Analytical models for n+-p+ double-gate SOIMOSFET's

Previously, we proposed n⁺-p⁺ double-gate SOI MOSFET's, which have n⁺ polysilicon for the back gate and p⁺ polysilicon for the front gate to enable adjustment of the threshold voltage, and demonstrated high speed operation. In this paper, we establish analytical models for this device, This transistor has two threshold voltages related to n⁺ and p⁺ polysilicon gates: V_th1 and V_th2, respectively. V _th1 is a function of the gate oxide thickness t_Ox and SOI thickness t_Si and is about 0.25 V when t_Ox/t_Si=5, while V_th2 is insensitive to t_Ox and t_Si and is about 1 V. We also derive models for conduction charge and drain current and verified their validity by numerical analysis. Furthermore, we establish a scaling theory unique to the device, and show how to design the device parameters with decreasing gate length. We show numerically that we can design sub 0.1 μm gate length devices with an an appropriate threshold voltage and an ideal subthreshold swing     

Suppression of cobalt silicide agglomeration using nitrogen(N2+) implantation

In this paper, the effects of nitrogen coimplantation with boron into p⁺-poly gate in PMOSFETs on the agglomeration effects of CoSi₂ are studied. The thermal stability of CoSi₂/poly-Si stacked layers can be significantly improved by using nitrogen implantation. Samples with 40-nm cobalt silicide (CoSi ₂) on 210-nm poly-Si implanted by 2×10¹⁵/cm ² N₂⁺ are thermally stable above 950°C for 30 s in N₂ ambient. If the dose of nitrogen is increased up to 6×10¹⁵/cm², the sheet resistance of CoSi₂ film is not increased at all, and TEM photographs show that the agglomeration of CoSi₂ film is completely suppressed     

n+/p+ Gate Bulk FinFETs With Locally Separated Channel Structure for Sub-50-nm DRAM Cell Transistors

We proposed a new p⁺/n⁺ poly-Si gate bulk fin-type field-effect transistor that has two channel fins separated locally by a shallow trench filled with oxide or p⁺ polygate. Key device characteristics were investigated by changing the n⁺ poly-Si gate length La, the material filling the trench, and the width and length of the trench at a given gate length L_g. It was shown that the trench filled with p⁺ poly-Si gate should not be contacted with the source/drain diffusion region to achieve an excellent I_on/I_off (> 1010) that is suitable for sub-50-nm dynamic random access memory cell transistors. Based on the aforementioned device structure, we designed reasonable Ls/Lg and channel fin width W_cfin at given L_g 's of 30, 40, and 50 nm.     

Bias temperature instability in scaled p+ polysilicongate p-MOSFET's

The bias temperature instability in surface-channel p⁺ polysilicon gate p-MOSFETs was evaluated. It was found that a large negative threshold voltage shift (ΔV_th,BT) is induced by negative bias temperature (BT) stress in short-channel p⁺ polysilicon gate p-MOSFETs. This Vth shift, which depends on the gate length of p-MOSFETs, is a new degradation mode. In this degradation, the negative ΔV_th,BT increases significantly with a reduction in the gate length. It was shown that this is because of the local degradation of the gate oxide near the gate edge. This degradation is caused by the electrochemical reaction between holes and oxide defects and it is enhanced by boron penetration through the gate oxide from p⁺-gate. For the bias temperature instability in p⁺ -gate p-MOSFETs, sufficient care should be taken in scaled dual-gate CMOS devices     

A comprehensive study on p+ polysilicon-gate MOSFET'sinstability with fluorine incorporation

It is reported that fluorine can jeopardize p⁺-gate devices under moderate annealing temperatures. MOSFETs with BF₂ or boron-implanted polysilicon gates were processed identically except at gate implantation. Evidence of boron penetration through 12.5-nm oxide and a large quantity of negative charge penetration (10 ¹² cm^-2) by fluorine even at moderate annealing conditions is reported. The degree of degradation is aggravated as fluorine dose increases. A detailed examination of the I-V characteristics of PMOSFET with fluorine incorporated p⁺-gate revealed that the long gate-length device had abnormal abrupt turn-on I_d-V_g characteristics, while the submicrometer-gate-length devices appeared to be normal. The abnormal turn-on I_d-V_g characteristics associated with long-gate-length p⁺-gate devices vanished when the device was subjected to X-ray irradiation and/or to a high-voltage DC stressing at the source/drain. The C-V characteristics of MOS structures of various gate dopants, processing ambients, doping concentrations, and annealing conditions were studied. Based on all experimental results, the degradation model of p⁺-gate devices is presented. The incorporation of fluorine in the p⁺ gate enhances boron penetration through the thin gate oxide into the silicon substrate and creates negative-charge interface states. The addition of H/OH species into F-rich gate oxide will further aggravate the extent of F-enhanced boron penetration by annealing out the negative-charge interface states     

Effect of electron cyclotron resonance H+,Ne+, Ar+, and Xe+ plasma precleaning ontitanium silicide formation

A vacuum integrated cluster tool process incorporating electron cyclotron resonance plasma cleaning, Ti sputter deposition, and rapid thermal annealing in N₂ is used to form a TiN_x<1/TiSi_y bilayer on (100) Si where the film composition is controlled by the preclean chemistry. Chemical cleaning with nominal 10 eV H⁺ completely removes native Si oxide resulting in a hydrogen terminated surface that promotes silicidation compared to one cleaned with buffered-oxide-etching (BOE). If the native oxide is only partially reduced, viz., SiO_x<2 surface, for example by shortening the H⁺ exposure time, then silicidation is largely inhibited and a thicker nitride layer is formed. Sputter cleaning with 50 to 250 eV Ar⁺ results in a bilayer that is roughly equivalent to that formed with BOE, whereas 50 to 150 eV Xe⁺ bombardment favors nitridation. Precleaning with >150 eV Ne⁺ promotes silicidation, thereby minimizing nitride thickness. The effects of precleaning are significant as the activation energy for TiSi_y formation is reduced from 1.8 eV characteristic of a BOE cleaned surface to 1.2 eV on Si etched with 250 eV Ne⁺. Mechanistically, the silicide kinetics are shown to be inhibited by the presence of a thin amorphous layer that is formed only when cleaning Si with Ar⁺ and Xe⁺ with the effect that both knock-on oxygen atoms and implanted noble gas atoms trapped within the amorphous layer retard the requisite solid-phase epitaxial regrowth kinetics. Recrystallizing the amorphous Si surface prior to metallization appears to restore the near-normal silicide kinetics that is characteristic of Ne⁺ cleaning     

Argon ion-implantation on polysilicon or amorphous-silicon forboron penetration suppression in p+ pMOSFET

In this paper, a technique to use Ar ion-implantation on the p⁺α-Si or poly-Si gate to suppress the boron penetration in p⁺ pMOSFET is proposed and demonstrated. An Ar-implantation of a dose over 5×10¹⁵ cm^-2 is shown to be able to sustain 900°C annealing for 30 min for the gate without having the underlying gate oxide quality degraded. It is believed to be due to gettering of fluorine, then consequently boron, by the bubble-like defects created by the Ar implantation in the p⁺ gate region to reduce the B penetration. Excellent electrical characteristics like dielectric breakdown (E_bd), interface state density (D_it), and charge-to-breakdown (Q_bd) on the gate oxide are obtained. The technique is compatible to the present CMOS process. The submicron pMOSFET fabricated by applying this technique exhibit better subthreshold characteristics and hot carrier immunity     

Plasma damage immunity of thin gate oxide grown on very lightly N+ implanted silicon

Plasma damage immunity of gate oxide grown on very low dose (2×10¹³/cm²) N⁺ implanted silicon is found to be improved compared to a regular gate oxide of similar thickness. Both hole trapping and electron trapping are suppressed by the incorporation of nitrogen into the gate oxide. Hole trapping behavior was determined from the relationship between initial electron trapping slope (IETS) and threshold voltage shifts due to current stress. This method is believed to be far more reliable than the typical method of initial gate voltage lowering during current stress     

Analytical threshold voltage model for short channeln+-p+ double-gate SOI MOSFETs

Solving a two-dimensional (2-D) Poisson equation in the channel region, we have developed models for short channel n⁺-p⁺ double-gate SOI MOSFETs, and showed how to design a device with a decreased gate length, suppressing short channel threshold voltage shift ΔVth and subthreshold swing (S-swing) degradation. According to our model, we can design a 0.05 μm L_G device of which threshold voltage is 0.2 V, ΔVth is 25 mV, and S-swing is 65 mV/decade with a 3-nm-thick gate oxide and 12-nm-thick SOI     

Device simulation of submicrometer gate p+-i-p+ diamond transistors

Two-dimensional device simulation of submicrometer gate diamond p ⁺-i-p⁺ transistors with a SiO₂ gate insulator was investigated using the MEDICI device simulation program. A large modulation of the source-to-drain current was obtained in the accumulation mode. The computed diamond device characteristics were equivalent or better than the simulation results of 6H-SiC MESFET's. It was concluded that the problems in diamond MESFET associated with the deep acceptor levels due to boron doping can be overcome in the p⁺ -i-p⁺ diamond FET's because of the hole injection and the space charge limited current     

A novel dual p-/p+ poly gate CMOS VLSItechnology

A CMOS VLSI technology using p^- and p⁺ poly gates for NMOS and PMOS devices is presented. Due to the midgap work function of the p^- poly gate, the NMOS native threshold voltage is 0.7 V and, therefore, no additional threshold adjust implantation is required. The NMOS transistor is a surface-channel device with improved field-effect mobility and lower body effect due to the reduction in the channel doping concentration. In addition, the p ^- poly gate is shown to be compatible with p⁺ poly-gated surface-channel PMOS devices     

Gate current and oxide reliability in p+ poly MOScapacitors with poly-Si and poly-Ge0.3Si0.7 gatematerial

Fowler-Nordheim (FN) tunnel current and oxide reliability of PRiLOS capacitors with a p⁺ polycrystalline silicon (poly-Si) and polycrystalline germanium-silicon (poly-Ge_0.3Si_0.7 ) gate on 5.6-nm thick gate oxides have been compared. It is shown that the FN current depends on the gate material and the bias polarity. The tunneling barrier heights, φ_B, have been determined from FN-plots. The larger barrier height for negative bias, compared to positive bias, suggests that electron injection takes place from the valence band of the gate. This barrier height for the GeSi gate is 0.4 eV lower than for the Si gate due to the higher valence band edge position. Charge-to-breakdown (Q_bd) measurements show improved oxide reliability of the GeSi gate on of PMOS capacitors with 5.6 nm thick gate oxide. We confirm that workfunction engineering in deep submicron MOS technologies using poly-GeSi gates is possible without limiting effects of the gate currents and oxide reliability     

A comprehensive study of suppression of boron penetration byamorphous-Si gate in P+-gate PMOS devices

This paper presents a comprehensive study of the impact of the silicon gate structure on the suppression of boron penetration in p⁺-gate devices. The characteristics and reliability for different gate structures (poly-Si, α-Si, poly-Si/poly-Si, poly-Si/α-Si, α-Si/poly-Si, and α-Si/α-Si) in p ⁺ polygate PMOS devices are investigated in detail. The suppression of boron penetration by the nitrided gate oxide is also discussed. The comparison is based on flatband voltage shift as well as the value of charge to breakdown. Results show that the effect of boron diffusion through the thin gate oxide in p⁺ polygate PMOS devices can be significantly suppressed by employing the as-deposited amorphous silicon gate. Stacked structures can also be employed to suppress boron penetration at the expense of higher polygate resistance. The single layer as-deposited amorphous silicon is a suitable silicon gate material in the p⁺-gate PMOS device for future dual-gate CMOS process. In addition, by employing a long time annealing at 600°C prior to p⁺-gate ion implantation and activation, further improvements in suppression of boron penetration, polygate resistance, and gate oxide reliability can be achieved for the as-deposited amorphous-Si gate. Modifying the silicon gate structure instead of the gate dielectrics is an effective approach to suppress the boron penetration effect     

Impact of nitrogen (N2+) implantation intopolysilicon gate on thermal stability of cobalt silicide formed onpolysilicon gate

A novel process which uses N₂⁺ implantation into polysilicon gates to suppress the agglomeration of CoSi₂ in polycide gated MOS devices is presented. The thermal stability of CoSi₂/polysilicon stacked layers can be dramatically improved by using N₂⁺ implantation into polysilicon. The sheet resistance of the samples without N₂⁺ implantation starts to increase after 875°C RTA for 30 s, while the sheet resistance of CoSi₂ film is not increased at all after 950 and 1000°C RTA for 30 s if the dose of nitrogen is increased up to 2×10¹⁵ cm^-2 and 6×10¹⁵ cm², respectively, and TEM photographs show that the agglomeration of CoSi₂ film is completely suppressed. It is found that the transformation to CoSi₂ from CoSi is impeded by N₂⁺ implantation such that the grain size of CoSi₂ with N₂⁺ implantation is much smaller than that without N₂⁺ implantation. As a result, the thermal stability of CoSi₂ is significantly improved by N₂⁺ implantation into polysilicon     

Technology limitations for N+/P+ polycidegate CMOS due to lateral dopant diffusion in silicide/polysilicon layers

The device degradation of dual-polycide-gate N⁺/P⁺ CMOS polycide transistors due to the lateral diffusion of dopants in the silicides is studied using a coupled 2-D process and device simulator. Design rule spacings between the NMOS and the PMOS transistor are given for various NMOS:PMOS gate area ratios and thermal processing conditions. The simulations show that contrary to previous findings, micrometer and submicrometer spacings are possible for certain silicide technologies using low-temperature or short higher-temperature furnace steps. Simulations show that CoSi₂ and TiSi₂ appear to be better candidates for submicrometer dual-gate applications than WSi₂     

MBE grown n+-i-δ(p+)-i-n+GaAs V-groove barrier transistor

The three-terminal n⁺-i-δ(p⁺)-i-n⁺V-groove barrier transistor (VBT) has been successfully fabricated by molecular beam epitaxy (MBE). The base terminal is connected to the δ(p⁺), the thin p⁺layer, by depositing aluminum on the etched V-groove. The demonstrated device possesses high potential of ultra-high-frequency (f_{r} > 30-GHz), high-power, and low-noise capability due to carriers transporting by thermionic emission and being controlled by the base-emitter bias.     

Evidence of hole direct tunneling through ultrathin gate oxideusing P+ poly-SiGe gate

P⁺ poly-Si and poly-Si_0.75Ge_0.25-gated PMOS transistors with ultrathin gate oxides of 25 and 29 Å were used for this study. The difference in the gate work function was used to determine the mechanisms of gate tunneling current in such thin gate oxides, Under negative gate bias (inversion bias), it was found that the source/drain terminal serves as a source of holes for small V_g value, and as gate bias increases (more negative), it becomes a hole sink. These observations can be interpreted in terms of two competing mechanisms. For the first time, hole direct tunneling is reported, Hole direct tunneling is the dominant mechanism for -2 Vg<0 V. For Vg<-2 V, electron direct tunneling is dominant. Electron-hole pair generation by the tunneling electrons starts to dominate over hole direct tunneling only for V_g<-4 V     

Anomalous reverse short-channel effect in p+ polysilicongated P-channel MOSFET

The boron-penetration-dependent Reverse Short Channel Effect (RSCE) on the threshold voltage is observed for short channel p⁺ poly-gate PMOSFET's. The RSCE is found to be more significant as the boron penetration becomes more severe. The RSCE is significant in BF ₂ doped poly-gated MOS devices and is alleviated in buffered poly-gated MOS devices. Fluorine enhanced boron diffusion in the gate oxide during high temperature process is believed to account for the RSCE, which is also confirmed by using a two-dimensional process simulator     

Stress-induced leakage current in p+ poly MOS capacitorswith poly-Si and poly-Si0.7Ge0.3 gatematerial

The gate bias polarity dependence of stress-induced leakage current (SILC) of PMOS capacitors with a p⁺ polycrystalline silicon (poly-Si) and polycrystalline Silicon-Germanium (poly-Si_0.7 Ge_0.3) gate on 5.6-nm thick gate oxides has been investigated. It is shown that the SILC characteristics are highly asymmetric with gate bias polarity. This asymmetric behavior is explained by the occurrence of a different injection mechanism for negative bias, compared to positive bias where Fowler-Nordheim (FN) tunneling is the main conduction mechanism. For gate injection, a larger oxide field is required to obtain the same tunneling current, which leads to reduced SILC at low fields. Moreover, at negative gate bias, the higher valence band position of poly-SiGe compared to poly-Si reduces the barrier height for tunneling to traps and hence leads to increased SILC. At positive gate bias, reduced SILC is observed for poly-SiGe gates compared to poly-Si gates. This is most likely due to a lower concentration of Boron in the dielectric in the case of poly-SiGe compared to poly-Si. This makes Boron-doped poly-SiGe a very interesting gate material for nonvolatile memory devices     

Er3+-Yb3+ and Er3+ doped fiberlasers

Single-mode fiber lasers operating at ~1.57 μm are described. Output powers of >2 mW are reported for laser diode pumped operation. Direct comparison is made between fiber lasers using sensitized erbium (Er³⁺ and Yb³⁺) and erbium on its own. The performance of Er³⁺-Yb³⁺ fiber lasers is analyzed in more detail as a function of fiber length. Both CW and Q-switched operations are studied and the results obtained demonstrate that practical sources at 1.5 μm are available from diode pumped Er³⁺ -Yb³⁺ systems