1-3 of 3
Xianghong Tom Tong
Close
Save search
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
Close Modal
Sort by
Proceedings Papers

E-beam Probing and E-beam-Assisted Device Alteration (EADA) for Fault Isolation in PowerVia and Advanced Technology Nodes

Jennifer J. Huening, Xianghong Tom Tong, Shuai Zhao, Ravi Thirugnanasambandam, Yunfei Wang ...
ISTFA2024, ISTFA 2024: Conference Proceedings from the 50th International Symposium for Testing and Failure Analysis, 519-522, October 28–November 1, 2024,
https://doi.org/10.31399/asm.cp.istfa2024p0519
Abstract
This paper demonstrates that e-beam assisted device alteration (EADA) is a powerful, high-resolution technique for fault isolation debug for advanced technology nodes. A case study using this technique is reviewed and shows successful isolation of a defective single inverter. In addition, fundamental studies of ring oscillator behavior and device perturbations with e-beam exposure found clear correlations for electron beam exposure with NMOS/PMOS device parameters. Electron-hole pair generation in the device with beam exposure is likely the main component for the perturbation, but there may be other contributing factors including charging effects and/or heating.
View Papertitled, E-beam Probing and E-beam-Assisted Device Alteration (EADA) for Fault Isolation in PowerVia and Advanced Technology Nodes View PDF for content titled, E-beam Probing and E-beam-Assisted Device Alteration (EADA) for Fault Isolation in PowerVia and Advanced Technology Nodes
Proceedings Papers

Electrical Event Capture with an Electron Beam Probing System

Neel Leslie, James Vickers, Jennifer J Huening, Xianghong Tom Tong, Patrick Pardy
ISTFA2023, ISTFA 2023: Conference Proceedings from the 49th International Symposium for Testing and Failure Analysis, 164-167, November 12–16, 2023,
https://doi.org/10.31399/asm.cp.istfa2023p0164
Abstract
With the introduction of flip-chip technology, optical-based failure analysis techniques have played a critical role in many failure analysis (FA) laboratories. This is due to the unhindered access for photons to probe or emit from the transistor layer through the bulk silicon. Among the optical techniques, laser voltage imaging (LVI) and laser voltage probing (LVP), collectively called LVx, dominate because they directly expose the electrical activity of a given circuit or cell.
View Papertitled, Electrical Event Capture with an Electron Beam Probing System View PDF for content titled, Electrical Event Capture with an Electron Beam Probing System
Book Chapter

Silicon Device Backside De-Processing and Fault Isolation Techniques

By Xianghong Tom Tong, Wen-hsien Chuang, Hyuk Ju Ryu, Prasoon Joshi, Di Xu ...
Series: ASM Technical Books
Publisher: ASM International
Published: 01 November 2019
DOI: 10.31399/asm.tb.mfadr7.t91110323
EISBN: 978-1-62708-247-1
Abstract
This article presents methods that enable one to consistently, uniformly and quickly remove substrate silicon from units without imparting damage to the structure of interest. It provides examples of electron beam probing and backside nano-probing techniques. The electron beam probing techniques are E-beam Logic State Imaging, Electron-beam Signal Image Mapping, and E-beam Device Perturbation. Backside nano-probing techniques discussed include: Electron Beam Absorbed Current, Electron Beam Induced Resistance Change, four terminal resistance measurements, resistive gate defect identification, and circuit editing. The article also presents methods to prepare electron beam probing samples where some remaining silicon is required for the transistor functions and transmission electron microscope samples from units where the substrate silicon has been partially or completely removed.
View PDF for content titled, Silicon Device Backside De-Processing and Fault Isolation Techniques