Title :
Reduction of Surface Roughness in Epitaxially Grown Germanium by Controlled Thermal Oxidation
Author :
Woo-Shik Jung ; Ju Hyung Nam ; Pal, Ashish ; Jae Hyung Lee ; Yeul Na ; Youngsik Kim ; Jin Hyung Lee ; Saraswat, Krishna C.
Author_Institution :
Dept. of Electr. Eng., Stanford Univ., Stanford, CA, USA
Abstract :
Obtaining a smooth substrate with surface roughness of 2 Å is essential for semiconductor device fabrication. In this letter, we characterize the effect of thermal oxidation of epitaxially grown Ge on its surface roughness. First, the effect of oxidation on root-mean-square roughness is investigated for epi-Ge surface that is bombarded with phosphorous ions. Next, the effect of oxidation is investigated with the presence of low thermal oxide layer on the epi-Ge. Finally, examination of the effect of temperature on surface roughness for capped epi-Ge is conducted. By making the Ge oxidation diffusion limited, surface roughness can be reduced to ~2 Å.
Keywords :
MOSFET; elemental semiconductors; epitaxial growth; germanium; ion implantation; oxidation; phosphorus; semiconductor epitaxial layers; silicon compounds; surface diffusion; surface roughness; Ge-SiO2; Ge:P; MOSFET; current 2 A; epitaxial growth; germanium; low thermal oxide layer; oxidation diffusion limited; phosphorous ion bombardment; root-mean-square roughness; semiconductor device fabrication; smooth substrate; surface roughness; temperature effect; thermal oxidation; Annealing; Oxidation; Rough surfaces; Silicon; Substrates; Surface roughness; Surface treatment; AFM; Germanium; germanium; surface roughness;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2015.2404814
