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02-12-2019 | Electronic materials

Nanocatalyst-induced hydroxyl radical (^·OH) slurry for tungsten CMP for next-generation semiconductor processing

Authors: Maneesh Kumar Poddar, Heon-Yul Ryu, Nagendra Prasad Yerriboina, Yeon-Ah Jeong, Jung-Hwan Lee, Tae-Gon Kim, Jae-Hyun Kim, Jong-Dai Park, Min-Gun Lee, Chang-Yong Park, Seong-Jun Han, Jae-Gon Choi, Jin-Goo Park

Published in: Journal of Materials Science | Issue 8/2020

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Abstract

Chemical mechanical polishing (CMP) is one of the important steps that involves during fabrication of semiconductor devices. This research highlights the importance of tungsten (W) polishing slurries consisting of a novel nonionic, heat-activated FeSi nanocatalyst on the performance of W chemical mechanical polishing. The results obtained from the polishing data showed a higher W removal rate of 5910 Å/min with a slurry consisting of FeSi nanocatalyst at a polishing temperature of 80 °C. The increase in W polishing rate using FeSi slurry was explained on the basis of formation of a thicker oxide layer (WO₃) due to the interaction between the W surface and hydroxyl radicals (^·OH) generated via the reaction between FeSi and hydrogen peroxide at 80 °C. Higher ^·OH generation and increase in oxygen depth profile of W film were confirmed by UV–Vis spectrometer and AES analysis, respectively. Compared to Fe(NO₃)₃ catalyst, the slurry with FeSi showed a higher static etch rate at 80 °C. Potentiodynamic polarization results obtained using FeSi slurry showed thicker WO₃ passivation layer as compared to the slurry with Fe(NO₃)₃. The increase in the polishing rate of W CMP using slurry with FeSi nanocatalyst can be essentially attributed to the generation of much stronger oxidant ^·OH due to its increased catalytic effect at a high polishing temperature of 80 °C.

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Title: Nanocatalyst-induced hydroxyl radical (·OH) slurry for tungsten CMP for next-generation semiconductor processing
Authors: Maneesh Kumar Poddar
Heon-Yul Ryu
Nagendra Prasad Yerriboina
Yeon-Ah Jeong
Jung-Hwan Lee
Tae-Gon Kim
Jae-Hyun Kim
Jong-Dai Park
Min-Gun Lee
Chang-Yong Park
Seong-Jun Han
Jae-Gon Choi
Jin-Goo Park
Publication date: 02-12-2019
Publisher: Springer US
Published in: Journal of Materials Science / Issue 8/2020
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-019-04239-4

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