A novel partial silicon-on-insulator laterally double-diffused metal-oxide-semiconductor transistor (PSOI LDMOS) with a thin buried oxide layer is proposed in this paper. The key structure feature of the device is a...A novel partial silicon-on-insulator laterally double-diffused metal-oxide-semiconductor transistor (PSOI LDMOS) with a thin buried oxide layer is proposed in this paper. The key structure feature of the device is an n+-layer, which is partially buried on the bottom interface of the top silicon layer (PBNL PSOI LDMOS). The undepleted interface n+-layer leads to plenty of positive charges accumulated on the interface, which will modulate the distributions of the lateral and vertical electric fields for the device, resulting in a high breakdown voltage (BV). With the same thickness values of the top silicon layer (10 p.m) and buried oxide layer (0.375 μm), the BV of the PBNL PSOI LDMOS increases to 432 V from 285 V of the conventional PSOI LDMOS, which is improved by 51.6%.展开更多
A novel silicon-on-insulator (SOI) power metM-oxide-semiconductor field effect transistor with an interface-gate (IG SOI) structure is proposed, in which the trench polysificon gate extends into the buried oxide l...A novel silicon-on-insulator (SOI) power metM-oxide-semiconductor field effect transistor with an interface-gate (IG SOI) structure is proposed, in which the trench polysificon gate extends into the buried oxide layer (BOX) at the source side and an IG is formed. Firstly, the IG offers an extra accumulation channel for the carriers. Secondly, the subsidiary depletion effect of the IG results in a higher impurity doping for the drift region. A low specific on-resistance is therefore obtained under the condition of a slightly enhanced breakdown voltage for the IG SOI. The influences of structure parameters on the device performances are investigated. Compared with the conventional trench gate SOI and lateral planar gate SOI, the specific on-resistances of the IG SOI are reduced by 36.66% and 25.32% with the breakdown voltages enhanced by 2.28% and 10.83% at the same SOI layer of 3 μm, BOX of 1 μm, and half-cell pitch of 5.5 μm, respectively.展开更多
基金supported by the Natural Science Foundation of Chongqing Science and Technology Commission(CQ CSTC)(Grant No.cstcjjA40008)the Fundamental Research Funds for the Central Universities,China(Grant No.CDJZR12160003)+1 种基金the China Postdoctoral Science Foundation(Grant Nos.2012M511906 and 2013T60835)Chongqing University Postgraduates’Science and Innovation Fund,China(Grant No.CDJXS12161105)
文摘A novel partial silicon-on-insulator laterally double-diffused metal-oxide-semiconductor transistor (PSOI LDMOS) with a thin buried oxide layer is proposed in this paper. The key structure feature of the device is an n+-layer, which is partially buried on the bottom interface of the top silicon layer (PBNL PSOI LDMOS). The undepleted interface n+-layer leads to plenty of positive charges accumulated on the interface, which will modulate the distributions of the lateral and vertical electric fields for the device, resulting in a high breakdown voltage (BV). With the same thickness values of the top silicon layer (10 p.m) and buried oxide layer (0.375 μm), the BV of the PBNL PSOI LDMOS increases to 432 V from 285 V of the conventional PSOI LDMOS, which is improved by 51.6%.
基金Supported by the National Natural Science Foundation of China under Grant Nos 61404014 and 61405018the Fundamental Research Funds for the Central Universities under Grant Nos CDJZR12160003 and 106112014CDJZR168801
文摘A novel silicon-on-insulator (SOI) power metM-oxide-semiconductor field effect transistor with an interface-gate (IG SOI) structure is proposed, in which the trench polysificon gate extends into the buried oxide layer (BOX) at the source side and an IG is formed. Firstly, the IG offers an extra accumulation channel for the carriers. Secondly, the subsidiary depletion effect of the IG results in a higher impurity doping for the drift region. A low specific on-resistance is therefore obtained under the condition of a slightly enhanced breakdown voltage for the IG SOI. The influences of structure parameters on the device performances are investigated. Compared with the conventional trench gate SOI and lateral planar gate SOI, the specific on-resistances of the IG SOI are reduced by 36.66% and 25.32% with the breakdown voltages enhanced by 2.28% and 10.83% at the same SOI layer of 3 μm, BOX of 1 μm, and half-cell pitch of 5.5 μm, respectively.
