Seth Prejean scite author profile

Seth Prejean

3Publications

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Advanced Micro Devices (Canada), Advanced Micro Devices (United States)

Publications

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Failure Analysis Turned Upside Down: A Review of Backside Analysis Techniques

Bruce

Prejean

et al. 2003

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This article provides a high-level review of the tools and techniques used for backside analysis. It discusses the use of laser scanning and conventional microscopy, liquid and solid immersion lenses, photon emission microscopy (PEM), and laser-based fault isolation methods with emphasis on light-induced voltage alteration (LIVA). It explains how laser voltage probing is used for backside waveform acquisition and describes backside sample preparation and deprocessing techniques including parallel polishing and milling, laser chemical etching, and FIB circuit edit and modification.

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CMOS Backside Deprocessing With TMAH / IPA as a Sample Preparation Procedure for Failure Analysis

Prejean

Bruce

Burke

2002

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This paper is about a sample preparation technique that is based on a previous research publication1. The technique was initially used for the investigation of salicide formation for CMOS process development. The initial results were very good and proved to be helpful with root cause failure analysis. Once the technique proved to be a viable failure analysis (FA) tool, a research team was formed to continue the development. This paper is written in conjunction with this team. The team is presently focused on developing a repeatable and reliable methodology of deprocessing CMOS devices from the backside. The team is also developing a methodology for post deprocessing analysis once the backside silicon is removed. The research that is presented here focuses on packaged as well as unpackaged devices. Etch rates and selectivity of tetramethylammoniumhydroxide (TMAH) is investigated along with temperature dependencies. Package material and chemical interference issues were discovered and remedied with special preparation techniques. Post deprocessing analysis is considered and many ideas are proposed as part of future research.

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Backside Deprocessing of CMOS SOI Devices for Physical Defect and Failure Analysis

Prejean

Shannon

2003

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This paper describes improvements in backside deprocessing of CMOS (Complimentary Metal Oxide Semiconductor) SOI (Silicon On Insulator) integrated circuits. The deprocessing techniques described here have been adapted from a previous research publication on backside deprocessing of bulk CMOS integrated circuits [1]. The focus of these improvements was to provide a repeatable and reliable methodology of deprocessing CMOS devices from the backside. We describe a repeatable and efficient technique to deprocess flip chip packaged devices and unpackaged die from the backside. While this technique has been demonstrated on SOI and bulk devices, this paper will focus on the latest SOI technology. The technique is useful for quick and easy access to the transistor level while preserving the metal interconnects for further analysis. It is also useful for deprocessing already thinned or polished die without removing them from the package. Removing a thin die from a package is very difficult and could potentially damage the device. This is especially beneficial when performing physical failure analysis of samples that have been back thinned for the purpose of fault isolation and defect localization techniques such as: LIVA (Laser Induced Voltage Alteration), TIVA (Thermally Induce Voltage Alteration), SDL [2] (Soft Defect Localization), and TRE (Time Resolved Emission) analysis. An important fundamental advantage of deprocessing SOI devices is that the BOX (Buried Oxide) layer acts as a chemical etch stop when etching the backside or bulk silicon. This leaves the transistor active silicon intact for analysis. Further delayering allows for the inspection of the active silicon, gate oxide, silicide, spacers, and poly. After deprocessing the transistor level, the metal layers are still intact and, in most cases, still electrically connected to the outside world. This can provide additional failure analysis opportunities.

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Seth Prejean

Failure Analysis Turned Upside Down: A Review of Backside Analysis Techniques

CMOS Backside Deprocessing With TMAH / IPA as a Sample Preparation Procedure for Failure Analysis

Backside Deprocessing of CMOS SOI Devices for Physical Defect and Failure Analysis

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