Title :
Scanning frequency comb microscopy (SFCM) shows promise for sub-10 nm dopant profiling
Author :
Hagmann, Mark J. ; Andrei, Petru
Author_Institution :
Electr. & Comput. Eng. Dept., Univ. of Utah, Salt Lake City, UT, USA
Abstract :
When a mode-locked ultrafast laser is focused on the tunneling junction of a scanning tunneling microscope a microwave frequency comb, at harmonics of the pulse repetition frequency of the laser, is superimposed on the DC tunneling current. A clean semiconductor sample, biased to form a nanoscale depletion region at the base of the tunneling junction, attenuates these harmonics. Simulations suggest that the dependence of the measured attenuation on the applied DC bias may be used to determine the local concentration of dopant atoms with a resolution as fine as the radius of the tunneling junction - which is much smaller than radius of the tip electrode.
Keywords :
doping profiles; laser beam effects; microwave photonics; scanning tunnelling microscopy; DC tunneling current; SFCM; applied DC bias; clean semiconductor sample; dopant atoms; microwave frequency comb; mode-locked ultrafast laser; nanoscale depletion region; pulse repetition frequency; scanning frequency comb microscopy; scanning tunneling microscope; size 10 nm; tip electrode; tunneling junction; Harmonic analysis; Junctions; Laser mode locking; Masers; Semiconductor device measurement; Semiconductor lasers; Tunneling; carrier profiling; dopant profiling; femtosecond laser; microwave frequency comb; scanning frequency comb microscopy; scanning probe microscopy;
Conference_Titel :
Microelectronics And Electron Devices (WMED), 2014 IEEE Workshop On
Conference_Location :
Boise, ID
Print_ISBN :
978-1-4799-2222-2
DOI :
10.1109/WMED.2014.6818724
