Ge GAA FETs and TMD FinFETs for the Applications Beyond Si—A Review
At a Glance
Section titled “At a Glance”| Metadata | Details |
|---|---|
| Publication Date | 2016-08-17 |
| Journal | IEEE Journal of the Electron Devices Society |
| Authors | Yao‐Jen Lee, Guang-Li Luo, Fu-Ju Hou, Min‐Cheng Chen, Chih-Chao Yang |
| Institutions | National Applied Research Laboratories |
| Citations | 28 |
Abstract
Section titled “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 (W<sub>fin</sub>) of 52 nm and Lg of 183 nm has I<sub>on</sub>/I<sub>off</sub> = 10<sup>5</sup>, SS = 130 mV/dec, and Ion = 235 μA/μm at -1 V. Next, due to the highest electron mobility (2200 cm<sup>2</sup>/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 = 1×10<sup>12</sup> cm<sup>-2</sup>·eV<sup>-1</sup> 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 Cl<sub>2</sub>/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 I<sub>on</sub>/I<sub>off</sub> ratio exceeding 10<sup>8</sup>, 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. MoS<sub>2</sub> covered on Si fin and nanowire resulted in improved (+25%) I<sub>on</sub> of the FinFET and nanowire FET. The PFETs also operated effectively and the N/P device V<sub>th</sub> 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 V<sub>th</sub> 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.
Tech Support
Section titled “Tech Support”Original Source
Section titled “Original Source”References
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