IEEE Journal of the Electron Devices Society (Jan 2016)
Ge GAA FETs and TMD FinFETs for the Applications Beyond Si—A Review
Abstract
Two parts of work are included in this paper. In the first part, the novel Ge gate-all-around field effect transistors (GAA FETs) are introduced and discussed. Fabrication of Ge GAA FETs requires only simple top-down dry etching and blanket Ge epitaxy techniques readily available in mass production. First, a novel process to etch away the defective Ge near Ge/Si interface from epitaxial Ge grown on SOI achieves a nearly defect-free channel, good gate control triangular gate, larger effective width than rectangular fin, and have low punch-through current through the Si substrate. By dislocation removal, the defect-free Ge channel can be formed on nothing. The p-channel triangular Ge GAA FET with fin width (Wfin) of 52 nm and Lg of 183 nm has Ion/Ioff = 105, SS = 130 mV/dec, and Ion = 235 μA/μm at -1 V. Next, due to the highest electron mobility (2200 cm2/Vs) on (111) Ge surface, the n-channel triangular Ge GAA FET with (111) sidewalls on Si and Lg = 350 nm shows 2 times enhanced Ion with respect to the devices with near (110) sidewalls. Electrostatic control of SS = 94 mV/dec (at 1 V) can be further improved if superior gate stack than EOT = 5.5 nm and Dit = 1×1012 cm-2·eV-1 is used. The Ion can be further enhanced if the line edge roughness (LER) can be reduced. Second, a feasible pathway to scale the Ge MOSFET technology by using a novel diamond-shaped Ge GAA FET with four {111} facets is also reviewed. The proposed dry etching process involves three isotropic/anisotropic etching steps with different Cl2/HBr ratios for forming the suspended diamond-shaped channel. Taking advantages of the GAA configuration, favorable carrier mobility of the {111} surface, and nearly defect-free suspended channel, nFET and pFET with excellent performance have been demonstrated, including an Ion/Ioff ratio exceeding 108, the highest ever reported for Ge-based pFETs. The TMD FinFET devices are reviewed in the second part of this paper. The TMD FinFET channel is deposited by CVD. MoS2 covered on Si fin and nanowire resulted in improved (+25%) Ion of the FinFET and nanowire FET. The PFETs also operated effectively and the N/P device Vth are low and matched perfectly. The proposed heterogeneous Si/TMD 3DFETs can be useful in future electronics. Furthermore, a 4 nm thin transition-metal dichalcogenide (TMD) body FinFET with back gate control is also proposed and reviewed. Hydrogen plasma treatment of TMD is employed to lower the series resistance. The 2 nm thin back gate oxide enables 0.5 V of Vth shift with 1.2 V change in back bias for correcting device variations and dynamically configuring a device as a high performance or low leakage device. TMD can potentially provide sub-nm thin monolayer body needed for 2 nm node FinFET.
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