Title :
Influence of interface traps and surface mobility degradation on scanning capacitance microscopy measurement
Author :
Hong, Yang David ; Yeow, Yew Tong ; Chim, Wai-Kin ; Wong, Kin-Mun ; Kopanski, Joseph J.
Author_Institution :
Sch. of Inf. Technol. & Electr. Eng., Univ. of Queensland, Brisbane, Australia
Abstract :
Although scanning capacitance microscopy (SCM) is based on the MOS capacitance theory, the measurement frequency is 915-MHz instead of 100 kHz to 1 MHz in conventional MOS capacitance-voltage measurement. At this high frequency, the reactance of the probe tip-to-substrate capacitance can become smaller than the series resistance of the substrate inversion layer, particularly when the surface mobility is degraded. The response of the oxide-silicon interface traps to SCM measurement is also different due to the use of a 10-kHz signal to determine dC/dV. In this paper, we compare experimental and simulation data to demonstrate the effects of interface traps and surface mobility degradation on SCM measurement. Implications on the treatment of SCM data for accurate dopant profile extraction are also presented.
Keywords :
MOS capacitors; capacitance; doping profiles; interface states; inversion layers; scanning electron microscopy; semiconductor device models; semiconductor doping; 915 MHz; MOS capacitance theory; capacitance-voltage measurement; dopant profile extraction; measurement frequency; oxide-silicon interface traps; scanning capacitance microscopy; semiconductor device modeling; series resistance; substrate inversion layer; surface mobility degradation; Capacitance measurement; Capacitance-voltage characteristics; Data mining; Degradation; Electrical resistance measurement; Frequency measurement; Microscopy; Probes; Surface resistance; Surface treatment; Dopant profile extraction; SCM; scanning capacitance microscopy; semiconductor device modeling; simulation;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2004.833590
