Stability of short-channel P-channel polysilicon thin-filmtransistors with ECR N2O-plasma gate oxide

Stability of hydrogenated short-channel (⩽3 μm) p-channel poly-Si TFT's with very thin (12 nm) electron cyclotron resonance N₂O plasma gate oxide is investigated. The fabricated poly-Si TFT's with gate length not less than 2 μm show excellent stability characteristics of less than 0.1 V in the threshold voltage shift and less than 3% in the percent change of transconductance after harsh electrical stresses. In a small |V_G| stress, an effective shortening of channel length is observed due to trapping of hot-electrons and the minimum leakage current is decreased. However, a large |V_G| stress causes more degradation on the subthreshold slope and minimum leakage current due to trapping of hot-holes     

Performance and off-state current mechanisms of low-temperatureprocessed polysilicon thin-film transistors with liquid phase depositedSiO2 gate insulator

Polysilicon thin-film transistors (poly-Si TFT's) with liquid phase deposition (LPD) silicon dioxide (SiO₂) gate insulator were realized by low-temperature processes (<620°C). The physical, chemical, and electrical properties of the new dielectric layer were clarified. The low-temperature processed (LTP) poly-Si TFT's with W/L=200 μm/10 μm had an on-off current ratio of 4.95×10 ⁶ at V_D=5 V, a field effect mobility of 25.5 cm ²/V·s at V_D=0.1 V, a threshold voltage of 6.9 V, and a subthreshold swing of 1.28 V/decade at V_D=0.1 V. Effective passivation of defects by plasma hydrogenation can improve the characteristics of the devices. The off-state current (I_L) mechanisms of the LTP poly-Si TFT's were systematically compared and clarified. The I_L is divided into three regions; the I_L is attributable to a resistive current in region I (low gate bias), to pure thermal generation current in region II (low drain bias), and to Frenkel-Poole emission current in region III (high gate bias and drain bias)     

Study on hydrogenation of polysilicon thin film transistors by ionimplantation

Hydrogenation of polysilicon (poly-Si) thin film transistors (TFT's) by ion implantation has been systematically studied. Poly-Si TFT performance was dramatically improved by hydrogen ion implantation followed by a forming gas anneal (FGA). The threshold voltage, channel mobility, subthreshold swing, leakage current, and ON/OFF current ratio have been studied as functions of ion implantation dose and FGA temperature. Under the optimized conditions (H⁺ dose of 5×10¹⁵ cm^-2 and FGA temperature at 375°C), NMOS poly-Si TFT's fabricated by a low temperature 600°C process have a mobility of ~27 cm ²/V·s, a threshold voltage of ~2 V, a subthreshold swing of ~0.9 V/decade, and an OFF-state leakage current of ~7 pA/μm at V_DS=10 V. The avalanche induced kink effect was found to be reduced after hydrogenation     

Stability of N-channel polysilicon thin-film transistors with ECRplasma thermal gate oxide

The effects of electrical stress on n-channel polysilicon thin-film transistors (poly-Si TFTs) with electron cyclotron resonance (ECR) plasma gate oxide have been investigated. The plasma-hydrogenerated low-temperature (⩽600°C) TFT's exhibited very a small increase of threshold voltage (ΔV_th<0.3 V) under the stress conditions (V_gs=15 V, V_ds=0 V ~15 V, and stress time=5×10⁴ s). The ΔV_t h was larger for the stress in the linear region than in the saturation region. It was found that the device degradation for the stress in the saturation region was caused by the hot-carriers. Increase of OFF current was maximum for the stress at V_gs=V_ds while for the stress at V_gsds, degradation of transconductance was the dominant effect seen     

Electrical characteristics of new LDD poly-Si TFT structuretolerant to process misalignment

A new lightly doped drain (LDD) poly-Si TFT structure having symmetrical electrical characteristics independent of the process induced misalignment is described in this paper. Based on the experimental results, we have established that there is no difference between the bi-directional I_D-V_G characteristics, and a low leakage current, comparable to a conventional LDD poly-Si TFT, has been maintained for this new poly-Si TFT. The maximum ON/OFF current ratio of about 1×10⁸ is obtained for the LDD length of 1.0 μm. In addition, the kink effect in the output characteristics has been remarkably improved in the new TFTs in comparison to the conventional non-LDD single- or dual-gate TFTs     

Polished TFT's: surface roughness reduction and its correlation todevice performance improvement

Chemical-mechanical polishing (CMP) has been applied to the fabrication of n-channel polysilicon thin film transistors (poly-Si TFT's). Three different polishing conditions are compared: (1) polishing before; (2) polishing after; and (3) both polishing before and after the a-Si recrystallization. Devices with no polishing act as control samples. Experiments consistently reveal that devices with post-anneal polishing exhibit the best performance, Two-fold improvement of drain current is attributed to the smoother active polysilicon surface. The electrical characteristics of a post-anneal polished TFT in terms of field effect mobility μ_FE, threshold voltage V_T, and subthreshold swing S can be further improved if hydrogenation is employed. It is also found that a large decrease in the poly-Si surface roughness leads to higher dielectric breakdown strength and improved short-channel effects. Atomic force microscopy (AFM) and transmission electron microscopy (TEM) results are presented and correlated with electrical results     

Performance improvement obtained for thin-film transistorsfabricated in prepatterned laser-recrystallized polysilicon

Thin-film transistors (TFT's) are fabricated in polysilicon films that are laser recrystallized either before or after active-area definition. We find the the performance of TPT's fabricated in active areas that are prepatterned before laser recrystallization is dramatically improved. For example, the field-effect mobility is increased by a factor of three, the threshold voltage is reduced from 5.32 V to 0.07 V, and the subthreshold slope is cut in half for W/L = 10 μm/10 μm TFT's. All TFT's discussed utilize gas-immersion laser-doped source and drain junctions and are unhydrogenated     

High performance poly-Si TFTs fabricated using pulsed laserannealing and remote plasma CVD with low temperature processing

Key technologies for fabricating polycrystalline silicon thin film transistors (poly-Si TFTs) at a low temperature are discussed. Hydrogenated amorphous silicon films were crystallized by irradiation of a 30 ns-pulsed XeCl excimer laser. Crystalline grains were smaller than 100 nm. The density of localized trap states in poly-Si films was reduced to 4×10¹⁶ cm^-3 by plasma hydrogenation only for 30 seconds. Remote plasma chemical vapor deposition (CVD) using mesh electrodes realized a good interface of SiO ₂/Si with the interface trap density of 2.0×10¹⁰ cm^-2 eV^-1 at 270°C. Poly-Si TFTs were fabricated at 270°C using laser crystallization, plasma hydrogenation and remote plasma CVD. The carrier mobility was 640 cm²/Vs for n-channel TFTs and 400 cm²/Vs for p-channel TFTs. The threshold voltage was 0.8 V for n-channel TFTs and -1.5 V for p-channel TFTs. The leakage current of n-channel poly-Si TFTs was reduced from 2×10^-10 A/μm to 3×10^-13 A/μm at the gate voltage of -5 V using an offset gate electrode with an offset length of 1 μm     

High-performance CMOS circuits fabricated by excimer-laser-annealedpoly-Si TFTs on glass substrates

High-performance CMOS circuits are fabricated from excimer-laser-annealed poly-Si TFTs on a glass substrate (300×300 mm). The propagation delay time of the 121 stage CMOS ring oscillators with 0.5 μm gate length is 0.18 nsec at 5 V supply voltage. The maximum operating frequency of the 40-stage shift registers with 1 μm gate length is 133 MHz at 5 V supply voltage. This value is high enough for peripheral CMOS circuits with line-at-a-time addressing     

A self-aligned gate lightly doped drain (Al, Ga)As/GaAs MODFET

An asymmetrical lightly doped drain (LDD) (Al, Ga)As/GaAs modulation-doped FET (MODFET) structure with high drain-to-source and drain-to-gate breakdown voltages was fabricated. The LDD structure has a self-aligned lightly doped n^- region between the channel and a heavily doped n⁺ region at the drain, to reduce the electric field and impact ionization. The length of the lightly doped n ^- region on the drain side was varied from 0 to 1 μm. Drain-to-source breakdown voltage BV_ds improved from 4.6 to >10 V while the transconductance g_m remained unchanged. The drain-to-gate reverse breakdown voltage BV _dg increased from ≈7 to >20 V. The two breakdown mechanisms are believed to be independent. The LDD MODFET should find widespread application in circuits requiring high breakdown voltage such as high-speed analog-to-digital converters (ADCs) and microwave power amplifiers     

Low temperature polycrystalline silicon thin film transistor withsilicon nitride ion stopper

The authors have fabricated a new low temperature polycrystalline silicon (poly-Si) thin film transistor (TFT) with silicon nitride (SiN _x) ion-stopper and laser annealed poly-Si. The fabricated poly-Si TFT using SiN_x as the ion-stopper as well as the gate insulator exhibited a field effect mobility of 110 cm²/Vs, subthreshold voltage of 5.5 V, subthreshold slope of 0.48 V/dec., and on/off current ratio of ~10⁶. Low off-state leakage current of 2.4×10^-2 A/μm at the drain voltage of 5 V and the gate voltage of -5 V was achieved     

The effects of NH3 plasma passivation on polysiliconthin-film transistors

The NH₃ plasma passivation has been performed for the first time on the polycrystalline silicon (poly-Si) thin-film transistors (TFT's). It is found that the TFT's after the NH₃ plasma passivation achieve better device performances, including the off-current below 0.1 pA/μm and the on/off current ratio higher than 10⁸, and also better hot-carrier reliability as well as thermal stability than the H₂-plasma devices. These improvements were attributed to not only the hydrogen passivation of the grain-boundary dangling bonds, but also the nitrogen pile-up at SiO₂/poly-Si interface and the strong Si-N bond formation to terminate the dangling bonds at the grain boundaries of the polysilicon films     

High performance low-temperature poly-Si n-channel TFTs for LCD

High-performance poly-Si TFTs were fabricated by a low-temperature 600°C process utilizing hard glass substrates. To achieve low threshold voltage (V_TH) and high field-effect mobility (μ_FE), the conditions for low-pressure chemical vapor deposition of the active layer poly-Si were optimized. Effective hydrogenation was studied using a multigate (maximum ten divisions) and thin-poly-Si-gate TFTs. The crystallinity of poly-Si after thermal annealing at 600°C depended strongly on the poly-Si deposition temperature and was maximum at 550-560°C. The V_TH and μ_FE showed a minimum and a maximum, respectively, at that poly-Si deposition temperature. The TFTs with poly-Si deposited at 500°C and a 1000-Å gate had a V _TH of 6.2 V and μ_FE of 37 cm²/V-s. The high-speed operation of an enhancement-enhancement type ring oscillator showed its applicability to logic circuits. The TFTs were successfully applied to 3.3-in.-diagonal LCDs with integration of scan and data drive circuits     

An SOI LDMOS/CMOS/BJT technology for integrated power amplifiersused in wireless transceiver applications

This paper describes a SOI LDMOS/CMOS/BJT technology that can be used in portable wireless communication applications. This technology allows the complete integration of the front-end circuits with the baseband circuits for low-cost/low-power/high-volume single-chip transceiver implementation. The LDMOS transistors (0.35 μm channel length, 3.8 μm drift length, 4.5 GHz f_T and 21 V breakdown voltage), CMOS transistors (1.5 μm channel length, 0.8/-1.2 V threshold voltage), lateral NPN transistor (18 V BV_CBO and h _FE of 20), and high Q-factor (up to 6.1 at 900 MHz and 7.2 at 1.8 GHz) on-chip inductors are fabricated. A fully-functional high performance integrated power amplifier for 900 MHz wireless transceiver application is also demonstrated     

Effects of NH3 plasma passivation on N-channelpolycrystalline silicon thin-film transistors

The NH₃-plasma passivation has been performed on polycrystalline silicon (poly-Si) thin-film transistors (TFT's), It is found that the TFT's after the NH₃-plasma passivation achieve better device performance, including the off-current below 0.1 pA/μm and the on/off current ratio higher than 10⁸, and also better hot-carrier reliability than the H₂-plasma devices. Based on optical emission spectroscopy (OES) and secondary ion mass spectroscopy (SIMS) analysis, these improvements were attributed to not only the hydrogen passivation of the defect states, but also the nitrogen pile-up at SiO₂/poly-Si interface and the strong Si-N bond formation to terminate the dangling bonds at the grain boundaries of the polysilicon films. Furthermore, the gate-oxide leakage current significantly decreases and the oxide breakdown voltage slightly increases after applying NH₃-plasma treatment. This novel process is of potential use for the fabrication of TFT/LCD's and TFT/SRAM's     

A novel gate-overlapped LDD poly-Si thin-film transistor

We fabricate a new polycrystalline silicon thin-film transistor (poly-Si TFT), called a gate-overlapped lightly doped drain (GO-LDD) TFT, which reduces the leakage current without sacrificing the ON current. A new GO-LDD TFT, of which the electrical characteristics are tolerable to the change of LDD doping concentration, can be easily fabricated by employing the buffer oxide without any additional LDD implantation. The change of ON current due to the misalignment of the LDD region may be eliminated. Experimental results show that the leakage current of the proposed TFT's is reduced by two orders of magnitude, compared with that of conventional nonoffset TFT, while the ON current is not decreased. It is observed that the ON/OFF current ratio is not changed significantly with LDD doping concentration and LDD length     

A high performance thin-film transistor using a low temperaturepoly-Si by silicide mediated crystallization

Electric field enhanced silicide mediated crystallization (SMC) was introduced for low-temperature polycrystalline silicon thin-film transistors (TFTs) on glass substrates. The amorphous silicon (a-Si) film having an average Ni thickness of 0.15 Å, was completely crystallized at a temperature of 480°C within 30 min in the presence of an electric field of 40 V/cm. The poly-Si is composed of needlelike crystallites with a few μm length and about 50 nm width. The poly-Si TFT using the SMC exhibited a field effect mobility of 86 cm²/Vs, a threshold voltage of -0.6 V, and a subthreshold slope of 0.6 V/dec     

Partially depleted SOI NMOSFET's with self-aligned polysilicon gateformed on the recessed channel region

A new SOI NMOSFET with a “LOCOS-like” shape self-aligned polysilicon gate formed on the recessed channel region has been fabricated by a mix-and-match technology. For the first time, we developed a new scheme for implementing self-alignment in both source/drain and gate structure in recessed channel device fabrication. Symmetric source/drain doping profile was obtained and highly symmetric electrical characteristics were observed. Drain current measured from 0.3 μm SOI devices with V_z of 0.773 V and T_ox=7.6 nm is 360 μA/μm at V_GS=3.5 V and V _DS=2.5 V. Improved breakdown characteristics were obtained and the BV_DSS (the drain voltage for 1 nA/μm of I_D at T_GS=0 V) of the device with L_eff=0.3 μm under the floating body condition was as high as 3.7 V     

A new patterning process concept for large-area transistor circuitfabrication without using an optical mask aligner

A new concept to produce large thin film transistor liquid crystal displays (TFT-LCD's) without using an optical mask aligner is proposed which emphasizes patterning technology. Some experimental thin film transistors (TFT's) are fabricated according to the concept and operated like conventional transistors fabricated by using an optical mask aligner. The concept includes improvement of printing technology and development of a double-layer resist method. The latter method employs a printed ink pattern and a photoresist. This prevents contamination of thin films by metal impurities which affect electrical characteristics of the TFT's. A special gravure offset printing technology is proposed, composed of a large thixotropy valued UV ink, and a fine, precision etched glass intaglio. The experimental TFT's, with a designed minimum gate length of 10 μm, have comparable electric characteristics to those of conventional poly-Si TFT's     

One transistor ferroelectric memory with Pt/Pb5Ge3O11/Ir/poly-Si/SiO2/Si gate-stack

One transistor ferroelectric nonvolatile memory with gate stack of Pt/Pb₅Ge₃O₁₁/lr/poly-Si/SiO₂ /Si was successfully fabricated. This device features a saturated memory window of 3 V at a programming voltage of higher than 3 V from C-V and I-V measurements. The memory window decays rapidly within 10 seconds after programming, but remains stable at 1 V for up to 100 h. The "on" and "off" state currents are greater than 10 μA/μm and less 0.01 pA/μm, respectively, at a drain voltage of 0.1 V