Germanium MOS capacitors incorporating ultrathin high-/spl kappa/ gate dielectric

For the first time, we have successfully demonstrated the feasibility of integrating a high-permittivity (/spl kappa/) gate dielectric material zirconium oxide into the MOS capacitors fabricated on pure germanium substrates. The entire fabrication process was essentially performed at room temperature with the exception of a 410/spl deg/C forming gas anneal. After processing steps intended to remove the germanium native oxide interlayer between the zirconium oxide dielectric and germanium substrate, an excellent capacitance-based equivalent SiO/sub 2/ thickness (EOT) on the order of 5-8 /spl Aring/ and capacitance-voltage (C-V) characteristics with hysteresis of 16 mV have been achieved. Additionally, excellent device yield and uniformity were possible using this low thermal budget process.     

MOS characteristics of substituted Al gate on high-/spl kappa/ dielectric

Substituted aluminum (SA) metal gate on high-/spl kappa/ gate dielectric is successfully demonstrated. Full substitution of polysilicon with Al is achieved for a Ti-Al-polysilicon-HfAlON gate structure by a low-temperature annealing at 450/spl deg/C. The SA gate on HfAlON dielectric shows a very low work function of 4.25eV, which is well suitable for bulk nMOSFETs. The SA process is fully free from the Fermi-level pinning problem. In addition, the SA process also shows improved uniformity in leakage current distribution compared to fully silicided metal gate.     

Improved interface quality and charge-trapping characteristics of MOSFETs with high-/spl kappa/ gate dielectric

The effects of high-pressure annealing on interface properties and charge trapping of nMOSFET with high-/spl kappa/ dielectric were investigated. Comparing with conventional forming gas (H/sub 2//Ar=4%/96%) annealed sample, nMOSFET sample annealed in high-pressure (5-20 atm), pure H/sub 2/ ambient at 400/spl deg/C shows 10%-15% improvements in linear drain current (I/sub d/) and maximum transconductance (g/sub m,max/). Interface trap density and charge trapping properties were characterized with charge pumping measurements and "single pulsed" I/sub d/-V/sub g/ measurements where reduced interface state density and improved charge trapping characteristics were observed after high pressure annealing. These results indicate that high pressure pure hydrogen annealing can be a crucial process for future high-/spl kappa/ gate dielectric applications.     

Germanium pMOSFETs with Schottky-barrier germanide S/D, high-/spl kappa/ gate dielectric and metal gate

Schottky-barrier source/drain (S/D) germanium p-channel MOSFETs are demonstrated for the first time with HfAlO gate dielectric, HfN-TaN metal gate and self-aligned NiGe S/D. The drain drivability is improved over the silicon counterpart with PtSi S/D by as much as /spl sim/5 times due to the lower hole Schottky barrier of the NiGe-Ge contact than that of PtSi-Si contact as well as the higher mobility of Ge channel than that of Si.     

Ge n-MOSFETs on lightly doped substrates with high-/spl kappa/ dielectric and TaN gate

In this letter, we report successful fabrication of germanium n-MOSFETs on lightly doped Ge substrates with a thin HfO/sub 2/ dielectric (equivalent oxide thickness /spl sim/10.8 /spl Aring/) and TaN gate electrode. The highest peak mobility (330 cm/sup 2//V/spl middot/s) and saturated drive current (130 /spl mu/A/sq at V/sub g/--V/sub t/=1.5 V) have been demonstrated for n-channel bulk Ge MOSFETs with an ultrathin dielectric. As compared to Si control devices, 2.5/spl times/ enhancement of peak mobility has been achieved. The poor performance of Ge n-MOSFET devices reported recently and its mechanism have been investigated. Impurity induced structural defects are believed to be responsible for the severe degradation.     

Electrical properties of amorphous high-/spl kappa/ HfTaTiO gate dielectric with dielectric constants of 40-60

High-quality Hf-based gate dielectrics with dielectric constants of 40-60 have been demonstrated. Laminated stacks of Hf, Ta, and Ti with a thickness of /spl sim/10 /spl Aring/ each was deposited on Si followed by rapid thermal anneal. X-ray diffraction analysis showed that the crystallization temperature of the laminated dielectric stack is increased up to 900/spl deg/C. The excellent electrical properties of HfTaTiO dielectrics with TaN electrode have been demonstrated, including low interface state density (D/sub it/), leakage current, and trap density. The effect of binary and ternary laminated metals on the enhancement of dielectric constant and electrical properties has been studied.     

Si interlayer passivation on germanium MOS capacitors with high-/spl kappa/ dielectric and metal gate

We have demonstrated the advantages of silicon interlayer passivation on germanium MOS devices, with CVD HfO/sub 2/ as the high-/spl kappa/ dielectric and PVD TaN as the gate electrode. A silicon interlayer between a germanium substrate and a high-/spl kappa/ dielectric, deposited using SiH/sub 4/ gas at 580/spl deg/C, significantly improved the electrical characteristics of germanium devices in terms of low D/sub it/ (7/spl times/10/sup 10//cm/sup 2/-eV), less C- V hysteresis and frequency dispersion. Low leakage current density of 5/spl times/10/sup -7/ A/cm/sup 2/ at 1 V bias with EOT of 12.4 /spl Aring/ was achieved. Post-metallization annealing caused continuing V/sub fb/ positive shift and J/sub g/ increase with increased annealing temperature, which was possibly attributed to Ge diffusion into the dielectric during annealing.     

High mobility NMOSFET structure with high-/spl kappa/ dielectric

High-/spl kappa/ NMOSFET structures designed for enhancement mode operation have been fabricated with mobilities exceeding 6000 cm/sup 2//Vs. The NMOSFET structures which have been grown by molecular beam epitaxy on 3-in semi-insulating GaAs substrate comprise a 10 nm strained InGaAs channel layer and a high-/spl kappa/ dielectric layer (/spl kappa//spl cong/20). Electron mobilities of >6000 and 3822 cm/sup 2//Vs have been measured for sheet carrier concentrations n/sub s/ of 2-3/spl times/10/sup 12/ and /spl cong/5.85/spl times/10/sup 12/ cm/sup -2/, respectively. Sheet resistivities as low as 280 /spl Omega//sq. have been obtained.     

High work-function metal gate and high-/spl kappa/ dielectrics for charge trap flash memory device applications

We report the impact of high work-function (/spl Phi//sub M/) metal gate and high-/spl kappa/ dielectrics on memory properties of NAND-type charge trap Flash (CTF) memory devices. In this paper, theoretical and experimental studies show that high /spl Phi//sub M/ gate and high permittivity (high-/spl kappa/) dielectrics play a key role in eliminating electron back tunneling though the blocking dielectric during the erase operation. Techniques to improve erase efficiency of CTF memory devices with a fixed metal gate by employing various chemicals and structures are introduced and those mechanisms are discussed. Though process optimization of high /spl Phi//sub M/ gate and high-/spl kappa/ materials, enhanced CTF device characteristics such as high speed, large memory window, and good reliability characteristics of the CTF devices are obtained.     

A study of relaxation current in high-/spl kappa/ dielectric stacks

Dielectric relaxation currents in SiO/sub 2//Al/sub 2/O/sub 3/ and SiO/sub 2//HfO/sub 2/ high-/spl kappa/ dielectric stacks are studied in this paper. We studied the thickness dependence, gate voltage polarity dependence and temperature dependence of the relaxation current in high-/spl kappa/ dielectric stacks. It is found that high-/spl kappa/ dielectric stacks show different characteristics than what is expected based on the dielectric material polarization model. By the drain current variation measurement in n-channel MOSFET, we confirm that electron trapping and detrapping in the high-/spl kappa/ dielectric stacks is the cause of the dielectric relaxation current. From substrate injection experiments, it is also concluded that the relaxation current is mainly due to the traps located near the SiO/sub 2//high-/spl kappa/ interface. As the electron trapping induces a serious threshold voltage shift problem, a low trap density at the SiO/sub 2//high-/spl kappa/ interface is a key requirement for high-/spl kappa/ dielectric stack application and reliability in MOS devices.     

Nanoscale germanium MOS Dielectrics-part II: high-/spl kappa/ gate dielectrics

In this paper, atomic layer deposition (ALD) and ultraviolet ozone oxidation (UVO) of zirconium and hafnium oxides are investigated for high-/spl kappa/ dielectric preparation in Ge MOS devices from the perspectives of thermodynamic stability and electrical characteristics. Prior to performing these deposition processes, various Ge surface preparation schemes have been examined to investigate their effects on the resulting electrical performance of the Ge MOS capacitors. Interfacial layer-free ALD high-/spl kappa/ growth on Ge could be obtained; yet, insertion of a stable interfacial layer greatly enhanced the electrical characteristics but with a compromise for equivalent dielectric thickness scalability. On the other hand, interfacial layer-free UVO high-/spl kappa/ growth on Ge was demonstrated with minimal capacitance-voltage hysteresis and sub-1.0-nm capacitance equivalent thickness. Finally, the leakage conduction and scalability of these nanoscale Ge MOS dielectrics are discussed and are shown to outperform their Si counterparts.     

A novel self-aligned offset-gated polysilicon TFT using high-/spl kappa/ dielectric spacers

In this letter, a novel self-aligned offset-gated Poly-Si thin-film transistor (TFT) using high-/spl kappa/ dielectric Hafnium oxide (HfO/sub 2/) spacers is proposed and demonstrated. The HfO/sub 2/ film is deposited by magnetron sputter deposition, and the HfO/sub 2/ spacers are formed by reactive ion etching. The permittivity of the deposited HfO/sub 2/ is approximately 20. Experimental results show that with the high vertical field induced underneath the high-/spl kappa/ spacers, an inversion layer is formed, and it effectively increases the on-state current while still maintaining a low leakage current in the off-state, compared to the conventional lightly doped drain or oxide spacer TFTs. The on-state current in the offset-gated Poly-Si TFT using the HfO/sub 2/ spacers is approximately two times higher than that of the conventional oxide spacer TFT.     

Electrical observation of deep traps in high-/spl kappa//metal gate stack transistors

The instability of threshold voltage in high-/spl kappa//metal gate devices is studied with a focus on the separation of reversible charge trapping from other phenomena that may contribute to time dependence of the threshold voltage during a constant voltage stress. Data on the stress cycles of opposite polarity on both pMOS and nMOS transistor suggests that trapping/detrapping at the deep bandgap states contributes to threshold voltage instability in the pMOS devices. It is found that under the same electric field stress conditions, threshold voltage changes in pMOS and nMOS devices are nearly identical.     

Intrinsic mobility evaluation of high-/spl kappa/ gate dielectric transistors using pulsed I/sub d/-V/sub g/

A novel intrinsic mobility extraction methodology for high-/spl kappa/ gate stacks that only requires a capacitance-voltage and pulsed I/sub d/-V/sub g/ measurement is demonstrated on SiO/sub 2/ and high-/spl kappa/ gate dielectric transistors and is benchmarked to other reported mobility extraction techniques. Fast transient charging effects in high-/spl kappa/ gate stacks are shown to cause the mobility extracted using conventional dc-based techniques to be lower than the intrinsic mobility.     

Characterization of accumulation layer capacitance for extracting data on high-/spl kappa/ gate dielectrics

A new parameter extraction technique has been outlined for high-/spl kappa/ gate dielectrics that directly yields values of the dielectric capacitance C/sub di/, the accumulation layer surface potential quotient, /spl beta//sub acc/, the flat-band voltage, the surface potential /spl phi//sub s/, the dielectric voltage, the channel doping density and the interface charge density at flat-band. The parallel capacitance, C/sub p/(=C/sub sc/+C/sub it/), was found to be an exponential function of /spl phi//sub s/ in the strong accumulation regime, for seven different high-/spl kappa/ gate dielectrics. The slope of the experimental lnC/sub p/(/spl phi//sub s/) plot, i.e., |/spl beta//sub acc/|, was found to depend strongly on the physical properties of the high-/spl kappa/ dielectric, i.e., was inversely proportional to [(/spl phi//sub b/m/sup *//m)/sup 1/2/K/C/sub di/], where /spl phi//sub b/ is the band offset, and m/sup */ is the effective tunneling mass. Extraction of /spl beta//sub acc/ represented an experimental carrier confinement index for the accumulation layer and an experimental gate-dielectric direct-tunneling current index. /spl beta//sub acc/ may also be an effective tool for monitoring the effects of post-deposition annealing/processing.     

Accumulation gate capacitance of MOS devices with ultrathin high-/spl kappa/ gate dielectrics: modeling and characterization

A quantum-mechanical (QM) model is presented for accumulation gate capacitance of MOS structures with high-/spl kappa/ gate dielectrics. The model incorporates effects due to penetration of wave functions of accumulation carriers into the gate dielectric. Excellent agreement is obtained between simulation and experimental C-V data. It is found that the slope of the C-V curves in weak and moderate accumulation as well as gate capacitance in strong accumulation varies from one dielectric material to another. Inclusion of penetration effect is essential to accurately describe this behavior. The physically based calculation shows that the relationship between the accumulation semiconductor capacitance and Si surface potential may be approximated by a linear function in moderate accumulation. Using this relationship, a simple technique to extract dielectric capacitance for high-/spl kappa/ gate dielectrics is proposed. The accuracy of the technique is verified by successfully applying the method to a number of different simulated and experimental C-V characteristics. The proposed technique is also compared with another method available in the literature. The improvements made in the proposed technique by properly incorporating QM and other physical effects are clearly demonstrated.     

An air spacer technology for improving short-channel immunity of MOSFETs with raised source/drain and high-/spl kappa/ gate dielectric

An air-spacer technology with raised source/drain (S/D) for ultrathin-body (UTB) silicon-on-insulator MOSFETs is developed. The results show that the poly raised S/D can effectively reduce the series resistance and the air spacer can effectively reduce the fringing capacitance. The air spacer is particularly useful when combined with high-/spl kappa/ gate dielectric. The improved device characteristics are demonstrated experimentally and by extensive two-dimensional device simulation.     

Improved device performance and reliability in high /spl kappa/ HfTaTiO gate dielectric with TaN gate electrode

The device performance and reliability of higher-/spl kappa/ HfTaTiO gate dielectrics have been investigated in this letter. HfTaTiO dielectrics have been reported to have a high-/spl kappa/ value of 56 and acceptable barrier height relative to Si (1.0 eV). Through process optimization, an ultrathin equivalent oxide thickness (EOT) (/spl sim/9 /spl Aring/) has been achieved. HfTaTiO nMOSFET characteristics have been studied as well. The peak mobility of HfTaTiO is 50% higher than that of HfO/sub 2/ and its high field mobility is comparable to that of HfSiON with an intentionally grown SiO/sub 2/ interface, indicative of superior quality of the interface and bulk dielectric. In addition, HfTaTiO dielectric has a reduced stress-induced leakage current (SILC) and improved breakdown voltage compared to HfO/sub 2/ dielectric.     

Atomic layer deposition of high-/spl kappa/ dielectric for germanium MOS applications - substrate

In this letter, we present the use of atomic layer deposition (ALD) for high-/spl kappa/ gate dielectric formation in Ge MOS devices. Different Ge surface cleaning methods prior to high-/spl kappa/ ALD have been evaluated together with the effects on inserting a Ge oxynitride (GeO/sub x/N/sub y/) interlayer between the high-/spl kappa/ layer and the Ge substrate. By incorporating a thin GeO/sub x/N/sub y/ interlayer, we have demonstrated excellent MOS capacitors with very small capacitance-voltage hysteresis and low gate leakage. Physical characterization has also been done to further investigate the quality of the oxynitride interlayer.     

Integrated high-/spl kappa/ (/spl kappa/ /spl sim/19) MIM capacitor with Cu/low-/spl kappa/ interconnects for RF application

We demonstrate a high-performance metal-high /spl kappa/ insulator-metal (MIM) capacitor integrated with a Cu/low-/spl kappa/ backend interconnection. The high-/spl kappa/ used was laminated HfO/sub 2/-Al/sub 2/O/sub 3/ with effective /spl kappa/ /spl sim/19 and the low-/spl kappa/ dielectric used was Black Diamond with /spl kappa/ /spl sim/2.9. The MIM capacitor (/spl sim/13.4 fF//spl mu/m/sup 2/) achieved a Q-factor /spl sim/53 at 2.5 GHz and 11.7 pF. The resonant frequency f/sub r/ was 21% higher in comparison to an equivalently integrated Si/sub 3/N/sub 4/-MIM capacitor (/spl sim/0.93 fF//spl mu/m/sup 2/) having similar capacitance 11.2 pF. The impacts of high-/spl kappa/ insulator and low-/spl kappa/ interconnect dielectric on the mechanism for resonant frequency improvement are distinguished using equivalent circuit analysis. This letter suggests that integrated high-/spl kappa/ MIM could be a promising alternative capacitor structure for future high-performance RF applications.