Title :
An Ultralow EOT Ge MOS Device With Tetragonal HfO2 and High Quality HfxGeyO Interfacial Layer
Author :
Chung-Hao Fu ; Kuei-Shu Chang-Liao ; Li-Jung Liu ; Chen-Chien Li ; Ting-Ching Chen ; Jen-Wei Cheng ; Chun-Chang Lu
Author_Institution :
Dept. of Eng. & Syst. Sci., Nat. Tsing Hua Univ., Hsinchu, Taiwan
Abstract :
A Ge MOS device with an ultralow equivalent oxide thickness of ~0.5 nm and acceptable leakage current of 0.5 A/cm2 is presented in this paper. The superior characteristics can be attributed to a tetragonal HfO2 with a higher k value (k ~ 31) and comparable bandgap. In addition, a Ge MOS device with tetragonal phase HfO2 (t-HfO2) also shows a lower leakage current and better thermal stability. The mechanisms for t-HfO2 formation may be explained by the little Ge diffusion from Ge substrate and oxygen deficiency, which are obtained by in situ interfacial layer (IL) formation and high-k processes. The IL with k ~ 13 can be formed by in situ H2O plasma treatment. Moreover, a Ge MOS device with the IL grown by H2O plasma shows smaller interface trap density and hysteresis effects due to a high composition of Ge+4.
Keywords :
MIS devices; germanium compounds; hafnium compounds; high-k dielectric thin films; leakage currents; thermal stability; H2O; HfxGeyO; HfO2; IL formation; high-k processes; hysteresis effects; interface trap density; interfacial layer formation; leakage current; oxygen deficiency; plasma treatment; tetragonal phase; thermal stability; ultralow EOT MOS device; ultralow equivalent oxide thickness; Dielectrics; Hafnium compounds; High K dielectric materials; Logic gates; MOS devices; Plasmas; Water; Chemical oxide; Ge MOS; GeO₂; GeO2; HfO₂; HfO2; equivalent oxide thickness (EOT); in situ plasma; in situ plasma.;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2014.2329839
