Title :
In Situ Process Control of Trilayer Gate-Stacks on p-Germanium With 0.85-nm EOT
Author :
Zheng, Y.X. ; Agrawal, A. ; Rayner, G.B. ; Barth, M.J. ; Ahmed, K. ; Datta, S. ; Engel-Herbert, R.
Author_Institution :
Pennsylvania State Univ., State College, PA, USA
Abstract :
In situ spectroscopic ellipsometry was utilized in an atomic-layer-deposition (ALD) reactor for rapid and rational gate stack process optimization of the trilayer dielectric HfO2/Al2O3/GeOx on Ge. The benefit of this approach was demonstrated by developing an entire process in situ: 1) native oxide removal by hydrogen plasma; 2) controlled reoxidation for Ge surface passivation; and 3) deposition of Al2O3 and HfO2 using thermal ALD. The low-k layer thicknesses were scaled down without losing their respective functions, i.e., GeOx to form an electrically well behaved interface with Ge and Al2O3 to thermodynamically stabilize the GeOx/Ge interface. Aggressive equivalent-oxide-thickness scaling of the trilayer stack down to 0.85 nm with a low gate leakage of 0.15 mA/cm2 at VFB- 1 V was achieved, while preserving a high-quality dielectric-semiconductor interface.
Keywords :
aluminium compounds; atomic layer deposition; elemental semiconductors; ellipsometry; field effect devices; germanium; hafnium compounds; interface states; passivation; Ge; HfO2-Al2O3-GeO; atomic-layer-deposition reactor; controlled reoxidation; dielectric-semiconductor interface; equivalent-oxide-thickness scaling; gate stack process optimization; hydrogen plasma; in situ process control; in situ spectroscopic ellipsometry; low-k layer thickness; native oxide removal; size 0.85 nm; surface passivation; thermal ALD; trilayer dielectric; trilayer gate-stacks; Aluminum oxide; Hafnium compounds; Leakage currents; Logic gates; Rough surfaces; Surface roughness; Surface treatment; ALD; GE; Ge; MOSCAP; atomic hydrogen clean; in-situ spectroscopic ellipsometry; interface; trilayer;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2015.2459663
