Plasma Etching Processes for CMOS Devices Realization
- 1st Edition - January 18, 2017
- Latest edition
- Editor: Nicolas Posseme
- Language: English
Plasma etching has long enabled the perpetuation of Moore's Law. Today, etch compensation helps to create devices that are smaller than 20 nm. But, with the constant downscaling in… Read more
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Description
Description
Plasma etching has long enabled the perpetuation of Moore's Law. Today, etch compensation helps to create devices that are smaller than 20 nm. But, with the constant downscaling in device dimensions and the emergence of complex 3D structures (like FinFet, Nanowire and stacked nanowire at longer term) and sub 20 nm devices, plasma etching requirements have become more and more stringent.Now more than ever, plasma etch technology is used to push the limits of semiconductor device fabrication into the nanoelectronics age. This will require improvement in plasma technology (plasma sources, chamber design, etc.), new chemistries (etch gases, flows, interactions with substrates, etc.) as well as a compatibility with new patterning techniques such as multiple patterning, EUV lithography, Direct Self Assembly, ebeam lithography or nanoimprint lithography.This book presents these etch challenges and associated solutions encountered throughout the years for transistor realization.
Key features
Key features
- Helps readers discover the master technology used to pattern complex structures involving various materials
- Explores the capabilities of cold plasmas to generate well controlled etched profiles and high etch selectivities between materials
- Teaches users how etch compensation helps to create devices that are smaller than 20 nm
Readership
Readership
Table of contents
Table of contents
1: CMOS Devices Through the Years
Abstract
1.1 Scaling law by Dennard
1.2 CMOS device improvement through the years
1.3 Summary
1.4 What is coming next?
2: Plasma Etching in Microelectronics
Abstract
2.1 Overview of plasmas and plasma etch tools
2.2 Plasma surface interactions during plasma etching
2.3 Patterns transfer by plasma etching
2.4 Conclusion
3: Patterning Challenges in Microelectronics
Abstract
3.1 Optical immersion lithography
3.2 Next-generation lithography
3.3 Conclusion
4: Plasma Etch Challenges for Gate Patterning
Abstract
4.1 pSi gate etching
4.2 Metal gate etching
4.3 Stopping on the gate oxide
4.4 High-k dielectric etching
4.5 Line width roughness transfer during gate patterning
4.6 Chamber wall consideration after gate patterning
4.7 Summary
Product details
Product details
- Edition: 1
- Latest edition
- Published: January 25, 2017
- Language: English
About the editor
About the editor
NP