the optimization of indium tin oxide, carbon nanotube-based, metal grid, and nano-wire thin-films [1]. The indium and carbon films do not match the chemical stability nor the electrical performance of the noble metals, and many metal films are not uniform in material distribution leading to significant surface roughness and randomized transmission haze. We demonstrate solution-processed masks for physical vapor-deposited metal electrodes consisting of hexagonally ordered aperture arrays with scalable aperture-size and spacing in an otherwise homogeneous noble metal thin-film. The fabricated electrodes are characterized optically and electrically by measuring transmittance and sheet resistance. The presented methods yield large-scale reproducible results. Experimentally realized thin-films show good agreement with finite-element method simulations and an analytical model of sheet resistance in thin-films with ordered apertures support the experimental results and serve to aid the design of highly transparent conductive films. A maximum Haacke number for these 33 nm thin-films, ΦH = 10.7×10−3Ω−1, equivalent to T≃80 % and Rsh≃10 Ω/sq, is extrapolated from the theoretical results. This corresponds to better electrical performance than carbon nanotube-based thin-films for equivalent optical transparency. Increased transparency may be realizable using thinner metal films trading off conductivity. Nevertheless, the findings of this article indicate that colloidal lithographic patterned transparent conductive films can serve as vital components in technologies with a demand for transparent electrodes with low sheet resistance.
Original languageEnglish
Publication date31. May 2018
Publication statusPublished - 31. May 2018
EventInternational Conference on Nanotechnology and Innovation in the Baltic Sea Region 2018 - University of Southern Denmark, Sønderborg, Denmark
Duration: 30. May 20181. Jun 2018


ConferenceInternational Conference on Nanotechnology and Innovation in the Baltic Sea Region 2018
LocationUniversity of Southern Denmark
Internet address


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