Research output: Contribution to journal › Article › peer-review
Adhesion layer free room-temperature pulsed laser deposition of ultrathin Au films. / Kolosovsky, Danil A.; Zalyalov, Timur M.; Ponomarev, Sergei A. et al.
In: Applied Surface Science, Vol. 698, 163077, 30.07.2025.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Adhesion layer free room-temperature pulsed laser deposition of ultrathin Au films
AU - Kolosovsky, Danil A.
AU - Zalyalov, Timur M.
AU - Ponomarev, Sergei A.
AU - Miskiv, Nikolay B.
AU - Morozov, Alexey A.
AU - Shukhov, Yuri G.
AU - Shevlyagin, Alexander V.
AU - Kuchmizhak, Aleksandr A.
AU - Starinskiy, Sergey V.
N1 - The research is founded by the Russian Science Foundation, grant No 24-79-10070 (https://rscf.ru/project/24-79-10070/).
PY - 2025/7/30
Y1 - 2025/7/30
N2 - The unique optical and electrical characteristics of ultrathin Au films make them ideal for plasmonic, optoelectronic, and metamaterial applications. However, fabricating continuous Au films just a few nanometers thick remains highly challenging. Conventional approaches require adhesion layers, which increase optical losses and often fail to meet optoelectronic device specifications. Another technique involves cooling the substrate to cryogenic levels, but this can cause structural peeling and cracking. We suggest employing pulsed laser deposition in a low-pressure oxygen atmosphere to form ultrathin conductive Au films at room temperature without adhesion layers. In this process, the percolation threshold of Au films is reduced due to the high flux and low kinetic energy of arriving atoms. The direct simulation Monte Carlo shows that at an oxygen pressure of 10 Pa, the kinetic energy of deposited atoms drops roughly tenfold, and their flux decreases by 30 % compared to vacuum expansion. The resulting films are about 5 nm thick, exhibit 72 % average transmittance in visible light, and have a sheet resistance of 30 Ω/sq, yielding a high figure of merit of 0.55 Ω−1/10.
AB - The unique optical and electrical characteristics of ultrathin Au films make them ideal for plasmonic, optoelectronic, and metamaterial applications. However, fabricating continuous Au films just a few nanometers thick remains highly challenging. Conventional approaches require adhesion layers, which increase optical losses and often fail to meet optoelectronic device specifications. Another technique involves cooling the substrate to cryogenic levels, but this can cause structural peeling and cracking. We suggest employing pulsed laser deposition in a low-pressure oxygen atmosphere to form ultrathin conductive Au films at room temperature without adhesion layers. In this process, the percolation threshold of Au films is reduced due to the high flux and low kinetic energy of arriving atoms. The direct simulation Monte Carlo shows that at an oxygen pressure of 10 Pa, the kinetic energy of deposited atoms drops roughly tenfold, and their flux decreases by 30 % compared to vacuum expansion. The resulting films are about 5 nm thick, exhibit 72 % average transmittance in visible light, and have a sheet resistance of 30 Ω/sq, yielding a high figure of merit of 0.55 Ω−1/10.
KW - Conductivity
KW - Percolation
KW - Pulsed laser deposition
KW - Transparent conducting materials
KW - Ultrathin Au films
UR - https://www.mendeley.com/catalogue/4fe5ba65-7573-3435-b012-440aca62c189/
UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-105001714847&origin=inward&txGid=fc45ca9a3a40e94e58b6c3e1eed771c0
U2 - 10.1016/j.apsusc.2025.163077
DO - 10.1016/j.apsusc.2025.163077
M3 - Article
VL - 698
JO - Applied Surface Science
JF - Applied Surface Science
SN - 0169-4332
M1 - 163077
ER -
ID: 65193221