Oxidized Ta2O5/Si3N4dielectric films on poly-crystalline Si for dRAMs

A dielectric film technology characterized by a novel multilayer structure formed by oxidation of Ta₂O₅/Si₃ N₄ films on polysilicon has been developed to realize high-density dRAMs. The dry oxidation of the Ta₂O₅/Si₃N₄ layers was performed at temperatures higher than 900°C. This film has a capacitance per unit area from 5.5 to 6.0 fF/ μm², which is equivalent to that of a 6.0- to 6.5-nm-thick SiO₂. The leakage current at an effective electric field of 5 MV/cm is less than 10^-9 A/cm². Under such an electric field, the extrapolated time to failure for 50% cumulative failure can be as high as 1000 years     

Reactor characterization for a process to etchSi3N4 formed on thin SiO2

A plasma etching process for patterning LPCVD (low-pressure chemical vapor deposition) Si₃N₄ which has been formed on thin thermally grown SiO₂ has been developed and characterized with an Applied Materials 8110 batch system using 100-mm-diameter silicon wafers. To fulfill the primary process objectives of minimal critical dimension (CD) loss (~0.08 μm), vertical profiles after etch, retention of some of the underlying thermal SiO₂, and batch etch uniformity, the reactor has been characterized by evaluating the effects of variation of reactor pressure (15 to 65 mTorr), O₂ concentration by flow rate (30 to 70%) of an O₂/CHF₂ mixture, and DC bias voltage (-200 to -550 V). Analysis of the resulting etch rate, etch uniformity, dimensional, and profile data suggests that satisfactory processing may be achieved at low reactor pressure (~25 mTorr), 50-60% O₂ by flow rate in O₂/CHF₃, and low DC bias (-200 to -250 V)     

Low threshold current GaAs/AlGaAs GRIN-SCH lasers grown bymolecular beam epitaxy on Si3N4 masked substrates

High-performance single-quantum-well graded-refractive index separate confinement heterostructure (SQW GRINSCH) laser have been grown by molecular beam epitaxy on Si₃N₄ patterned GaAs (100) substrates. Lasers grown on stripe windows orientated in the [011] direction have optical waveguiding and current confinement supplied by facetting occurring during growth. Lasers fabricated on 10 μm wide Si ₃N₄ openings have threshold currents as low as 15 mA for a 500 μm-long cavity. The current density required to reach optical transparency is 144 A/cm²; an internal quantum efficiency of 81%, and a peak optical power of 70 mW per facet has been obtained. Device performance comparable to ridge lasers is observed in a self-aligned laser process     

Effects of post-deposition anneal on the electrical properties ofSi3N4 gate dielectric

The effects of postdeposition anneal of chemical vapor deposited silicon nitride are studied. The Si₃N₄ films were in situ annealed in either H₂(2%)/O₂ at 950°C or N₂O at 950°C in a rapid thermal oxidation system. It is found that an interfacial oxide was grown at the Si₃N₄/Si interface by both postdeposition anneal conditions. This was confirmed by thickness measurement and X-ray photoelectronic spectroscopy (XPS) analysis. The devices with H₂ (2%)/O₂ anneal exhibit a lower gate leakage current and improved reliability compared to that of N₂O anneal. This improvement is attributed to a greater efficiency of generating atomic oxygen in the presence of a small amount of hydrogen, leading to the elimination of structural defects in the as-deposited Si₃N ₄ film by the atomic oxygen. Good drivability is also demonstrated on a 0.12 μm n-MOSFET device     

Photoresponse model for Si1-xGex/Siheterojunction internal photoemission infrared detector

A photoresponse model has been developed for the Si_1-xGe_x/Si heterojunction internal photoemission (HIP) infrared detector at wavelengths corresponding to photon energies less than the Fermi energy. A Si_0.7Ge_0.3/Si HIP detector with a cutoff wavelength of 23 μm and an emission coefficient of 0.4 eV^-1 has been demonstrated. The model agrees with the measured detector response at λ>8 μm. The potential barrier determined by the model is in close agreement (difference ~4 meV) with the potential barrier determined by the Richardson plot, compared to the discrepancies of 20-50 meV usually observed for PtSi Schottky detectors     

A stacked capacitor technology with ECR plasma MOCVD(Ba,Sr)TiO3 and RuO2/Ru/TiN/TiSixstorage nodes for Gb-scale DRAMs

A Gb-scale DRAM stacked capacitor technology with (Ba,Sr)TiO₃ thin films is described, The four-layer RuO₂/Ru/TiN/TiSi_x, storage node configuration allows 500°C processing and fine-patterning down to the 0.20 μm size by electron beam lithography and reactive ion etching. Good insulating (Ba_0.4Sr_0.6)TiO₃ (BST) films with an SiO₂ equivalent thickness of 0.65 nm on the electrode sidewalls and leakage current of 1×10^{-/6 A}cm² at 1 V are obtained by ECR plasma MOCVD without any post-deposition annealing, A lateral step coverage of 50% for BST is observed on the 0.2 μm size storage node pattern, and the BST thickness on the sidewalls is very uniform, thanks to the ECR downflow plasma. Using this stacked capacitor technology, a sufficient cell capacitance of 25 fF for 1 Gb DRAMs can be achieved in a capacitor area of 0.125 μm² with only the 0.3 μm high-storage electrodes     

High-speed performance of Si/Si1-xGexheterojunction bipolar transistors

A theoretical investigation of Si/Si_1-xGe_x heterojunction bipolar transistors (HBTs) undertaken in an attempt to determine their speed potential is discussed. The analysis is based on a compact transistor model, and devices with self-aligned geometry, including both extrinsic and intrinsic parameters, are considered. For an emitter area of 1×5 μm², an f_t of over 75 GHz and f_max of over 35 GHz were computed at a collector current density of 1×10 ⁵ A/cm² and V_CB of 5 V     

The scaled performance of Si/Si1-xGexresonant tunneling diodes

Small area resonant tunneling diodes (RTDs) with strained Si_0.4Ge_0.6 potential barriers and a strained Si quantum well grown on a relaxed Si_0.8Ge_0.2 virtual substrate were fabricated and characterized. A room temperature peak current density (J_P) of 282 kA/cm² with a peak to valley current ratio (PVCR) of 2.43 were recorded for a 5×5 μm ² sample, the highest values reported to date for Si/Si_1-xGe_x RTDs. Scaling of the device size demonstrated a decrease in J_P proportional to an increase in the lateral area of the tunnel junctions, whereas the PVCR remained approximately constant. This observation suggests that the dc behavior of such Si/Si_1-xGe_x RTD design is presently limited by thermal effects     

Two-step annealing technique for leakage current reduction inchemical-vapor-deposited Ta2O5 film

A capacitor technology developed to obtain extremely thin Ta₂ O₅ dielectric film with an effective SiO₂ film thickness down to 3 nm (equivalent to 11 fF/μm²) for a 1.5-V, low-power, high-density, 64-Mb DRAM is discussed. The Ta₂ O₅ has low leakage current, low defect density, and excellent step coverage. The key process is two-step annealing after the deposition of the film by thermal chemical vapor deposition (CVD). The first step involves ozone (O₃) annealing with ultraviolet light irradiation, which reduces the leakage current. The second step is dry oxygen (O₂) annealing, which decreases the defect density. A more significant reduction in the leakage current is attained by the combination of the two annealing steps     

Electrical Characteristics of Memory Devices With a High- k HfO2 Trapping Layer and Dual SiO2/Si3N4 Tunneling Layer

A novel device structure with a high-k HfO₂ charge storage layer and dual tunneling layer (DTL) (SiO₂/Si₃N₄) is presented in this paper. Combining advantages of the high trapping efficiency of high-k materials and enhanced charge injection from the substrate through the DTL, the device achieves a fast program/erase speed and a large memory window. The device demonstrates excellent retention due to its physically thick DTL and also improved endurance without any increase of programming V_th throughout the cyclic test as compared with SONOS Flash memory devices using an Si₃N₄ trapping layer.     

Reactive ion etching of Ta-Si-N diffusion barriers in CHF3+O2

Reactive ion etching of Ta₃₆Si₁₄N₅₀ diffusion barrier layers was performed in CHF₃+O₂ plasmas. Etch depths and rates were determined as a function of etch gas composition, cathode power, and etching time. Etching proceeds only after an initial delay which depends on gas composition and cathode power. This delay is attributed to the presence of a native surface oxide which must first be removed before etching can commence. Maximum etch rate was attained at 62.5% O₂ concentration, which also corresponds to minimum delay     

A high performance MIM capacitor using HfO2 dielectrics

Metal-insulator-metal (MIM) capacitors with a 56 nm thick HfO₂ high-κ dielectric film have been fabricated and demonstrated for the first of time with a low thermal budget (~200°C). Voltage linearity, temperature coefficients of capacitance, and electrical properties are all characterized. The results show that the HfO₂ MIM capacitor can provide a higher capacitance density than Si₃N₄ MIM capacitor while still maintaining comparable voltage and temperature coefficients of capacitance. In addition, a low leakage current of 2×10^-9 A/cm² at 3 V is achieved. All of these make the HfO ₂ MIM capacitor to be very suitable for use in silicon RF and mixed signal IC applications     

Formation of high quality storage capacitor dielectrics by in-siturapid thermal reoxidation of Si3N4 films inN2O ambient

This letter reports on a novel reoxidation technique for SiO₂ /Si₃N₄ (ON) stacked films by using N₂ O as oxidant. Effect of in-situ rapid thermal N₂O reoxidation (RTNO) on the electrical characteristics of thin ON stacked films are studied and compared with those of in-situ rapid thermal. O ₂ reoxidation (RTO). Prior to reoxidation, the Si₃N₄ film was deposited by rapid thermal chemical vapor deposition (RT-CVD) using SiH₄ and NH₃. Results show that RTNO of the Si₃N₄ films significantly improves electrical characteristics of ON stacked films in terms of lower leakage current, suppressed charge trapping, reduced defect density and improved time-dependent-dielectric-breakdown (TDDB), as compared to RTO of the Si₃N₄ films     

Responsivity and impact ionization coefficients ofSi1-xGex photodiodes

The spectral response and impact ionization coefficient ratio of Si_1-xGe_x have been determined. Measurements were made on p⁺-i-n⁺ diodes grown by solid/gas source molecular beam epitaxy. The diodes are characterized by reverse breakdown voltages of 4-12 V and dark currents of 20-170 pA/μm² . The long wavelength cut-off of the diodes increases from 1.2 μm to 1.6 μm as x increases from 0.08 to 1.0 with a maximum responsivity of 0.5 A/W in all the diodes tested. The ratio α/β varies from 3.3 to 0.3 in the same composition range, with α/β=1 at x≅0.45. These results have important implications in the use of this material system in various photodetection applications     

Effect of bottom electrode materials on the electrical andreliability characteristics of (Ba, Sr)TiO3 capacitors

The dielectric constant and the leakage current density of (Ba, Sr)TiO₃ (BST) thin films deposited on various bottom electrode materials (Pt, Ir, IrO₂/Ir, Ru, RuO₂/Ru) before and after annealing in O₂ ambient were investigated. The improvement of crystallinity of BST films deposited on various bottom electrodes was observed after the postannealing process. The dielectric constant and leakage current of the films mere also strongly dependent on the postannealing conditions. BST thin film deposited on Ir bottom electrode at 500°C, after 700°C annealing in O₂ for 20 min, has the dielectric constant of 593, a loss tangent of 0.019 at 100 kHz, a leakage current density of 1.9×10 ^-8 A/cm² at an electric field of 200 kV/cm with a delay time of 30 s, and a charge storage density of 53 fC/μm² at an applied field of 100 kV/cm. The BST films deposited on Ir with post-annealing can obtain better dielectric properties than on other bottom electrodes in our experiments. And Ru electrode is unstable because the interdiffusion of Ru and Ti occurs at the interface between the BST and Ru after postannealing. The ten year lifetime of time-dependent dielectric breakdown (TDDB) studies indicate that BST on Pt, Ir, IrO₂/Ir, Ru, and RuO₂/Ru have long lifetimes over ten gears on operation at the voltage bias of 2 V     

Low-resistance bandgap-engineeredW/Si1-xGex/Si contacts

Bandgap-engineered W/Si_1-xGe_x/Si junctions (p⁺ and n⁺) with ultra-low contact resistivity and low leakage have been fabricated and characterized. The junctions are formed via outdiffusion from a selectively deposited Si_0.7Ge _0.3 layer which is implanted and annealed using RTA. The Si _1-xGe_x layer can then be selectively thinned using NH₄OH/H₂O₂/H₂O at 75°C with little change in characteristics or left as-deposited. Leakage currents were better than 1.6×10^-9 A/cm² (areal), 7.45×10^-12 A/cm (peripheral) for p⁺/n and 3.5×10^-10 A/cm² (peripheral) for n⁺/p. W contacts were formed using selective LPCVD on Si_1-xGe_x. A specific contact resistivity of better than 3.2×10^-8 Ω cm² for p ⁺/n and 2.2×10^-8 Ω cm² for n⁺/p is demonstrated-an order of magnitude n⁺ better than current TiSi₂ technology. W/Si_1-xGe _x/Si junctions show great potential for ULSI applications     

Silicide/strained Si1-xGex Schottky-barrierinfrared detectors

By employing a thin silicon sacrificial cap layer for silicide formation, the authors successfully demonstrated Pd₂Si/strained Si_1-xGe_x Schottky-barrier infrared detectors with extended cutoff wavelengths. The sacrificial silicon eliminates the segregation effects and Fermi level pinning which occur if the metal reacts directly with Si_1-x Ge_x alloy. The Schottky barrier height of the silicide/strained Si_1-xGe_x detector decreases with increasing Ge fraction, allowing for tuning of the detector's cutoff wavelength. The cutoff wavelength was extended beyond 8 μm in PtSi/Si _0.85Ge_0.15 detectors. It is shown that high quantum efficiency and near-ideal dark current can be obtained from these detectors     

SiGe pMODFETs on silicon-on-sapphire substrates with 116 GHzfmax

The dc and microwave results of Si_0.2Ge_0.8/Si_0.7Ge_0.3 pMODFETs grown on silicon-on-sapphire (SOS) substrates by ultrahigh vacuum chemical vapor deposition are reported. Devices with L_g=0.1 μm displayed high transconductance (377 mS/mm), low output conductance (25 mS/mm), and high gate-to-drain breakdown voltage (4 V). The dc current-voltage (I-V) characteristics were also nearly identical to those of control devices grown on bulk Si substrates. Microwave characterization of 0.1×50 μm² devices yielded unity current gain (f_T) and unilateral power gain (f _max) cutoff frequencies as high as 50 GHz and 116 GHz, respectively. Noise parameter characterization of 0.1×90 μm² devices revealed minimum noise figure (F_min) of 0.6 dB at 3 GHz and 2.5 dB at 20 GHz     

Si/Si1-xGex heterojunction bipolartransistors produced by limited reaction processing

Si/Si_1-xGe_x heterojunction transistors (HBTs) fabricated by a chemical vapor deposition (CVD) technique are reported. A rapid thermal CVD limited-reaction processing (LRP) technique was used for the in situ growth of all three device layers, including a 20-mm Si_1-xGe_x layer in the base. The highest current gains observed (β=400) were for a Si/Si_1-x Ge_x HBT with a base doping of 7×10¹⁸ cm^-3 near the junction and a shallow arsenic implant to form ohmic contacts and increase current gain. Ideal base currents were observed for over six decades of current and the collector current remained ideal for nearly nine current decades starting at 1 pA. The bandgap difference between a p-type Si layer doped to 5×10¹⁷ cm^-3 and the Si_1-xGe_x(x=0.31) base measured 0.27 eV. This value was deduced from the measurements of the temperature dependence of the base current and is in good agreement with published calculations for strained Si_1-xGe_x layers on Si     

The degradation of TDDB characteristics of Si02/Si3N4/Si02 stacked films caused by surfaceroughness of Si3N4 films [DRAMs]

The effect of surface roughness of Si₃N₄ films on time-dependent dielectric breakdown (TDDB) characteristics of SiO₂/Si₃N₄/SiO₂ (ONO) stacked films was investigated. The surface roughness of Si₃N ₄ films-was found to become higher with increasing deposition temperature and to cause the degradation of TDDB characteristics of ONO films in DRAMs. A local thinning of ONO films, evaluated from the TDDB characteristics, agreed with the surface roughness measured by atomic force microscopy (AFM) and cross-sectional transmission electron microscopy (XTEM). Dependence of time to breakdown of ONO films on the deposition conditions was interpreted by electric field intensification due to the surface roughness of Si₃N₄ films