Dual near-zero-thickness sealing for the strengthening of cobalt thin films and nanolines for future interconnect applications

Graphical abstract showing the samples of thin Co and Co(MnO) films and nano-lines (left column), the STEM images of the samples of thin Co and Co(MnO) films after annealing (middle column), and the schematics of their microstructure changes (bottom, right column), along with electromigration testin...

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Published in	Applied surface science Vol. 609; p. 155387
Main Authors	Chen, Giin-Shan, Pan, Yen-Chang, Chen, Wei-Chun, Hsiao, Chien-Nan, Chang, Chin-Chia, Cheng, Yi-Lung, Fang, Jau-Shiung
Format	Journal Article
Language	English
Published	Elsevier B.V 30.01.2023
Subjects	Cobalt film Electroless plating Interconnect Reliability Self-assembled monolayer Self-forming barrier Interconnect Self-assembled monolayer Self-forming barrier Cobalt film Reliability Electroless plating
Online Access	Get full text
ISSN	0169-4332
DOI	10.1016/j.apsusc.2022.155387

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Abstract	Graphical abstract showing the samples of thin Co and Co(MnO) films and nano-lines (left column), the STEM images of the samples of thin Co and Co(MnO) films after annealing (middle column), and the schematics of their microstructure changes (bottom, right column), along with electromigration testing curves of Co and Co(MnO) nano-lines (top, right column). [Display omitted] •Self-assembled monolayers (SAMs) and self-forming barriers are surface-functional coatings.•An all-wet electroless process is used to seal Co films and nanolines with a 1-nm-thin SAM and 0.1% of MnO.•The dual-sealing enhances thermal stability of the Co films on NiSi/Si substrates.•The dual-sealing enhances electromigration reliability of Co nanolines.•Mechanism of the enhancements is elucidated by electron microscopy and analysis. Self-assembled monolayers (SAMs) and self-forming barriers are molecularly thin surface functional coatings and could be a viable option for enhancing the reliability of thin Co films and Co nanolines. Here, we present an all-wet metallization process which enables electroless-plated Co films to be protected by an amino-based SAM coating and self-forming manganese monoxide (MnO) alloy. Co or lightly alloyed (0.1 % MnO) Co was deposited on the SAM barrier on NiSi/Si, denoted Co [or Co(MnO)]/SAM/NiSi/Si. The two types of samples were annealed to some extent for the evaluation of their thermal stability, primarily using (scanning) transmission electron microscopy [S(TEM)]. For the Co/SAM/NiSi/Si after annealing, the SAM barrier retains its integrity, but it alone is insufficient to prevent interface diffusion and chemical reactions of Co and Si. A three-nanolayered structure, CoSi2(CoSi2−x)/CoSi2/Co2Si, is formed beneath the SAM; faceted CoSi precipitates with a three-domain structure are found above the SAM. By contrast, the Co(MnO)/SAM/NiSI/Si is stable under identical annealing without interface diffusion and chemical reactions. Significant enhancement of electromigration reliability of Co nanolines by the tiny MnO alloying is confirmed by activation energy measurements, and the mechanism for the enhancement is thoroughly elucidated by S(TEM).
AbstractList	Graphical abstract showing the samples of thin Co and Co(MnO) films and nano-lines (left column), the STEM images of the samples of thin Co and Co(MnO) films after annealing (middle column), and the schematics of their microstructure changes (bottom, right column), along with electromigration testing curves of Co and Co(MnO) nano-lines (top, right column). [Display omitted] •Self-assembled monolayers (SAMs) and self-forming barriers are surface-functional coatings.•An all-wet electroless process is used to seal Co films and nanolines with a 1-nm-thin SAM and 0.1% of MnO.•The dual-sealing enhances thermal stability of the Co films on NiSi/Si substrates.•The dual-sealing enhances electromigration reliability of Co nanolines.•Mechanism of the enhancements is elucidated by electron microscopy and analysis. Self-assembled monolayers (SAMs) and self-forming barriers are molecularly thin surface functional coatings and could be a viable option for enhancing the reliability of thin Co films and Co nanolines. Here, we present an all-wet metallization process which enables electroless-plated Co films to be protected by an amino-based SAM coating and self-forming manganese monoxide (MnO) alloy. Co or lightly alloyed (0.1 % MnO) Co was deposited on the SAM barrier on NiSi/Si, denoted Co [or Co(MnO)]/SAM/NiSi/Si. The two types of samples were annealed to some extent for the evaluation of their thermal stability, primarily using (scanning) transmission electron microscopy [S(TEM)]. For the Co/SAM/NiSi/Si after annealing, the SAM barrier retains its integrity, but it alone is insufficient to prevent interface diffusion and chemical reactions of Co and Si. A three-nanolayered structure, CoSi2(CoSi2−x)/CoSi2/Co2Si, is formed beneath the SAM; faceted CoSi precipitates with a three-domain structure are found above the SAM. By contrast, the Co(MnO)/SAM/NiSI/Si is stable under identical annealing without interface diffusion and chemical reactions. Significant enhancement of electromigration reliability of Co nanolines by the tiny MnO alloying is confirmed by activation energy measurements, and the mechanism for the enhancement is thoroughly elucidated by S(TEM).
ArticleNumber	155387
Author	Fang, Jau-Shiung Chen, Giin-Shan Chen, Wei-Chun Pan, Yen-Chang Chang, Chin-Chia Hsiao, Chien-Nan Cheng, Yi-Lung
Author_xml	– sequence: 1 givenname: Giin-Shan surname: Chen fullname: Chen, Giin-Shan email: gschen@fcu.edu.tw organization: Department of Materials Science and Engineering, Feng Chia University, 407 Taichung, Taiwan – sequence: 2 givenname: Yen-Chang surname: Pan fullname: Pan, Yen-Chang organization: Department of Materials Science and Engineering, Feng Chia University, 407 Taichung, Taiwan – sequence: 3 givenname: Wei-Chun surname: Chen fullname: Chen, Wei-Chun organization: Taiwan Instrument Research Institute, National Applied Research Laboratories, Hsinchu 300, Taiwan – sequence: 4 givenname: Chien-Nan surname: Hsiao fullname: Hsiao, Chien-Nan organization: Taiwan Instrument Research Institute, National Applied Research Laboratories, Hsinchu 300, Taiwan – sequence: 5 givenname: Chin-Chia surname: Chang fullname: Chang, Chin-Chia organization: Department of Materials Science and Engineering, Feng Chia University, 407 Taichung, Taiwan – sequence: 6 givenname: Yi-Lung surname: Cheng fullname: Cheng, Yi-Lung organization: Department of Electrical Engineering, National Chi-Nan University, 545 Nantou, Taiwan – sequence: 7 givenname: Jau-Shiung surname: Fang fullname: Fang, Jau-Shiung organization: Department of Materials Science and Engineering, National Formosa University, 632 Yunlin, Taiwan
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Keywords	Interconnect Self-assembled monolayer Self-forming barrier Cobalt film Reliability Electroless plating
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Snippet	Graphical abstract showing the samples of thin Co and Co(MnO) films and nano-lines (left column), the STEM images of the samples of thin Co and Co(MnO) films...
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SubjectTerms	Cobalt film Electroless plating Interconnect Reliability Self-assembled monolayer Self-forming barrier
Title	Dual near-zero-thickness sealing for the strengthening of cobalt thin films and nanolines for future interconnect applications
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