Numerical analysis on the LDMOS with a double epi-layer and trench electrodes

We proposed a new lateral double-diffused MOS (LDMOS) structure employing a double p/n epitaxial layer, which is formed on p⁻ substrates. Trenched gate and drain are also employed to obtain uniform and high drift current density. The breakdown voltage and the specific on-resistance of the proposed LDMOS are numerically calculated by using a two-dimensional (2D) device simulator, Medici. The n⁻ drift region and upper p⁻ region of the proposed LDMOS are fully depleted in off-states employing the RESURF technique. The simulation results show that the breakdown voltage is 142 V and specific on-resistance is 183 mΩ mm² when the cell pitch of the LDMOS is 7.5 μm. The proposed LDMOS shows better trade-off characteristics than the previous results.     

High-voltage and low specific on-resistance power UMOSFET using P and N type columns

For the first time, we present the unique features exhibited by power 4H–SiC UMOSFET in which N and P type columns (NPC) in the drift region are incorporated to improve the breakdown voltage, the specific on-resistance, and the total lateral cell pitch. The P-type column creates a potential barrier in the drift region of the proposed structure for increasing the breakdown voltage and the N-type column reduces the specific on-resistance. Also, the JFET effects reduce and so the total lateral cell pitch will decrease. In the NPC-UMOSFET, the electric field crowding reduces due to the created potential barrier by the NPC regions and causes more uniform electric field distribution in the structure. Using two dimensional simulations, the breakdown voltage and the specific on-resistance of the proposed structure are investigated for the columns parameters in comparison with a conventional UMOSFET (C-UMOSFET) and an accumulation layer UMOSFET (AL-UMOSFET) structures. For the NPC-UMOSFET with 10 µm drift region length the maximum breakdown voltage of 1274 V is obtained, while at the same drift region length, the maximum breakdown voltages of the C-UMOSFET and the AL-UMOSFET structures are 534 and 703 V, respectively. Moreover, the proposed structure exhibits a superior specific on-resistance (R_on,sp) of 2 mΩ cm², which shows that the on-resistance of the optimized NPC-UMOSFET are decreased by 56% and 58% in comparison with the C-UMOSFET and the AL-UMOSFET, respectively.     

Silicon-on-insulator power integrated circuits

A power integrated circuit process has been developed, based on silicon-on-insulator, which allows intelligent CMOS control circuitry to be placed alongside integrated high-voltage power devices. A breakdown voltage of 335 V has been obtained by using a silicon layer of 4 μm thickness together with a buried oxide layer of 3 μm thickness. The respective LDMOS specific on-resistance and LIGBT on-state voltage for this breakdown voltage were 148 mΩ cm² and 3.9 V, respectively.     

Study of the breakdown failure mechanisms for power AlGaN/GaN HEMTs implemented using a RF compatible process

The breakdown failure mechanisms for a family of power AlGaN/GaN HEMTs were studied. These devices were fabricated using a commercially available MMIC/RF technology with a semi-insulating SiC substrate. After a 10 min thermal annealing at 425 K, the transistors were subjected to temperature dependent electrical characteristics measurement. Breakdown degradation with a negative temperature coefficient of ?0.113 V/K for the devices without field plate was found. The breakdown voltage is also found to be a decreasing function of the gate length. Gate current increases simultaneously with the drain current during the drain-voltage stress test. This suggests that the probability of a direct leakage current path from gate to the 2-DEG region. The leakage current is attributed by a combination of native and generated traps/defects dominated gate tunneling, and hot electrons injected from the gate to channel. Devices with field plate show an improvement in breakdown voltage from ～40 V (with no field plate) to 138 V and with lower negative temperature coefficient. A temperature coefficient of ?0.065 V/K was observed for devices with a field plate length of 1.6 μm.     

4H–SiC BJTs with current gain of 110

4H–SiC BJTs with a common emitter current gain of 110 have been demonstrated. The high current gain was attributed to a thin base of 0.25 μm which reduces the carrier recombination in the base region. The device open base breakdown voltage (BV_CEO) of 270 V was much less than the open emitter breakdown voltage (BV_CBO) of 1560 V due to the emitter leakage current multiplication from the high current gain by “transistor action” of BJTs. The device has shown minimal gain degradation after electrical stress at high current density of >200 A/cm²up to 25 h.     

Microwave performance of field-plate 0.13-μm MOS transistors with varying field-plate extension

Si-based field-plate 0.13 μm gate length metal-oxide-semiconductor field effect transistor (Si MOSFET) with field-plate (FP) lengths of 0.1 μm, 0.2 μm, and 0.3 μm have been fabricated and investigated. The field-plate metals were connected to gate electrode in this study to improve device gate resistance (R_g) resulting in the better microwave performance. By increasing the length of field-plate metal extension (L_FPE), the off-state drain-to-source surface leakage current can be suppressed. Besides, low surface traps in FP NMOS also leads to a higher drain-to-source current (I_ds) especially at high current regime compared to standard device. The power added efficiency (PAE) was 56.3% for L_FPE of 0.3 μm device, and these values where 54.7% and 53.8% for L_FPE of 0.2 μm and 0.1 μm devices, respectively. Wider field-plate metal extension exhibits highly potential for low noise amplifier and high efficiency power amplifier applications.     

Self-aligned flexible organic thin-film transistors with gates patterned by nano-imprint lithography

Many applications that rely on organic electronic circuits still suffer from the limited switching speed of their basic elements – the organic thin film transistor (OTFT). For a given set of materials the OTFT speed scales inversely with the square of the channel length, the parasitic gate overlap capacitance, and the contact resistance. For maximising speed we pattern transistor channels with lengths from 10 μm down to the sub-micrometre regime by industrially scalable UV-nanoimprint lithography. The reduction of the overlap capacitance is achieved by minimising the source–drain to gate overlap lengths to values as low as 0.2 μm by self-aligned electrode definition using substrate reverse side exposure. Pentacene based organic thin film transistors with an exceptionally low line edge roughness <20 nm of the channels, a mobility of 0.1 cm²/Vs, and an on–off ratio of 10⁴, are fabricated on 4″ × 4″ flexible substrates in a carrier-free process scheme. The stability and spatial distribution of the transistor channel lengths are assessed in detail with standard deviations of L ranging from 185 to 28 nm. Such high-performing self-aligned organic thin film transistors enabled a ring-oscillator circuit with an average stage delay below 4 μs at an operation voltage of 7.5 V.     

AlGaN/GaN Schottky barrier diodes on silicon substrates with various Fe doping concentrations in the buffer layers

This study demonstrated AlGaN/GaN Schottky barrier diodes (SBDs) for use in high-frequency, high-power, and high-temperature electronics applications. Four structures with various Fe doping concentrations in the buffer layers were investigated to suppress the leakage current and improve the breakdown voltage. The fabricated SBD with an Fe-doped AlGaN buffer layer of 8 × 10¹⁷ cm^− 3 realized the highest on-resistance (R_ON) and turn-on voltage (V_ON) because of the memory effect of Fe diffusion. The optimal device was the SBD with an Fe-doped buffer layer of 7 × 10¹⁷ cm^− 3, which exhibited a R_ON of 31.6 mΩ-cm², a V_ON of 1.2 V, a breakdown voltage of 803 V, and a buffer breakdown voltage of 758 V. Additionally, the low-frequency noise decreased when the Fe doping concentration in the buffer layer was increased. This was because the electron density in the channel exhibited the same trend as that of the Fe doping concentration in the buffer layer.     

Deep trap-induced dynamic on-resistance degradation in GaN-on-Si power MISHEMTs

Identification and characterization of a single, deep trap causing large increases in the on-resistance of GaN-on-Si power metal-insulator-semiconductor-high electron mobility transistors (MISHEMTs) is reported. This is achieved by using HEMT-based deep level optical spectroscopy (DLOS) and related methods in conjunction with high voltage off-state V_DS switching up to 400 V. A trap with an activation energy of ~ E_C − 2 eV that is physically located in the drain-access region of the MISHEMT is shown to be the primary source of an increase of the dynamic on-resistance increase by as much as ~ 9 times at 400 V operation. Comparisons of trap signatures extracted from the MISHEMT with capacitance-based DLOS measurements of simple Schottky-diode test-structures showing the same, dominant trap signature suggests that the physical defect is located within the GaN buffer and is not a surface or insulator-related defect. A buffer trap based model is presented to explain the observed on-resistance degradation effects in the MISHEMTs during high voltage switching.     

High-speed organic single-crystal transistors gated with short-channel air gaps: Efficient hole and electron injection in organic semiconductor crystals

Short-channel, high-mobility organic filed-effect transistors (OFETs) are developed based on single crystals gated with short-channel air gaps. The high hole mobility of 10 cm²/Vs for rubrene, and high electron mobility of 4 cm²/Vs for PDIF-CN₂ crystals are demonstrated even with a short channel length of 6 μm. Such performance is due to low contact resistance in these devices estimated to be as low as ～0.5 kΩ cm at gate voltage of ?4 V for rubrene. With the benefit of the short channel length of 4.5 μm in a new device architecture with less parasitic capacitance, the cutoff frequency of the rubrene air–gap device was estimated to be as high as 25 MHz for drain voltage of ?15 V, which is the fastest reported for p-type OFETs, operating in ambient conditions.     

In situ modification of low-cost Cu electrodes for high-performance low-voltage pentacene thin film transistors (TFTs)

We demonstrate low-voltage pentacene thin film transistors (TFTs) using in situ modified low-cost Cu (M-Cu) as source–drain (S/D) electrodes and solution-processed high capacitance (200 nF/cm²) gate dielectrics. Under a gate voltage of ?3 V, the device with M-Cu electrodes shows a much higher apparent mobility (1.0 cm²/V s), a positively shifted threshold voltage (?0.62 V), a lower contact resistance (0.11 MΩ) and a larger transconductance (12 μS) as compared to the device with conventional Au electrodes (corresponding parameters are 0.71 cm²/V s, ?1.44 V, 0.41 MΩ, and 5.7 μS, respectively). The enhancement in the device performance is attributed to the optimized interface properties between S/D electrodes and pentacene. Moreover, after encapsulation the M-Cu electrodes with a thin layer of Au in the aim of suppressing unfavorable surface oxidation, the electronic characteristics of the device are further improved, and highly enhanced apparent mobility (2.3 cm²/V s) and transconductance (19 μS) can be achieved arising from the increased conductivity of the electrode itself. Our study provides a simple and feasible approach to achieve high performance low-voltage OTFTs with low-cost S/D electrodes, which is desirable for large area applications.     

Reliability of Diode-Integrated SiC Power MOSFET(DioMOS)

Status of the reliability study on silicon carbide (SiC) power MOS transistors is presented. The SiC transistors studied are diode-integrated MOSFETs (DioMOS) in which a highly doped n-type epitaxial channel layer formed underneath the gate oxide acts as a reverse diode and thus an external Schottky barrier diode can be eliminated. The novel MOS device can reduce the total area of SiC leading to potentially lower cost as well as the size of the packaging. After summarizing the issues on reliability of conventional SiC MOS transistors, the improvements by the newly proposed DioMOS with blocking voltage of 1200 V are presented. The I–V characteristic of the integrated reverse diode is free from the degradation which is typically observed in conventional pn-junction-based body diode in SiC MOS transistors. The improved quality of the MOS gate in the DioMOS results in very stable threshold voltage within its variation less than 0.1 V even after 2000 h of serious gate voltage stresses of + 25 V and − 10 V at 150 °C. High temperature reverse bias test (HTRB) shows very stable off-state and gate leakage current up to 2000 h under the drain voltage of 1200 V at 150 °C. These results indicate that the presented DioMOS can be applied to practical switching systems free from the reliability issues.     

Operational frequency degradation induced trapping in scaled GaN HEMTs

Cut-off frequency increase from 12.1 GHz to 26.4 GHz, 52.1 GHz and 91.4 GHz is observed when the 1 μm gate length GaN HEMT is laterally scaled down to L_G = 0.5 μm, L_G = 0.25 μm and L_G = 0.125 μm, respectively. The study is based on accurately calibrated transfer characteristics (I_D-V_GS) of the 1 μm gate length device using Silvaco TCAD. If the scaling is also performed horizontally, proportionally to the lateral (full scaling), the maximum drain current is reduced by 38.2% when the gate-to-channel separation scales from 33 nm to 8.25 nm. Degradation of the RF performance of a GaN HEMT due to the electric field induced acceptor traps experienced under a high electrical stress is found to be about 8% for 1 μm gate length device. The degradation of scaled HEMTs reduces to 3.5% and 7.3% for the 0.25 μm and 0.125 gate length devices, respectively. The traps at energy level of E_T = E_V + 0.9 eV (carbon) with concentrations of N_IT = 5 × 10¹⁶cm^− 3, N_IT = 5 × 10¹⁷cm^− 3 and N_IT = 5 × 10¹⁸cm^− 3 are located in the drain access region where highest electrical field is expected. The effect of traps on the cut-off frequency is reduced for devices with shorter gate lengths down to 0.125 μm.     

Source/drain metallization effects on the specific contact resistance of indium tin zinc oxide thin film transistors

We report on the specific contact resistance of interfaces between thin amorphous semiconductor Indium Tin Zinc Oxide (ITZO) channel layers and different source/drain (S/D) electrodes (Al, ITO, and Ni) in amorphous oxide thin film transistors (TFTs) at different channel lengths using a transmission line model. All the contacts showed linear current–voltage characteristics. The effects of different channel lengths (200–800 μm, step 200 μm) and the contact resistance on the performance of TFT devices are discussed in this work. The Al/ITZO TFT samples with the channel length of 200 μm showed metallic behavior with a linear drain current-gate voltage (I_D–V_G) curve due to the formation of a conducting channel layer. The specific contact resistance (ρ_C) at the source or drain contact decreases as the gate voltage is increased from 0 to 10 V. The devices fabricated with Ni S/D electrodes show the best TFT characteristics such as highest field effect mobility (16.09 cm²/V·s), ON/OFF current ratio (3.27×10⁶), lowest sub-threshold slope (0.10 V/dec) and specific contact resistance (8.62 Ω·cm² at V_G=0 V). This is found that the interfacial reaction between Al and a-ITZO semiconducting layer lead to the negative shift of threshold voltage. There is a trend that the specific contact resistance decreases with increasing the work function of S/D electrode. This result can be partially ascribed to better band alignment in the Ni/ITZO interface due to the work function of Ni (5.04–5.35 eV) and ITZO (5.00–6.10 eV) being somewhat similar.     

Study of the leakage current suppression for hybrid-Schottky/ohmic drain AlGaN/GaN HEMT

The leakage current suppression mechanism in AlGaN/GaN High Electron Mobility Transistors (HEMTs) is investigated. It is known that leakage current can cause severe reliability problems for HEMT devices and conventional AlGaN/GaN HEMT devices suffer from detrimental off-state drain leakage current issues, especially under high off-state drain bias. Therefore, a leakage current suppression technique featuring hybrid-Schottky/ohmic-drain contact is discussed. Through the 2-zones leakage current suppression mechanism by the hybrid-Schottky/drain metal including the shielding effect of the rough ohmic-drain metal morphology and the drain side electric field modulation, AlGaN/GaN HEMT featuring this novel technique can significantly enhance the leakage current suppression capability and improve the breakdown voltage. An analytical method using loop-voltage-scanning is proposed to illustrate the optimization procedure of the hybrid-Schottky/ohmic drain metallization on leakage current suppression. Through the comparison of the loop leakage current hysteresis of conventional ohmic drain HEMT and hybrid-Schottky/ohmic drain, the leakage current suppression mechanism is verified through the leakage current considering surface acceptor-like trap charging/discharging model. Device featuring the hybrid-Schottky/ohmic drain technique shows an improvement in breakdown voltage from 450 V (with no Schottky drain metal) to 855 V with a total drift region length of 9 μm, indicating enhanced off-state reliability characteristics for the AlGaN/GaN HEMT devices.     

A new technique in LDMOS transistors to improve the breakdown voltage and the lattice temperature

A new technique for high breakdown voltage of the LDMOS device is proposed in this paper. The main idea in the proposed technique is to insert the P⁺ silicon windows in the buried oxide at the interface of the n-drift to improve the breakdown voltage, electric field and maximum lattice temperature. The proposed structure is called as P⁺ window LDMOS (PW-LDMOS). It is shown by extending the depletion region between the P⁺ windows and the n-drift region, the breakdown voltage of PW-LDMOS increases to 405 V from 84 V of the conventional LDMOS on 1 µm silicon layer and 2 µm buried oxide layer. Also, effective values of doping, length, and depth of P⁺ window are investigated in the breakdown voltage. Moreover, a self-heating-effect is alleviated by the silicon windows in comparison with the conventional LDMOS. All the achieved results have been extracted by two-dimensional and two-carriers simulator ATLAS.     

Bottom gate organic thin-film transistors fabricated by ultraviolet transfer embossing with improved device performance

Ultraviolet transfer embossing is optimized to fabricate bottom gate organic thin-film transistors (OTFTs) on flexible plastic substrates, achieving significant improved device performance (μ = 0.01–0.02cm²/Vs; on/off ratio = 10⁴) compared with the top gate OTFTs made previously by the same method (μ = 0.001–0.002 cm²/Vs; on/off ratio = 10²). The performance improvement can be ascribed to the reduced roughness of the dielectric-semiconductor interface (R_rms = 0.852 nm) and thermally cross-linked PVP dielectric which leads to reduced gate leakage current and transistor off current in the bottom-gated configuration. This technique brings an alternative great opportunity to the high-volume production of economic printable large-area OTFT-based flexible electronics and sensors.     

A facile chemical reduction approach for effectively tuning thermoelectric properties of PEDOT films

Poly(3,4-ethylenedioxythiophene)–tosylate–polyethylene glycol–polypropylene glycol–polyethylene glycol (PEDOT–Tos–PPP) films were prepared via a vapor phase polymerization (VPP) method. The films possess good electrical conductivity (1550 S cm⁻¹), low Seebeck coefficient (14.9 μV K⁻¹) and thermal conductivity (0.501 W m⁻¹ K⁻¹), and ZT ∼ 0.02 at room temperature (RT, 295 K). Then, the films were treated with NaBH₄/DMSO solutions of different NaBH₄ concentrations to adjust the redox level. After the NaBH₄/DMSO treatment (dedoping), the electrical conductivity of the films continuously decreased from 1550 to 5.7 S cm⁻¹, whereas the Seebeck coefficient steeply increased from 14.9 to 143.5 μV K⁻¹. A maximum power factor of 98.1 μW m⁻¹ K⁻² has been achieved at an optimum redox level. In addition, the thermal conductivity of the PEDOT–Tos–PPP films decrease from 0.501 to 0.451 W m⁻¹ K⁻¹ after treated with 0.04% NaBH₄/DMSO solution. A maximum ZT value of 0.064 has been achieved at RT. The electrical conductivity and thermal conductivity (Seebeck coefficient) of the untreated and 0.04% NaBH₄/DMSO treated PEDOT–Tos–PPP films decrease (increases) with increasing temperature from 295 to 385 K. And the power factor of the films monotonically increases with temperature. The ZT at 385 K of the 0.04% NaBH₄/DMSO treated film is 0.155.     

Inverter circuits on glass substrates based on ZnO-nanoparticle thin-film transistors

The integration technique and the properties of inverter circuits on glass substrates using ZnO nanoparticles as semiconductor material are presented. The inverter device consists of a switching and a load metal–insulator–semiconductor field-effect transistor with poly(4-vinylphenol) as the gate dielectric. Although the semiconductor is deposited by spin-coating of a colloidal ZnO dispersion and the process temperature is limited to 200 °C, the inverters show reasonable maximum peak gains at low power consumption. The maximum peak gain was 6 V/V, whereas the maximum static power dissipation density was less than 26 nW/μm². Additionally, the influence of the geometry ratio as well as of the supply voltage on the device performance has been investigated. With regard to the optical characteristics, the proposed technique leads to circuits with an optical transmittance of up to 80%.