Enhancement of Conformality of Silicon Nitride Thin Films by ABC‐Type Atomic Layer Deposition-Reference-Cited by-同舟云学术

Enhancement of Conformality of Silicon Nitride Thin Films by ABC‐Type Atomic Layer Deposition

Published:2023-12-18 Issue: Volume: Page:
ISSN:2199-160X
Container-title:Advanced Electronic Materials
language:en
Short-container-title:Adv Elect Materials

Author:

Kim Jiwon¹,Yeon Changbong²^ORCID,Cho Deok‐Hyun²,Jung Jaesun²,Shong Bonggeun¹^ORCID

Affiliation:

1. Department of Chemical Engineering Hongik University Mapo‐gu Seoul 04066 South Korea

2. Thin Film Material Development Team Soulbrain Co. Gongju‐si Chungcheongnam‐do 32598 South Korea

Abstract

AbstractAtomic layer deposition (ALD) is utilized for the fabrication of miniaturized electronic devices with nanometer‐scale features. However, the conventional ALD process on high‐aspect‐ratio (HAR) substrates often results in the deposition of thin films with suboptimal conformality over the depth of the trench structures. This study introduces an ABC‐type ALD of silicon nitride (SiNx) employing vapor‐deliverable tert‐butyl chloride (TBC) as a surface inhibitor. Herein, density functional theory (DFT) calculations elucidate the surface reaction mechanisms, confirming the inhibition of the Si precursor by the t‐butyl moiety. Notably, the ABC‐type ALD exhibits reduced growth per cycle relative to the conventional process while avoiding detectable carbon contamination in the SiNx thin films. Applying this process to substrates with trench structures revealed a substantial improvement in conformality following the introduction of TBC. Furthermore, the step coverage of the deposited SiNx can be modulated by adjusting TBC exposure, enabling greater film thickness at the bottom than that at the top of the trench. The proposed method of modulating ALD processes holds potential for the high‐volume manufacturing of semiconductor devices with HAR structures.

Funder

Ministry of Trade, Industry and Energy

Publisher

Wiley

Subject

Electronic, Optical and Magnetic Materials

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1002/aelm.202300722

Reference73 articles.

1. The future transistors

2. N.Chandrasekaran N.Ramaswamy C.Mouli In2020 IEEE Int. Electron Devices Meeting (IEDM) IEEE NewYork2020 10.1.1‐10.1.8.

3. 3-D NAND Technology Achievements and Future Scaling Perspectives

4. S.Subramanian M.Hosseini T.Chiarella S.Sarkar P.Schuddinck B. T.Chan D.Radisic G.Mannaert A.Hikavyy E.Rosseel F.Sebaai A.Peter T.Hopf P.Morin S.Wang K.Devriendt D.Batuk G. T.Martinez A.Veloso E. D.Litta S.Baudot Y. K.Siew X.Zhou B.Briggs E.Capogreco J.Hung R.Koret A.Spessot J.Ryckaert S.Demuynck et al. In2020 IEEE Symp. on VLSI Technology IEEE NewYork2020 1.

5. J. W.Han S. H.Park M. Y.Jeong K. S.Lee K. N.Kim H. J.Kim J. C.Shin S. M.Park S. H.Shin S. W.Park K. S.Lee J. H.Lee S. H.Kim B. C.Kim M. H.Jung I. Y.Yoon H.Kim S. U.Jang K. J.Park Y. K.Kim I. G.Kim J. H.Oh S. Y.Han B. S.Kim B. J.Kuh J. M.Park In2023 IEEE Symp. on VLSI Technology and Circuits (VLSI Technology and Circuits) IEEE NewYork2023 pp.1–2.