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     

Low-frequency noise in polysilicon emitter bipolar transistors

The low-frequency noise in polysilicon emitter bipolar transistors is investigated. Transistors with various geometries and various properties of the oxide layer at the monosilicon polysilicon interface are studied. The main 1/f noise source proved to be located in the oxide layer. This source causes both 1/f noise in the base current S_Ib and 1/f noise in the emitter series resistance S_re The magnitude of the 1/f noise source depends on the properties of the oxide layer. The 1/f noise is ascribed to barrier height fluctuations of the oxide layer resulting in transparency fluctuations for both minority and majority carriers in the emitter, giving rise to S_Ib and S _re respectively. It is also shown that a low transparency of the oxide layer also reduces the contribution of mobility fluctuations to S_Ib     

The benefits of fluorine in pnp polysilicon emitter bipolartransistors

BF₂ implantation into polysilicon and its subsequent rapid thermal diffusion into single crystal silicon is commonly used for the fabrication of pnp polysilicon emitter bipolar transistors. In this paper the effect of the fluorine, which is introduced into the polysilicon during the BF₂ implant, is investigated. Pnp polysilicon emitter bipolar transistors are fabricated in which the boron and fluorine are implanted separately, with the fluorine only going into one half of each wafer. Electrical results show that fluorine has two interrelated effects. In devices given a low thermal budget emitter drive-in, a drop in base current by a factor of approximately 3.2 is observed when the fluorine is present, together with an improvement in the ideality of the base characteristics. This is explained by the passivation of trapping states at the polysilicon/silicon interface by the fluorine. In contrast, in devices-given a higher thermal budget emitter drive-in, an increase in base current by a factor of approximately 2.5 is observed, when fluorine is present. This is explained by the action of the fluorine in accelerating the breakup of the interfacial layer. A model is proposed to explain this behavior     

H2/O2 plasma on polysilicon thin-filmtransistor

It is reported for that H₂ plasma followed by O₂ plasma is more effective for passivating grain boundary states in polysilicon thin film. Polysilicon thin-film transistors (TFTs) made after H₂/O₂ plasma treatment can exhibit a turn-on threshold voltage of -0.1 V, a subthreshold swing of 0.154 V/decade, an ON/OFF current ratio I_on/I_off over 1×10⁸, and an electron mobility of 40.2 cm² /V-s     

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     

Investigation of boron diffusion in polysilicon and its applicationto the design of p-n-p polysilicon emitter bipolar transistors withshallow emitter junctions

Ion implantation of boron into undoped polysilicon is utilized. The main goals are to characterize the diffusion of implanted boron from polysilicon, and to correlate the diffusion behavior with the electrical properties of shallow (<500 Å) p-n-p polysilicon emitter bipolar transistors. It is shown that diffusion and electrical activity problems are encountered with boron polysilicon emitters which are not present with arsenic. Base current and emitter resistance are measured on shallow p-n-p polysilicon emitter transistors, and it is shown that the use of a deliberately grown interfacial oxide layer can decrease the base current by a factor of 10 and increase the emitter resistance by a factor of around 2. Comparisons with identical n-p-n polysilicon emitter transistors show that the modeled interfacial oxide, tunneling parameters for n-p-n and p-n-p devices are inconsistent     

Low-cost process for fabricating polysilicon transistors

A process for the fabrication of p-channel polysilicon MOS transistors is described. The process is compatible with the use of low-temperature glass substrates and replaces the use of ion implantation for the source/drain doping with in situ doped polysilicon. MOS transistors made with this process exhibit an on/off current ratio of 2.5×10⁵, a mobility of 16 cm²/V-s, and a subthreshold slope of 1.3 V/decade     

Low-temperature polysilicon TFT with two-layer gate insulator usingphoto-CVD and APCVD SiO2

The performance of polysilicon thin-film transistors (TFTs) formed by a 600°C process was improved using a two-layer gate insulator of photochemical-assisted vapor deposition (photo-CVD) SiO₂ and atmospheric-pressure chemical vapor deposition (APCVD) SiO₂. The photo-CVD SiO₂, 100 Å thick, was deposited on polysilicon and followed by APCVD SiO₂ of 1000 Å thickness. The TFT had a threshold voltage of 8.3 V and a field-effect mobility of 35 cm²/V-s, which were higher than those of the conventional TFT with a single-layer gate SiO₂ of APCVD. Hydrogenation by hydrogen plasma was more effective for the new TFT than for the conventional device     

Novel gate dielectric films formed by ion plating forlow-temperature-processed polysilicon TFTs

A novel SiO₂ film formed by ion plating (IP) at room temperature was developed for low-temperature-processed (LTP) (<625°C) polysilicon thin-film transistors (poly-Si TFT's). The IP SiO₂ film is a high-density dielectric with strained bonds, and also a high-performance insulator with low-leakage current and high-breakdown voltage. Poly-Si TFT with IP SiO₂ as a gate insulator shows satisfactory performance     

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)     

Performance enhancement of offset gated polysilicon thin-film transistors

Simple offset gated n-channel polysilicon thin film transistors (TFTs) of channel length L=10 /spl mu/m were investigated in relation to the intrinsic offset length /spl Delta/L and the polysilicon quality. For /spl Delta/L/spl les/1 /spl mu/m, the device parameters such as threshold voltage, subthreshold slope and field effect mobility are improved, while the leakage current remains unchanged. In TFTs with /spl Delta/L>1 /spl mu/m, the leakage current decreases with increasing the offset length. When the polysilicon layer is of high quality (large grain size and low intra-grain defect density), the leakage current is completely suppressed without sacrificing the on-current in TFT's with offset length of 2 /spl mu/m.     

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     

Impact of fluorine incorporation in the polysilicon emitter of NPNbipolar transistors

We demonstrate that fluorine incorporation in the polysilicon emitter of NPN bipolar transistors significantly reduces the current gain h_fe. The gain degradation can be related to a reduction of the barrier to hole transport at the poly-Si/mono-Si interface. In addition to a gain reduction, fluorinated-emitter transistors display lower base recombination currents (at low base-emitter biases) than nonfluorinated emitter devices, suggesting that fluorine passivates recombination centers in the emitter-base space charge region     

MODEL AND MODELING OF LOW TEMPERATURE CURRENT GAIN OF POLYSILICON EMITTER BIPOLAR TRANSISTORS

A unified model of low temperature current gain of polysilicon emitter bipolar transistors based on effective recombination method is presented, incorporating band-gap narrowing, carrier freezing-out, tunneling of holes through polysilicon/silicon interface oxide layer and reduced mobility mechanism in polysilicon. The modeling results based on this model are in good agreement with experimental data.     

A comprehensive analytical and numerical model of polysilicon emitter contacts in bipolar transistors

A comprehensive model-both analytical and numerical-is proposed as a tool to analyze heavily doped emitters of transistors with polycrystalline silicon (polysilicon) contacts. The grains and grain boundaries of polysilicon, the interfacial oxide-like layer between polycrystalline and monocrystalline silicon are lumped respectively into "boxes" in which the drift minority current component is neglected. The mobility reduction of carriers in polysilicon on the whole is explicitly attributed to the additional scattering due to the lattice disorder in the grain boundaries and the carrier tunneling through the interface. The effect of the poly-contacts on transistors can be modeled as a reduced surface recombination velocity for minority carriers in combination with a series emitter resistance for majority carriers. Furthermore, by characterizing the monocrystalline emitter with an effective recombination velocity, the effect of the polysilicon layer on the current gain can be analyzed analytically. Computer simulation is used to verify the assumptions of the model formulation. Using published data [1], the analytical and numerical approaches are compared and it is shown that for these devices a unique combination of physical parameters are needed for the model to fit the data.     

Polyoxides grown on n+ polysilicon

The polarity asymmetry on the electrical characteristics of the oxides grown on n⁺ polysilicon (polyoxides) was investigated in terms of the oxidation process, the doping level of the lower polysilicon layer, the oxidation temperature and the oxide thickness. It was found that the thin polyoxide prepared by using a low-temperature wafer loading and N₂ pre-annealing process, has a smoother polyoxide/polysilicon interface and exhibits a lower oxide tunneling current, a higher dielectric breakdown field when the top electrode is positively biased, a lower electron trapping rate and a larger charge-to-breakdown than does the normal polyoxide. The polarity asymmetry is also strongly dependent on the doping level of the lower polysilicon layer, the oxidation temperature and the oxide thickness. It was found that only the thinner polyoxides (⩽240 Å) grown on the heavily-doped polysilicon film (30 Ω/sq) by using the higher-temperature oxidation process (⩾950°C) conduct a less oxide tunneling current when the top electrode is positively biased     

Novel technique for SiO2 formed by liquid-phasedeposition for low-temperature processed polysilicon TFT

A technique for SiO₂ formation by liquid-phase deposition (LPD) at nearly room temperature for low-temperature processed (LTP) polysilicon thin-film transistor (poly-Si TFT) was developed. LPD SiO₂ film with a lower P-etch rate shows a dense structure. LPD SiO₂ also exhibits good electrical characteristics. LTP poly-Si thin-film transistors (TFTs) with LPD SiO ₂ as the gate insulator have been fabricated and investigated. Their characteristics indicate performance adequate for their use as pixel transistors in liquid crystal displays (LCDs)     

Stability of polysilicon thin film transistors under switch operating

Ageing of low temperature polysilicon Thin Film Transistors (TFTs) under AC gate bias stress is reported in this study. The active layer of these high performances transistors is amorphous deposited using Low Pressure Chemical Vapor Deposition (LPCVD) technique. The drain and source regions are in-situ doped during the LPCVD deposition by using phosphine to fabricate n-type transistors. The active layer and the drain arid source regions are Solid Phase Crystallized. The field effect mobility is higher than 100 cm²/V.s, the subthreshold slope around 0.6 V/dec, the threshold voltage around 0.2V and the switching time around 370 nsec.As these TFTs are commonly used as switching devices in the most of applications in large area electronics field, the study of their stability under AC electrical stress is important. The present work shows that the effect of the positive or negative DC stress is higher than that of the AC stress and then the degradation of polysilicon TFTs is over-estimated when it is checked from the effects of DC gate bias stress.Degradation under bias stress is shown to originate from the creation of gap states at the channel-interface oxide and in the channel material. The lower influence of the AC stress is explained from an annealing effect of the created states by the application of an opposite sign bias stress.     

A CMOS structure using beam-recrystallized polysilicon

A new CMOS structure has been fabricated with the p-channel transistors in a layer of recrystallized polysilicon and the n-channel transistors in adjacent, laterally displaced regions of the underlying single-crystal silicon. The process allows the use of existing circuit layouts with only minor, if any, modification. Moderate quality transistors are fabricated in a layer of recrystallized polysilicon without degrading the characteristics of high-quality transistors simultaneously formed in the substrate. The oscillation period of ring oscillators is close to that calculated, and varies with the transistor dimensions in the expected manner.     

Modeling hot-carrier effects in polysilicon emitter bipolartransistors

In self-aligned polysilicon emitter transistors a large electric field existing at the periphery of the emitter-base junction under reverse bias can create hot-carrier-induced degradation. The degradation of polysilicon emitter transistor gain under DC stress conditions can be modelled by ΔI_B∝I_R ^m+ntⁿ where n≈0.5 and m ≈0.5. The more complex relationships of Δβ(I _C, I_R, t) and β(I _C, I_R, t) result naturally from the simple ΔI_B model. Using these relationships the device lifetime can be extrapolated over a wide range of reverse stress currents for a given technology