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1-3 of 3
Rakshith Venkatesh
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Proceedings Papers
ISTFA2022, ISTFA 2022: Conference Proceedings from the 48th International Symposium for Testing and Failure Analysis, 153-162, October 30–November 3, 2022,
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Near Infra-Red (NIR) techniques such as Laser Voltage Probing/Imaging (LVP/I), Dynamic Laser Stimulation (DLS), and Photon Emission Microscopy (PEM) are indispensable for Electrical Fault Isolation/Electrical Failure Analysis (EFI/EFA) of silicon Integrated Circuit (IC) devices. However, upcoming IC architectures based on Buried Power Rails (BPR) with Backside Power Delivery (BPD) networks will greatly reduce the usefulness of these techniques due to the presence of NIR-opaque layers that block access to the transistor active layer. Alternative techniques capable of penetrating these opaque layers are therefore of great interest. Recent developments in intense, focused X-ray microbeams for micro X-Ray Fluorescence (μXRF) microscopy open the possibility to using X-rays for targeted and intentional device alteration. In this paper, we will present results from our preliminary investigations into X-ray Device Alteration (XDA) of flip-chip packaged FinFET devices and discuss some implications of our findings for EFI/EFA.
Proceedings Papers
ISTFA2019, ISTFA 2019: Conference Proceedings from the 45th International Symposium for Testing and Failure Analysis, 86-98, November 10–14, 2019,
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High core-Vdd overvoltage latchup margins in CMOS ICs are required to enable many reliability screens (e.g., DVS and HTOL testing). We introduce an efficient way to isolate defects that degrade these margins using PEM and 1064/1340 nm CW laser-stimulation. Current pulses from a current amplifier are used to rapidly charge and discharge the DUT power rail to repetitively ramp Vdd to (or near) the latchup threshold. The characteristic drop in Vdd when latchup is induced is used to generate a latchup flag for laser-stimulation mapping. Latchup events are automatically terminated and latchup durations are minimized, leading to high stability/repeatability of the technique. Isolations down to the cell level were successfully performed in sub-14 nm FinFET test vehicles. This level of isolation is unmatched and this is the first reported use of thermal laser stimulation for latchup investigations. In one provided example, the latchup trigger was isolated to FET based decoupling capacitors (decaps) widely used as fill.
Proceedings Papers
ISTFA2016, ISTFA 2016: Conference Proceedings from the 42nd International Symposium for Testing and Failure Analysis, 7-18, November 6–10, 2016,
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Using a laser to purposely damage (or zap) a static random-access memory (SRAM) bitcell for bitmap validation purposes is a well-established technique. However, the absence of visible damage in FinFET SRAM cells, amongst other things, makes precision zapping in these devices more difficult. In this paper, we describe system enhancements and a modified workflow for bitmap validation of these devices using precision, near-infrared (NIR) laser-induced damage. We also explore the use of laser perturbation and non-precision zapping options. Examples are provided.