Title :
Thermal Immune NiGermanide for High Performance Ge MOSFETs on Ge-on- Si Substrate Utili
Author :
Zhang, Ying-Ying ; Oh, Jungwoo ; Han, In-Shik ; Zhong, Zhun ; Li, Shi-Guang ; Jung, Soon-Yen ; Park, Kee-Young ; Shin, Hong-Sik ; Choi, Won-Ho ; Kwon, Hyuk-Min ; Loh, Wei-Yip ; Majhi, Prashant ; Jammy, Raj ; Lee, Hi-Deok
Author_Institution :
Dept. of Electron. Eng., Chungnam Nat. Univ., Daejeon
Abstract :
Highly thermally stable Ni germanide technology for high performance germanium metal-oxide-semiconductor field-effect transistors (Ge MOSFETs) is proposed, utilizing Pd incorporation into Ni germanide. The proposed Ni germanide shows not only the improvement of thermal stability but also the reduction of hole barrier height, which can improve the device on-current by reducing the Ni germanide to p+ source/drain contact resistance. The proposed Ni germanide showed a stable sheet resistance of up to 500degC 30-min postgermanidation annealing due to the suppression of agglomeration and oxidation of Ni germanide and the diffusion of Ni and Ge atoms by the incorporated Pd. Therefore, the proposed Ni0.95Pd0.05 alloy could be promising for the high mobility Ge MOSFET applications.
Keywords :
MOSFET; annealing; contact resistance; diffusion; electrical resistivity; elemental semiconductors; germanium; nickel alloys; nickel compounds; oxidation; palladium alloys; titanium compounds; MOSFETs; Ni0.95Pd0.05-TiN; NiGe-Ge; agglomeration; annealing; contact resistance; diffusion; hole barrier height; metal-oxide-semiconductor field-effect transistors; oxidation; sheet resistance; temperature 500 degC; thermal stability; Atomic layer deposition; Epitaxial growth; Germanium alloys; Jamming; MOSFETs; Nickel alloys; Rough surfaces; Substrates; Surface roughness; Thermal stability; Annealing; Ni alloys; Ni compounds; Schottky barriers; Schottky diodes; germanium;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2008.2010593
