Figure 1: The thin-body silicide source/drain MOSFET in cross section. Source/drains are made in 100Å Si: NMOS uses ErSi1.7 (Φb0n=0.28V), PMOS uses PtSi (Φb0p=0.24V). Spacer thickness is limited to 100Å, in order to guarantee that the metal diffuses underneath the gate. Complementary silicide source/drain thin-body
Spectroscopic ellipsometry was used to investigate the oxidation of pure Hf films on silicon for the formation of HfO2 (hafnium oxide) gate-dielectric films in advanced complementary metal-oxide-semiconductor field-effect transistors. Absorption coefficients near the absorption edge were extracted using the data inversion method, in which the optical constants for short wavelengths were calculated using the film thickness determined from long-wavelength data. The extracted optical band gap of 5.7 eV matches well with published data, and a curve shift due to crystallization was detected. In addition, an extra absorption peak corresponding to electron transition from the valence band to a defect energy level was observed in the range 4.5–5.0 eV above the valence-band edge. The 1.2 eV energy difference between the conduction-band edge and the edge of this extra peak is close to the electron trap energy level reported elsewhere. The intensity of the detected peak was clearly correlated with leakage current and near-interface trap densities. Based on the annealing condition dependence of the extra absorption peak, the defects are likely oxygen vacancies within the HfO2 film.
Deep-sub-tenth micron MOSFETs with gate length down to 20 nm are reported. To improve the short channel effect immunities, a novel "Folded Channel Transistor" structure is proposed. The quasi-planar nature of this new variant of the vertical double-gate SO1 MOSFETs [1], [2] simplified the fabrication process. The special features of thie structure ( Fig. 1) are: (1) a transistor is formed in a vertical ultra-thin Si fin and is controlled by a double-gate, which suppresses short channel effects; (2) the two gates are self-aligned and are aligned to the S/D; (3) S/D is raised to reduce the parasitic resistance; (4) new low-temperature gate or ultra-thin gate dielectric materials can be used because they are deposited after the S/D; and (5) the structure is quasi-planar because the Si fins are relatively short. Figure 2 shows the process flow and the SEM pictures at two fabrication steps. Using SO1 wafers as the starting material, Si3N4 and Si02 layer were deposited on the 50-nm SO1 layer. Using 100 keV EB lithography and ashing technique, -20 nm wiide Si fins were patterned and etched. Then, 100-nm P-doped a-Si and 300-nm Si02 were deposited and the result is shown in the top SEM picture. The a-Si becomes polycrystalline later and provides a good contact at the side surface of the Si fin. After delineating the a-Si S/D pattern, SiOz spacers were formed on the sidewalls of the S/D. Through sufficient over-etching, Si02 was removed from the sides of the relatively low Si fins. The top-view SEM picture shows a 15-nm thin Si fin visible in the 50-nm spacer gap, which determines the gate length. After growing 2.5-nm gate oxide on the side surfaces of the Si fin, B-in-situ-doped SiGe (60% Ge) was deposited as the gate. During the gate oxidation, P was diffused from the raised S/D into the Si fin region tlo form S/D extension. We did not use metal electrodes in this experiment so that additional S/D extension diffusion can be optimized. This explains the large parasitic resistance of over 3000 ohmldevice. The W of the devices is twice the height of the Si fins or approximately 100 nm.Typical I-V characteristics of 30-nm gate length are slhown in Fig. 3. In spite of low channel impurity concentration ( 10l6 cm-'), the leakage current caused by DIBL was well suppressed. The Vt roll-off characteristics of a 20-nm Si width devices are shown in Fig. 4. Vt is defined as the gate voltage when Ids= lo-'' A. Good roll-off characteristics are observed for folded channel structure. Figure 5 shows the subthreshold swing dependence on the: Si width. Since the thin body of the double-gate device prevents the punch-through, the folded channel devices show small swings. In Fig. 6, the transconductance (Gm) are plotted with the Si width as a parameter. Interestingly, Gm peaks at 30-nm of Si width. This is because that the thin body increases the parasitic resistance but also can increase the mobility and reduce the charge centrioid, resulting in an optimum in the Si width. Finally, to achieve high current drivability and demonstrate dis...
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