High-speed time-resolved emission analysis is an attractive failure analysis technique because of its non-invasiveness. Super-conductive nanowire single photon detector (SNSPD or SSPD) is a key candidate of key device for time-resolved emission analysis. In this paper, we demonstrate time-resolved emission and its application of spatial resolution enhancement. We could confirm that time-resolved emission imaging can enhance spatial resolution by simple mathematical operations compared to static emission analysis, which is effective for finding emission spots before detailed time-resolved data investigations.

In this work we present spectrally resolved photon emission microscopy (SPEM) measurements for short-channel FETs acquired through the backside of the Si substrate using InGaAs detector. Two spectrum resolution methods have been used: continuous using a prism and discrete using a set of interference band-pass filters. The photon emission (PE) spectra have been corrected for the background / noise of the detector; they have been calibrated with respect to the system optical transmission function and corrected for the absorption on free carriers in the remaining layer of Si substrate. We discuss all the standardization aspects thoroughly as they are crucial in order to obtain correct device-intrinsic PE spectral information. Finally, we present the spectral results for FET devices operated in various operating conditions.

In this work we present spectrally resolved photon emission microscopy (SPEM) measurements originating from short-channel MOSFETs acquired through the backside of the silicon substrate. Two commonly used detectors have been chosen for the detection of electroluminescence (EL) in the visible and near-infrared spectral regime, namely Si-CCD and InGaAs. As the backside photon emission (PE) inspection is strongly influenced by the absorption of light in a substrate material, the SPEM experiments have been carried out through thinned silicon layers as obtained by mechanical grinding and local focused-ion-beam (FIB) assisted Si material removal. Intrinsic Si absorption (generation of electron-hole pairs) and absorption on free carriers have been modeled to be able to calibrate experimental results and obtain devicerelated PE spectra. The results show no evidences of specific transitions and lead to a conclusion that photon emission from MOSFETs is fully electrical field related.

In this paper, the differential and lockin imaging techniques of Dynamic Photon Emission (DPE) were developed by using highly sensitive near-infrared InGaAs camera in time integrated mode. At first, the setup and method for differential imaging of DPE (DI-DPE) are introduced. The unique debug and pinpointing capability of fails of DI-PEM is discussed in combination with two case studies. Based on DI-DPE, the setup and method for Lockin imaging of DPE (LI-DPE) are then developed for such cases where the correlated DPE is enhanced in strong photon emission background. The correlation in LI-DPE can separate the emission spots from different power domains.

SIL(Solid Immersion Lens) is well investigated for optical pickup application because of its capability of high resolution. We applied this technique to microscopy, especially for precise observation of semiconductors. And also we applied it to fault isolation techniques like emission microscopy , OBIRCH(Optical Beam Induced Resistance Change) and TIVA,SEI. We found significant enhancement of resolution and sensitvity by using SIL. Applying this technique to emission microscopy, we should be aware of optical absorption charactristics of SIL lens materials. We investigated proper SIL lens materials for emission microscopy and laser scanning applications, and checked performance of Si(Silicon)-SIL and GaP(Gallium phosphide)-SIL. We also compared combinations of some kinds of SILs and detectors like C-CCD(cooled CCD) camera, MCT(HgCdTe) camera and position sensitive detector with InGaAs photo cathode II(image intensifier).