In this paper, a novel dual-gate and dielectric-inserted lateral trench insulated gate bipolar transistor (DGDI LTIGBT) structure, which features a double extended trench gate and a dielectric inserted in the drift ...In this paper, a novel dual-gate and dielectric-inserted lateral trench insulated gate bipolar transistor (DGDI LTIGBT) structure, which features a double extended trench gate and a dielectric inserted in the drift region, is proposed and discussed. The device can not only decrease the specific on-resistance Ron,sp , but also simultaneously improve the temperature performance. Simulation results show that the proposed LTIGBT achieves an ultra-low on-state voltage drop of 1.31 V at 700 A·cm-2 with a small half-cell pitch of 10.5 μm, a specific on-resistance R on,sp of 187 mΩ·mm2, and a high breakdown voltage of 250 V. The on-state voltage drop of the DGDI LTIGBT is 18% less than that of the DI LTIGBT and 30.3% less than that of the conventional LTIGBT. The proposed LTIGBT exhibits a good positive temperature coefficient for safety paralleling to handling larger currents and enhances the short-circuit capability while maintaining a low self-heating effect. Furthermore, it also shows a better tradeoff between the specific on-resistance and the turnoff loss, although it has a longer turnoff delay time.展开更多
A high voltage(〉 600 V) integrable silicon-on-insulator(SOI) trench-type lateral insulated gate bipolar transistor(LIGBT) with a reduced cell-pitch is proposed.The LIGBT features multiple trenches(MTs):two o...A high voltage(〉 600 V) integrable silicon-on-insulator(SOI) trench-type lateral insulated gate bipolar transistor(LIGBT) with a reduced cell-pitch is proposed.The LIGBT features multiple trenches(MTs):two oxide trenches in the drift region and a trench gate extended to the buried oxide(BOX).Firstly,the oxide trenches enhance electric field strength because of the lower permittivity of oxide than that of Si.Secondly,oxide trenches bring in multi-directional depletion,leading to a reshaped electric field distribution and an enhanced reduced-surface electric-field(RESURF) effect.Both increase the breakdown voltage(BV).Thirdly,oxide trenches fold the drift region around the oxide trenches,leading to a reduced cell-pitch.Finally,the oxide trenches enhance the conductivity modulation,resulting in a high electron/hole concentration in the drift region as well as a low forward voltage drop(Von).The oxide trenches cause a low anode-cathode capacitance,which increases the switching speed and reduces the turn-off energy loss(Eoff).The MT SOI LIGBT exhibits a BV of 603 V at a small cell-pitch of 24 μm,a Von of 1.03 V at 100 A/cm-2,a turn-off time of 250 ns and Eoff of 4.1×10?3 mJ.The trench gate extended to BOX synchronously acts as dielectric isolation between high voltage LIGBT and low voltage circuits,simplifying the fabrication processes.展开更多
A low gate voltage operated multi-emitter-dot gated lateral bipolar junction transistor (BJT) ion sensor is proposed. The proposed device is composed of an arrayed gated lateral BJT, which is driven in the metal-oxi...A low gate voltage operated multi-emitter-dot gated lateral bipolar junction transistor (BJT) ion sensor is proposed. The proposed device is composed of an arrayed gated lateral BJT, which is driven in the metal-oxidesemiconductor field-effect transistor (MOSFET)-BJT hybrid operation mode. Further, it has multiple emitter dots linked to each other in parallel to improve ionic sensitivity. Using hydrogen ionic solutions as reference solutions, we conduct experiments in which we compare the sensitivity and threshold voltage of the multi-emitter-dot gated lateral BJT with that of the single-emitter-dot gated lateral BJT. The multi-emitter-dot gated lateral BJT not only shows increased sensitivity but, more importantly, the proposed device can be operated under very low gate voltage, whereas the conventional ion-sensitive field-effect transistors cannot. This special characteristic is significant for low power devices and for function devices in which the provision of a gate voltage is difficult.展开更多
A novel silicon carbide gate-controlled bipolar field effect composite transistor with poly silicon region(SiC GCBTP)is proposed.Different from the traditional electrode connection mode of SiC vertical diffused MOS(VD...A novel silicon carbide gate-controlled bipolar field effect composite transistor with poly silicon region(SiC GCBTP)is proposed.Different from the traditional electrode connection mode of SiC vertical diffused MOS(VDMOS),the P+region of P-well is connected with the gate in SiC GCBTP,and the polysilicon region is added between the P+region and the gate.By this method,additional minority carriers can be injected into the drift region at on-state,and the distribution of minority carriers in the drift region will be optimized,so the on-state current is increased.In terms of static characteristics,it has the same high breakdown voltage(811 V)as SiC VDMOS whose length of drift is 5.5μm.The on-state current of SiC GCBTP is 2.47×10^(-3)A/μm(V_(G)=10 V,V_(D)=10 V)which is 5.7 times of that of SiC IGBT and 36.4 times of that of SiC VDMOS.In terms of dynamic characteristics,the turn-on time of SiC GCBTP is only 0.425 ns.And the turn-off time of SiC GCBTP is similar to that of SIC insulated gate bipolar transistor(IGBT),which is 114.72 ns.展开更多
A novel ultralow turnoff loss dual-gate silicon-on-insulator (SOI) lateral insulated gate bipolar transistor (LIGBT) is proposed. The proposed SOI LIGBT features an extra trench gate inserted between the p-well an...A novel ultralow turnoff loss dual-gate silicon-on-insulator (SOI) lateral insulated gate bipolar transistor (LIGBT) is proposed. The proposed SOI LIGBT features an extra trench gate inserted between the p-well and n-drift, and an n-type carrier stored (CS) layer beneath the p-well. In the on-state, the extra trench gate acts as a barrier, which increases the cartier density at the cathode side of n-drift region, resulting in a decrease of the on-state voltage drop (Von). In the off-state, due to the uniform carder distribution and the assisted depletion effect induced by the extra trench gate, large number of carriers can be removed at the initial turnoff process, contributing to a low turnoff loss (Eoff). Moreover, owing to the dual-gate field plates and CS layer, the carrier density beneath the p-well can greatly increase, which further improves the tradeoff between Eoff and Von. Simulation results show that Eoff of the proposed SOI LIGBT can decrease by 77% compared with the conventional trench gate SOI LIGBT at the same Von of 1.1 V.展开更多
基于介质场增强(ENDIF)理论,提出了一种部分超结型薄硅层SOI横向绝缘栅双极型晶体管(PSJ SOI LIGBT)。分析了漂移区注入剂量和超结区域位置对器件耐压性能的影响,并在工艺流程中结合线性变掺杂技术和超结技术,使该器件实现了高垂直方向...基于介质场增强(ENDIF)理论,提出了一种部分超结型薄硅层SOI横向绝缘栅双极型晶体管(PSJ SOI LIGBT)。分析了漂移区注入剂量和超结区域位置对器件耐压性能的影响,并在工艺流程中结合线性变掺杂技术和超结技术,使该器件实现了高垂直方向耐压和低导通电阻。测试结果表明,该器件的耐压达到816 V,比导通电阻仅为12.5Ω·mm^(2)。展开更多
A lateral insulated gate bipolar transistor(LIGBT)based on silicon-on-insulator(SOI)structure is proposed and investigated.This device features a compound dielectric buried layer(CDBL)and an assistant-depletion trench...A lateral insulated gate bipolar transistor(LIGBT)based on silicon-on-insulator(SOI)structure is proposed and investigated.This device features a compound dielectric buried layer(CDBL)and an assistant-depletion trench(ADT).The CDBL is employed to introduce two high electric field peaks that optimize the electric field distributions and that,under the same breakdown voltage(BV)condition,allow the CDBL to acquire a drift region of shorter length and a smaller number of stored carriers.Reducing their numbers helps in fast-switching.Furthermore,the ADT contributes to the rapid extraction of the stored carriers from the drift region as well as the formation of an additional heat-flow channel.The simulation results show that the BV of the proposed LIGBT is increased by 113%compared with the conventional SOI LIGBT of the same length L_(D).Contrastingly,the length of the drift region of the proposed device(11.2μm)is about one third that of a traditional device(33μm)with the same BV of 141 V.Therefore,the turn-off loss(E_(OFF))of the CDBL SOI LIGBT is decreased by 88.7%compared with a conventional SOI LIGBT when the forward voltage drop(VF)is 1.64 V.Moreover,the short-circuit failure time of the proposed device is 45%longer than that of the conventional SOI LIGBT.Therefor,the proposed CDBL SOI LIGBT exhibits a better V_(F)-E_(OFF)tradeoff and an improved short-circuit robustness.展开更多
A novel trench insulated gate bipolar transistor(IGBT) with improved dynamic characteristics is proposed and investigated. The poly gate and poly emitter of the proposed IGBT are arranged alternately along the trench....A novel trench insulated gate bipolar transistor(IGBT) with improved dynamic characteristics is proposed and investigated. The poly gate and poly emitter of the proposed IGBT are arranged alternately along the trench. A self-biased p-MOSFET is formed on the emitter side. Owing to this unique three-dimensional(3D) trench architecture, both the turnoff characteristic and the turn-on characteristic can be greatly improved. At the turn-off moment, the maximum electric field and impact ionization rate of the proposed IGBT decrease and the dynamic avalanche(DA) is suppressed. Comparing with the carrier-stored trench gate bipolar transistor(CSTBT), the turn-off loss(E_(off)) of the proposed IGBT also decreases by 31% at the same ON-state voltage. At the turn-on moment, the built-in p-MOSFET reduces the reverse displacement current(I_(G_dis)), which is conducive to lowing dI_(C)/d_(t). As a result, compared with the CSTBT with the same turn-on loss(E_(on)), at I_(C) = 20 A/cm^(2), the proposed IGBT decreases by 35% of collector surge current(I_(surge)) and 52% of dI_(C)/d_(t).展开更多
A reverse-conducting lateral insulated-gate bipolar transistor (NI.2-LltJlS|) with a trench oxide layer (IUL), teaturlng a vertical N-buffer and P-collector is proposed. Firstly, the TOL enhances both of the surf...A reverse-conducting lateral insulated-gate bipolar transistor (NI.2-LltJlS|) with a trench oxide layer (IUL), teaturlng a vertical N-buffer and P-collector is proposed. Firstly, the TOL enhances both of the surface and bulk electric fields of the N-drift region, thus the breakdown voltage (BV) is improved. Secondly, the vertical N-buffer layer increases the voltage drop VpN of the P-collector/N-buffer junction, thus the snapback is suppressed. Thirdly, the P-body and the vertical N-buffer act as the anode and the cathode, respectively, to conduct the reverse current, thus the inner diode is integrated. As shown by the simulation results, the proposed RC-LIGBT exhibits trapezoidal electric field distribution with BV of 342.4 V, which is increased by nearly 340% compared to the conventional RC-LIGBT with triangular electric fields of 100.2 V. Moreover, the snapback is eliminated by the vertical N-buffer layer design, thus the reliability of the device is improved.展开更多
基金the Major Program of the National Natural Science Foundation of China(Grant No.2009ZX02305-006)the National Natural Science Foundation of China(Grant No.61076082)
文摘In this paper, a novel dual-gate and dielectric-inserted lateral trench insulated gate bipolar transistor (DGDI LTIGBT) structure, which features a double extended trench gate and a dielectric inserted in the drift region, is proposed and discussed. The device can not only decrease the specific on-resistance Ron,sp , but also simultaneously improve the temperature performance. Simulation results show that the proposed LTIGBT achieves an ultra-low on-state voltage drop of 1.31 V at 700 A·cm-2 with a small half-cell pitch of 10.5 μm, a specific on-resistance R on,sp of 187 mΩ·mm2, and a high breakdown voltage of 250 V. The on-state voltage drop of the DGDI LTIGBT is 18% less than that of the DI LTIGBT and 30.3% less than that of the conventional LTIGBT. The proposed LTIGBT exhibits a good positive temperature coefficient for safety paralleling to handling larger currents and enhances the short-circuit capability while maintaining a low self-heating effect. Furthermore, it also shows a better tradeoff between the specific on-resistance and the turnoff loss, although it has a longer turnoff delay time.
基金Projects supported by the National Natural Science Foundation of China (Grant No. 61176069)the State Key Laboratory of Electronic Thin Films and Integrated Devices,China (Grant No. CXJJ201004)the National Key Laboratory of Analog Integrated Circuit,China (Grant No. 9140C090304110C0905)
文摘A high voltage(〉 600 V) integrable silicon-on-insulator(SOI) trench-type lateral insulated gate bipolar transistor(LIGBT) with a reduced cell-pitch is proposed.The LIGBT features multiple trenches(MTs):two oxide trenches in the drift region and a trench gate extended to the buried oxide(BOX).Firstly,the oxide trenches enhance electric field strength because of the lower permittivity of oxide than that of Si.Secondly,oxide trenches bring in multi-directional depletion,leading to a reshaped electric field distribution and an enhanced reduced-surface electric-field(RESURF) effect.Both increase the breakdown voltage(BV).Thirdly,oxide trenches fold the drift region around the oxide trenches,leading to a reduced cell-pitch.Finally,the oxide trenches enhance the conductivity modulation,resulting in a high electron/hole concentration in the drift region as well as a low forward voltage drop(Von).The oxide trenches cause a low anode-cathode capacitance,which increases the switching speed and reduces the turn-off energy loss(Eoff).The MT SOI LIGBT exhibits a BV of 603 V at a small cell-pitch of 24 μm,a Von of 1.03 V at 100 A/cm-2,a turn-off time of 250 ns and Eoff of 4.1×10?3 mJ.The trench gate extended to BOX synchronously acts as dielectric isolation between high voltage LIGBT and low voltage circuits,simplifying the fabrication processes.
基金Supported by the National Natural Science Foundation of China under Grant No 61403014
文摘A low gate voltage operated multi-emitter-dot gated lateral bipolar junction transistor (BJT) ion sensor is proposed. The proposed device is composed of an arrayed gated lateral BJT, which is driven in the metal-oxidesemiconductor field-effect transistor (MOSFET)-BJT hybrid operation mode. Further, it has multiple emitter dots linked to each other in parallel to improve ionic sensitivity. Using hydrogen ionic solutions as reference solutions, we conduct experiments in which we compare the sensitivity and threshold voltage of the multi-emitter-dot gated lateral BJT with that of the single-emitter-dot gated lateral BJT. The multi-emitter-dot gated lateral BJT not only shows increased sensitivity but, more importantly, the proposed device can be operated under very low gate voltage, whereas the conventional ion-sensitive field-effect transistors cannot. This special characteristic is significant for low power devices and for function devices in which the provision of a gate voltage is difficult.
基金Project supported in part by the Science Foundation for Distinguished Young Scholars of Shaanxi Province,China(Grant No.2018JC-017)111 Project(Grant No.B12026)。
文摘A novel silicon carbide gate-controlled bipolar field effect composite transistor with poly silicon region(SiC GCBTP)is proposed.Different from the traditional electrode connection mode of SiC vertical diffused MOS(VDMOS),the P+region of P-well is connected with the gate in SiC GCBTP,and the polysilicon region is added between the P+region and the gate.By this method,additional minority carriers can be injected into the drift region at on-state,and the distribution of minority carriers in the drift region will be optimized,so the on-state current is increased.In terms of static characteristics,it has the same high breakdown voltage(811 V)as SiC VDMOS whose length of drift is 5.5μm.The on-state current of SiC GCBTP is 2.47×10^(-3)A/μm(V_(G)=10 V,V_(D)=10 V)which is 5.7 times of that of SiC IGBT and 36.4 times of that of SiC VDMOS.In terms of dynamic characteristics,the turn-on time of SiC GCBTP is only 0.425 ns.And the turn-off time of SiC GCBTP is similar to that of SIC insulated gate bipolar transistor(IGBT),which is 114.72 ns.
基金Project supported by the National Natural Science Foundation of China(Grant Nos.61376080 and 61674027)the Natural Science Foundation of Guangdong Province,China(Grant Nos.2014A030313736 and 2016A030311022)
文摘A novel ultralow turnoff loss dual-gate silicon-on-insulator (SOI) lateral insulated gate bipolar transistor (LIGBT) is proposed. The proposed SOI LIGBT features an extra trench gate inserted between the p-well and n-drift, and an n-type carrier stored (CS) layer beneath the p-well. In the on-state, the extra trench gate acts as a barrier, which increases the cartier density at the cathode side of n-drift region, resulting in a decrease of the on-state voltage drop (Von). In the off-state, due to the uniform carder distribution and the assisted depletion effect induced by the extra trench gate, large number of carriers can be removed at the initial turnoff process, contributing to a low turnoff loss (Eoff). Moreover, owing to the dual-gate field plates and CS layer, the carrier density beneath the p-well can greatly increase, which further improves the tradeoff between Eoff and Von. Simulation results show that Eoff of the proposed SOI LIGBT can decrease by 77% compared with the conventional trench gate SOI LIGBT at the same Von of 1.1 V.
文摘基于介质场增强(ENDIF)理论,提出了一种部分超结型薄硅层SOI横向绝缘栅双极型晶体管(PSJ SOI LIGBT)。分析了漂移区注入剂量和超结区域位置对器件耐压性能的影响,并在工艺流程中结合线性变掺杂技术和超结技术,使该器件实现了高垂直方向耐压和低导通电阻。测试结果表明,该器件的耐压达到816 V,比导通电阻仅为12.5Ω·mm^(2)。
基金Project supported by the National Basic Research Program of China(Grant No.2015CB351906)Science Foundation for Distinguished Young Scholars of Shaanxi Province,China(Grant No.2018JC-017)。
文摘A lateral insulated gate bipolar transistor(LIGBT)based on silicon-on-insulator(SOI)structure is proposed and investigated.This device features a compound dielectric buried layer(CDBL)and an assistant-depletion trench(ADT).The CDBL is employed to introduce two high electric field peaks that optimize the electric field distributions and that,under the same breakdown voltage(BV)condition,allow the CDBL to acquire a drift region of shorter length and a smaller number of stored carriers.Reducing their numbers helps in fast-switching.Furthermore,the ADT contributes to the rapid extraction of the stored carriers from the drift region as well as the formation of an additional heat-flow channel.The simulation results show that the BV of the proposed LIGBT is increased by 113%compared with the conventional SOI LIGBT of the same length L_(D).Contrastingly,the length of the drift region of the proposed device(11.2μm)is about one third that of a traditional device(33μm)with the same BV of 141 V.Therefore,the turn-off loss(E_(OFF))of the CDBL SOI LIGBT is decreased by 88.7%compared with a conventional SOI LIGBT when the forward voltage drop(VF)is 1.64 V.Moreover,the short-circuit failure time of the proposed device is 45%longer than that of the conventional SOI LIGBT.Therefor,the proposed CDBL SOI LIGBT exhibits a better V_(F)-E_(OFF)tradeoff and an improved short-circuit robustness.
基金Project supported by the Natural Science Foundation of Hunan Province, China (Grant No. 2023JJ40161)the Natural Science Foundation of Changsha, China (Grant No. kq2202163)+1 种基金the National Natural Science Foundation of China (Grant No. U21A20499)the Fundamental Research Funds for the Central Universities, China (Grant No. 531118010735)。
文摘A novel trench insulated gate bipolar transistor(IGBT) with improved dynamic characteristics is proposed and investigated. The poly gate and poly emitter of the proposed IGBT are arranged alternately along the trench. A self-biased p-MOSFET is formed on the emitter side. Owing to this unique three-dimensional(3D) trench architecture, both the turnoff characteristic and the turn-on characteristic can be greatly improved. At the turn-off moment, the maximum electric field and impact ionization rate of the proposed IGBT decrease and the dynamic avalanche(DA) is suppressed. Comparing with the carrier-stored trench gate bipolar transistor(CSTBT), the turn-off loss(E_(off)) of the proposed IGBT also decreases by 31% at the same ON-state voltage. At the turn-on moment, the built-in p-MOSFET reduces the reverse displacement current(I_(G_dis)), which is conducive to lowing dI_(C)/d_(t). As a result, compared with the CSTBT with the same turn-on loss(E_(on)), at I_(C) = 20 A/cm^(2), the proposed IGBT decreases by 35% of collector surge current(I_(surge)) and 52% of dI_(C)/d_(t).
基金Project supported by the National Natural Science Foundation of China(Grant No.61604027)the Basic and Advanced Technology Research Project of Chongqing Municipality,China(Grant No.cstc2016jcyj A1923)+3 种基金the Scientific and Technological Research Foundation of Chongqing Municipal Education Commission,China(Grant No.KJ1500404)the Youth Natural Science Foundation of Chongqing University of Posts and Telecommunications,China(Grant Nos.A2015-50 and A2015-52)the Chongqing Key Laboratory Improvement Plan,China(Chongqing Key Laboratory of Photo Electronic Information Sensing and Transmitting Technology)(Grant No.cstc2014pt-sy40001)the University Innovation Team Construction Plan Funding Project of Chongqing,China(Architecture and Core Technologies of Smart Medical System)(Grant No.CXTDG201602009)
文摘A reverse-conducting lateral insulated-gate bipolar transistor (NI.2-LltJlS|) with a trench oxide layer (IUL), teaturlng a vertical N-buffer and P-collector is proposed. Firstly, the TOL enhances both of the surface and bulk electric fields of the N-drift region, thus the breakdown voltage (BV) is improved. Secondly, the vertical N-buffer layer increases the voltage drop VpN of the P-collector/N-buffer junction, thus the snapback is suppressed. Thirdly, the P-body and the vertical N-buffer act as the anode and the cathode, respectively, to conduct the reverse current, thus the inner diode is integrated. As shown by the simulation results, the proposed RC-LIGBT exhibits trapezoidal electric field distribution with BV of 342.4 V, which is increased by nearly 340% compared to the conventional RC-LIGBT with triangular electric fields of 100.2 V. Moreover, the snapback is eliminated by the vertical N-buffer layer design, thus the reliability of the device is improved.
