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The Effects of Friction and Temperature in the Chemical–Mechanical Planarization Process

Chemical–mechanical planarization (CMP) represents the preferred technology in which both chemical and mechanical interactions are combined to achieve global planarization/polishing of wafer surfaces (wafer patterns from metal with a selective layer, in this paper). CMP is a complex process of mater...

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Detalles Bibliográficos
Autores principales: Ilie, Filip, Minea, Ileana-Liliana, Cotici, Constantin Daniel, Hristache, Andrei-Florin
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10095230/
https://www.ncbi.nlm.nih.gov/pubmed/37048844
http://dx.doi.org/10.3390/ma16072550
Descripción
Sumario:Chemical–mechanical planarization (CMP) represents the preferred technology in which both chemical and mechanical interactions are combined to achieve global planarization/polishing of wafer surfaces (wafer patterns from metal with a selective layer, in this paper). CMP is a complex process of material removal process by friction, which interferes with numerous mechanical and chemical parameters. Compared with chemical parameters, mechanical parameters have a greater influence on the material removal rate (MRR). The mechanical parameters manifest by friction force (F(f)) and heat generated by friction in the CMP process. The F(f) can be estimated by its monitoring in the CMP process, and process temperature is obtained with help of an infrared rays (IR) sensor. Both the F(f) and the MRR increase by introducing colloidal silica (SiO(2)) as an abrasive into the selective layer CMP slurry. The calculated wafer non-uniformity (WNU) was correlated with the friction coefficient (COF). The control of F(f) and of the slurry stability is important to maintain a good quality of planarization with optimal results, because F(f) participates in mechanical abrasion, and large F(f) may generate defects on the wafer surface. Additionally, the temperature generated by the F(f) increases as the SiO(2) concentration increases. The MRR of the selective layer into the CMP slurry showed a non-linear (Prestonian) behavior, useful not only to improve the planarization level but to improve its non-uniformity due to the various pressure distributions. The evaluation of the F(f) allowed the calculation of the friction energy (E(f)) to highlight the chemical contribution in selective-layer CMP, from which it derived an empirical model for the material removal amount (MRA) and validated by the CMP results. With the addition of abrasive nanoparticles into the CMP slurry, their concentration increased and the MRA of the selective layer improved; F(f) and MRR can be increased due to the number of chemisorbed active abrasive nanoparticles by the selective layer. Therefore, a single abrasive was considered to better understand the effect of SiO(2) concentration as an abrasive and of the MRR features depending on abrasive nanoparticle concentration. This paper highlights the correlation between friction and temperature of the SiO(2) slurry with CMP results, useful to examine the temperature distribution. All the MRRs depending on E(f) after planarization with various SiO(2) concentrations had a non-linear characteristic. The obtained results can help in developing a CMP process more effectively.