Characterization of shallow trench isolation CMP process and its application

Helen Li; ChunLei Zhang; JinBing Liu; ZhengFang Liu; Kuang Han Chen; Tamba Gbondo-Tugbawa; Hua Ding; Flora Li; Brian Lee; Aaron Gower-Hall; Yang-Chih Chiu

doi:10.1117/12.2219912

16 March 2016 Characterization of shallow trench isolation CMP process and its application

Helen Li, ChunLei Zhang, JinBing Liu, ZhengFang Liu, Kuang Han Chen, Tamba Gbondo-Tugbawa, Hua Ding, Flora Li, Brian Lee, Aaron Gower-Hall, Yang-Chih Chiu

Author Affiliations +

Proceedings Volume 9781, Design-Process-Technology Co-optimization for Manufacturability X; 978113 (2016) https://doi.org/10.1117/12.2219912
Event: SPIE Advanced Lithography, 2016, San Jose, California, United States

Abstract

Chemical mechanical polishing (CMP) has been a critical enabling technology in shallow trench isolation (STI), which is used in current integrated circuit fabrication process to accomplish device isolation. Excessive dishing and erosion in STI CMP processes, however, create device yield concerns. This paper proposes characterization and modeling techniques to address a variety of concerns in STI CMP. In the past, majority of CMP publications have been addressed on interconnect layers in backend- of-line (BEOL) process. However, the number of CMP steps in front-end-of-line (FEOL) has been increasing in more advanced process techniques like 3D-FinFET and replacement metal gate, as a results incoming topography induced by FEOL CMP steps can no longer be ignored as the topography accumulates and stacks up across multiple CMP steps and eventually propagating to BEOL layers. In this paper, we first discuss how to characterize and model STI CMP process. Once STI CMP model is developed, it can be used for screening design and detect possible manufacturing weak spots. We also work with process engineering team to establish hotspot criteria in terms of oxide dishing and nitride loss.

As process technologies move from planar transistor to 3D transistor like FinFet and multi-gate, it is important to accurately predict topography in FEOL CMP processes. These incoming topographies when stacked up can have huge impact in BEOL copper processes, where copper pooling becomes catastrophic yield loss. A calibration methodology to characterize STI CMP step is developed as shown in Figure 1; moreover, this STI CMP model is validated from silicon data collected from product chips not used in calibration stage. Additionally, wafer experimental setup and metrology plan are instrumental to an accurate model with high predictive power.

After a model is generated, spec limits and threshold to establish hotspots criteria can be defined. Such definition requires working closely with foundry process engineering and integration team and reviewing past failure analysis (FA) to come up a reasonable metrics. Conventionally, a potential STI weak point can be found when nitride residues remains in the active region after nitride strip. Another source of STI hotspots occurs when nitride erosion is too much, and active region can suffer severe damage.

Citation Download Citation

Helen Li, ChunLei Zhang, JinBing Liu, ZhengFang Liu, Kuang Han Chen, Tamba Gbondo-Tugbawa, Hua Ding, Flora Li, Brian Lee, Aaron Gower-Hall, and Yang-Chih Chiu "Characterization of shallow trench isolation CMP process and its application", Proc. SPIE 9781, Design-Process-Technology Co-optimization for Manufacturability X, 978113 (16 March 2016); https://doi.org/10.1117/12.2219912

ACCESS THE FULL ARTICLE

INSTITUTIONAL
Select your institution to access the SPIE Digital Library.

SELECT YOUR INSTITUTION

PERSONAL
Sign in with your SPIE account to access your personal subscriptions or to use specific features such as save to my library, sign up for alerts, save searches, etc.

PERSONAL SIGN IN

No SPIE Account? Create one

PURCHASE THIS CONTENT

SUBSCRIBE TO DIGITAL LIBRARY

50 downloads per 1-year subscription

Members: $195

Non-members: $335 ADD TO CART

25 downloads per 1 - year subscription

Members: $145

Non-members: $250 ADD TO CART

PURCHASE SINGLE ARTICLE

Includes PDF, HTML & Video, when available