Title :
Single-shot thermal energy mapping of semiconductor devices with the nanosecond resolution using holographic interferometry
Author :
Pogany, D. ; Dubec, V. ; Bychikhin, S. ; Fürböck, C. ; Litzenberger, M. ; Groos, G. ; Stecher, M. ; Gornik, E.
Author_Institution :
Inst. for Solid State Electron., Vienna Univ. of Technol., Austria
Abstract :
A novel two-dimensional backside optical imaging method for thermal energy mapping inside semiconductor devices is presented. The method is based on holographic interferometry from the device backside and uses the thermo-optical effect. An image of the local thermal energy is obtained with 5-ns time resolution using a single stress pulse. The technique allows a unique recording of the internal device behavior. The method is demonstrated analyzing the nonrepetitive thermal and current flow dynamics in smart power electrostatic discharge (ESD) protection devices. A spreading of the current during the stress pulse is observed and explained by the effect of the negative temperature dependence of the impact ionization coefficient.
Keywords :
current distribution; electrostatic discharge; holographic interferometry; impact ionisation; power bipolar transistors; protection; semiconductor device testing; thermal variables measurement; thermo-optical effects; ESD protection transistor; current flow dynamics; current spreading; electrothermal effects; holographic interferometry; impact ionization coefficient; internal device behavior; local thermal energy image; n-p-n bipolar transistor; nanosecond resolution; negative temperature dependence; nonrepetitive thermal flow dynamics; semiconductor devices; single stress pulse; single-shot thermal energy mapping; smart power electrostatic discharge protection devices; thermo-optical effect; time resolution; two-dimensional backside optical imaging method; Electrostatic discharge; Energy resolution; Holography; Image resolution; Nanoscale devices; Optical imaging; Optical interferometry; Semiconductor devices; Thermal stresses; Thermooptical devices;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2002.803752
