Single Device Characterization by Nano-probing to Identify Failure Root Cause

2005 ◽  
Author(s):  
Chao-Chi Wu ◽  
Jon C. Lee ◽  
Jung-Hsiang Chuang ◽  
Tsung-Te Li
Keyword(s):  
Failure Analysis ◽  
Success Rate ◽  
Failure Mechanism ◽  
Fault Isolation ◽  
Device Characterization ◽  
Nano Technology ◽  
Analysis Techniques ◽  
Root Cause ◽  
Visual Defects ◽  
Lower Success Rate

Abstract In general failure analysis cases, a less invasive fault isolation approach can be utilized to resolve a visual root cause defect. In the case of nano technology, visual defects are not readily resolved, due to an increase in non-visible defects. The nonvisible defects result in a lower success rate since conventional FA methods/tools are not efficient in identifying the failure root cause. For the advanced nanometer process, this phenomenon is becoming more common; therefore the utilization of advanced techniques are required to get more evidence to resolve the failure mechanism. The use of nanoprobe technology enables advanced device characterization h order to obtain more clues to the possible failure mechanism before utilizing the traditional physical failure analysis techniques.

An Application of Breakthrough Failure Analysis Techniques in Eliminating Silicon Dislocation Problem in Sub-Micron CMOS Devices

1997 ◽  
Author(s):  
E. H. Yeoh ◽  
W. M. Mak ◽  
H. C. Lock ◽  
S. K. Sim ◽  
C. C. Ooi ◽  
...  
Keyword(s):  
Failure Analysis ◽  
Failure Mechanism ◽  
Packing Density ◽  
Failure Mechanisms ◽  
Potential Solution ◽  
Critical Dimensions ◽  
Functional Failure ◽  
Analysis Techniques ◽  
Root Cause ◽  
First Time

Abstract As device interconnect layers increase and transistor critical dimensions decrease below sub-micron to cater for higher speed and higher packing density, various new and subtle failure mechanisms have emerged and are becoming increasingly prevalent. Silicon dislocation is a new failure mechanism that falls in this category and was for the first time, uncovered in submicron multilayered CMOS devices. This mechanism was responsible for a systematic yield problem; identified as the 'centre GFA wafer' functional failure problem. In this paper, several breakthrough failure analysis techniques used to narrow down and identify this new mechanism will be presented. Root cause determination and potential solution to this problem will also be discussed.

Nanoprobing as an Essential and Fast Methodology in Identification of Failure’s Root Cause for Advanced Technology

2013 ◽  
Author(s):  
Yinzhe Ma ◽  
Chong Khiam Oh ◽  
Ohnmar Nyi ◽  
Chuan Zhang ◽  
Donald Nedeau ◽  
...  
Keyword(s):  
Failure Analysis ◽  
Success Rate ◽  
Failure Mechanism ◽  
Turnaround Time ◽  
Advanced Technology ◽  
Electrical Behavior ◽  
Root Cause ◽  
Front End

Abstract This paper highlights the use of nanoprobing as a crucial and fast methodology for failure analysis (FA) in sub 20nm with an improved semi-auto nanoprobing system. Nanoprobing has the capability to localize as well as characterize the electrical behavior of the malfunctioning device for a better understanding of the failure mechanism. It provides a valuable guide to choose a proper physical FA technique to identify the root cause of the failure. This established methodology helps to accelerate the FA turnaround time and improve the success rate. Its application to a few of the front end of line and one back end of line issues is highlighted in the paper.

Efficient Fault Isolation and Failure Analysis Methods to Root Cause Defects in Microprocessors

2019 ◽  
Author(s):  
Hasan Faraby ◽  
Tristan Deborde ◽  
Martin von Haartman
Keyword(s):  
Failure Analysis ◽  
Success Rate ◽  
State Of The Art ◽  
Fault Isolation ◽  
High Success Rate ◽  
Electrical Isolation ◽  
Root Cause ◽  
Isolation Techniques ◽  
Analysis Methods

Abstract This paper analyzes the through-put time and output of fault isolation and failure analysis (FI/FA) flows on state-of-the-art microprocessors. An average reduction in through-put time of 40% was demonstrated with a shortened FI/FA flow while still maintaining a high success rate. The direct FA/nano-probing flow which was utilized by up to around 90% of the fail cases omitted the optical fault isolation step and instead expanded the use of plasma FIB, nano-probing and electrical isolation techniques (such as diagnosis tools). The end result is shorter through-put time and higher FI/FA volume which is important in order to achieve a faster production ramp. In the paper two cases studies are presented to demonstrate the new efficient FI/FA techniques.

Vdd Leakage Analysis by a Combination of Various Failure Analysis Techniques

2008 ◽  
Author(s):  
Z. G. Song ◽  
S. B. Ippolito ◽  
P. J. McGinnis ◽  
A. Shore ◽  
B. Paulucci ◽  
...  
Keyword(s):  
Failure Analysis ◽  
Hot Spot ◽  
Fault Isolation ◽  
Physical Analysis ◽  
Analysis Techniques ◽  
Root Cause ◽  
Defect Location ◽  
Analysis Methodology ◽  
Analysis Process ◽  
Leakage Failure

Abstract It is generally accepted that the fault isolation of Vdd short and leakage can be globally addressed by liquid crystal analysis (LCA), photoemission analysis and/or laser stimulating techniques such as OBIRCH or TIVA. However, the hot spot detected by these techniques may be a secondary effect, rather than the exact physical defect location. Further electrical probing with knowledge of the circuit schematic and layout may still be required to pinpoint the exact physical defect location, so that a suitable physical analysis methodology can be chosen to identify the root cause of the failure. This paper has described a thorough analysis process for Vdd leakage failure by a combination of various failure analysis techniques and finally the root cause of the Vdd leakage was identified.

A New Failure Analysis Flow of Gate Oxide Integrity Failure in Wafer Fabrication

2009 ◽  
Author(s):  
Hua Younan ◽  
Chu Susan ◽  
Gui Dong ◽  
Mo Zhiqiang ◽  
Xing Zhenxiang ◽  
...  
Keyword(s):  
Failure Analysis ◽  
Gate Dielectric ◽  
Dielectric Breakdown ◽  
Defect Density ◽  
Gate Oxide ◽  
Oxide Thickness ◽  
Fault Isolation ◽  
Wafer Fabrication ◽  
Root Cause ◽  
Gate Oxide Integrity

Abstract As device feature size continues to shrink, the reducing gate oxide thickness puts more stringent requirements on gate dielectric quality in terms of defect density and contamination concentration. As a result, analyzing gate oxide integrity and dielectric breakdown failures during wafer fabrication becomes more difficult. Using a traditional FA flow and methods some defects were observed after electrical fault isolation using emission microscopic tools such as EMMI and TIVA. Even with some success with conventional FA the root cause was unclear. In this paper, we will propose an analysis flow for GOI failures to improve FA’s success rate. In this new proposed flow both a chemical method, Wright Etch, and SIMS analysis techniques are employed to identify root cause of the GOI failures after EFA fault isolation. In general, the shape of the defect might provide information as to the root cause of the GOI failure, whether related to PID or contamination. However, Wright Etch results are inadequate to answer the questions of whether the failure is caused by contamination or not. If there is a contaminate another technique is required to determine what the contaminant is and where it comes from. If the failure is confirmed to be due to contamination, SIMS is used to further determine the contamination source at the ppm-ppb level. In this paper, a real case of GOI failure will be discussed and presented. Using the new failure analysis flow, the root cause was identified to be iron contamination introduced from a worn out part made of stainless steel.

Case Study in Fault Isolation of a Metal Short for Yield Enhancement

2010 ◽  
Author(s):  
Sarven Ipek ◽  
David Grosjean
Keyword(s):  
Failure Analysis ◽  
Failure Mechanism ◽  
Photon Emission ◽  
Fault Isolation ◽  
Yield Enhancement ◽  
Analysis Technique ◽  
Laser Signal ◽  
Signal Injection ◽  
Microscopy Techniques

Abstract The application of an individual failure analysis technique rarely provides the failure mechanism. More typically, the results of numerous techniques need to be combined and considered to locate and verify the correct failure mechanism. This paper describes a particular case in which different microscopy techniques (photon emission, laser signal injection, and current imaging) gave clues to the problem, which then needed to be combined with manual probing and a thorough understanding of the circuit to locate the defect. By combining probing of that circuit block with the mapping and emission results, the authors were able to understand the photon emission spots and the laser signal injection microscopy (LSIM) signatures to be effects of the defect. It also helped them narrow down the search for the defect so that LSIM on a small part of the circuit could lead to the actual defect.

The Influence of Optical Beams on Semiconductor Devices During Failure Analysis

2002 ◽  
Author(s):  
Charles Zhang ◽  
Matt Thayer ◽  
Lowell Herlinger ◽  
Greg Dabney ◽  
Manuel Gonzalez
Keyword(s):  
Failure Analysis ◽  
Semiconductor Devices ◽  
Laser Wavelength ◽  
Fault Isolation ◽  
Analysis Techniques ◽  
Cmos Transistor ◽  
Optical Beams

Abstract A number of backside analysis techniques rely on the successful use of optical beams in performing backside fault isolation. In this paper, the authors have investigated the influence of the 1340 nm and 1064 nm laser wavelength on advanced CMOS transistor performance.

Pseudo-Dynamic Fault Isolation Technique Using Backside Emission Microscopy – Case Study, Where All Other Methods Fail

2002 ◽  
Author(s):  
Yoav Weizman ◽  
Ezra Baruch ◽  
Michael Zimin
Keyword(s):  
Failure Analysis ◽  
Process Variations ◽  
Fault Isolation ◽  
Operating Conditions ◽  
Detection Sensitivity ◽  
Isolation Technique ◽  
Root Cause ◽  
Emission Microscopy ◽  
Failure Location ◽  
Noisy Background

Abstract Emission microscopy is usually implemented for static operating conditions of the DUT. Under dynamic operation it is nearly impossible to identify a failure out of the noisy background. In this paper we describe a simple technique that could be used in cases where the temporal location of the failure was identified however the physical location is not known or partially known. The technique was originally introduced to investigate IDDq failures (1) in order to investigate timing related issues with automated tester equipment. Ishii et al (2) improved the technique and coupled an emission microscope to the tester for functional failure analysis of DRAMs and logic LSIs. Using consecutive step-by-step tester halting coupled to a sensitive emission microscope, one is able detect the failure while it occurs. We will describe a failure analysis case in which marginal design and process variations combined to create contention at certain logic states. Since the failure occurred arbitrarily, the use of the traditional LVP, that requires a stable failure, misled the analysts. Furthermore, even if we used advanced tools as PICA, which was actually designed to locate such failures, we believe that there would have been little chance of observing the failure since the failure appeared only below 1.3V where the PICA tool has diminished photon detection sensitivity. For this case the step-by-step halting technique helped to isolate the failure location after a short round of measurements. With the use of logic simulations, the root cause of the failure was clear once the failing gate was known.

Case Study Failure Analysis of an Ultra-High Vacuum Enclosure Made of a Silicon Chip and Borosilicate Glass for the Cold Atom Laboratory

2017 ◽  
Author(s):  
Gil Garteiz ◽  
Javeck Verdugo ◽  
David Aveline ◽  
Eric Williams ◽  
Arvid Croonquist ◽  
...  
Keyword(s):  
Sample Preparation ◽  
Failure Analysis ◽  
Failure Mechanism ◽  
Borosilicate Glass ◽  
High Vacuum ◽  
Cold Atom ◽  
Fault Isolation ◽  
Ultra High Vacuum ◽  
Liquid Bath

Abstract In this paper, a failure analysis case study on a custom-built vacuum enclosure is presented. The enclosure’s unique construction and project requirement to preserve the maximum number of units for potential future use in space necessitated a fluorocarbon liquid bath for fault isolation and meticulous sample preparation to preserve the failure mechanism during failure analysis.

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