Title :
Germanium nMOSFETs With Recessed Channel and S/D: Contact, Scalability, Interface, and Drain Current Exceeding 1 A/mm
Author :
Heng Wu ; Mengwei Si ; Lin Dong ; Jiangjiang Gu ; Jingyun Zhang ; Ye, Peide D.
Author_Institution :
Birck Nanotechnol. Center, Purdue Univ., West Lafayette, IN, USA
Abstract :
A novel recessed channel and source/drain (S/D) technique is employed in Ge nMOSFETs, which greatly improves metal contacts to n-type Ge with contact resistance of down to 0.23 Ω · mm and enhances gate electrostatic control with ION/IOFF of 105. The recessed S/D contacts are thoroughly investigated, showing strong dependence on the doping profile. For the first time, the drain current of Ge nMOSFETs has exceeded 1 A/mm with an Id of 1043 mA/mm on a 40-nm Lch device. Scalability study is carried out in deep sub-100-nm region on Ge nMOSFETs with Lch down to 25 nm. Interface study is also conducted with a new postoxidation method introduced, which significantly reduces the interface trap density. Device behaviors corresponding to interface traps are also investigated through a Technology Computer Aided Design simulation.
Keywords :
MOSFET; contact resistance; doping profiles; germanium; interface states; technology CAD (electronics); Ge; doping profiles; drain current; gate electrostatic control enhancement; interface trap density reduction; metal contact resistance; nMOSFET; postoxidation method; recessed S-D contacts; recessed channel; source-drain technique; technology computer aided design simulation; Annealing; Doping; Logic gates; MOSFET; Nickel; Time-domain analysis; Time-varying systems; Ge; Ge-on-insulator (GeOI); MOSFET; nMOSFET; recessed channel; recessed source/drain (S/D); scalability; scalability.;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2015.2412878
