Investigation of a modified NPN transistor in CMOS structures for enhanced ESD-induced latch-up protection
Integrated circuits (ICs) are vital in modern electronics, including everyday life, industrial manufacturing and military equipment. Reducing transistor size and improving performance requires shrinking the gate oxide layer, which makes ICs more fragile and vulnerable to electrostatic discharg...
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| Format: | Thesis-Master by Coursework |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/172084 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Integrated circuits (ICs) are vital in modern electronics, including everyday life, industrial
manufacturing and military equipment. Reducing transistor size and improving performance
requires shrinking the gate oxide layer, which makes ICs more fragile and vulnerable to electrostatic
discharge (ESD). ESD can occur at every stage of IC production, making ESD protection critical
to improving IC reliability. This paper presents a systematic approach to ESD protection for full chip network design and a design window for effective ESD operation. Four basic requirements for
ESD protection devices are discussed, namely robustness, sensitivity, effectiveness and
transparency. Various device architectures are described, including diodes, bipolar junction
transistors (BJTs), grounded gate NMOS and silicon-controlled rectifiers, and their compatibility
with chip fabrication processes. Three ESD discharge models, namely the machine model, the
human model and the charged device model, are commonly used to test ESD protection
performance, while transmission line pulse (TLP) testing is widely used to assess the effectiveness
of ESD protected devices. This Dissertation also elucidates the mechanisms behind avalanche and
thermal breakdown and how they relate to the important ESD protection parameters of trigger point
voltage, sustaining voltage and failure current. Although this Dissertation focuses on High Voltage
NPN (HVNPN) devices, the models and explanations presented are useful for the design of all ESD
protection devices. In summary, this Dissertation provides a comprehensive understanding of ESD
protection mechanisms and the importance of taking robustness into account when designing ESD
protection devices. |
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