Two kinds of structure of unit in SiC power MOSFET: plane structure and groove structure
There are mainly two kinds of structure of unit in SiC power MOSFET: plane structure and groove structure. The structure of the planar SiC MOSFET is shown in figure 1. This structure is characterized by a simple process, good unit consistency, and high avalanche energy.
However, in the middle of this structure, the N region is sandwiched between two P regions, and when the current is limited to the narrow N region near the P body, the JFET effect will be produced, thus increasing the on-state resistance. at the same time, the parasitic capacitance of this structure is also larger.
Figure 1: the structure of a planar SiC MOSFET.
The structure of the slot SiC MOSFET is shown in figure 2.
In this structure, the gate is embedded in the matrix to form a vertical channel. Due to the trenching, the process becomes complex, and the consistency of the element and the avalanche energy is worse than the plane structure.
However, because this structure can increase the cell density, there is no JFET effect, the channel crystal plane achieves the best channel mobility, and the on-resistance is obviously lower than that of the planar structure; at the same time, the parasitic capacitance is smaller, the switching speed is faster, and the switching loss is very low, so this structure is studied and adopted in the new generation of structures.
Figure 2: structure of trench SiC MOSFET.
The main problem of the groove structure SiC MOSFET is that because the device works in a high voltage state, the internal working electric field strength is high, especially at the bottom of the groove, the working electric field strength is very high, and it is easy to exceed the maximum critical electric field strength locally, resulting in local breakdown and affecting the reliability of the device, as shown in figure 3.
Figure 3: internal working electric field of trench SiC MOSFET structure.
Cymbal. Therefore, the technical evolution direction of the new generation of SiC MOSFET trench structure is how to reduce the working electric field intensity at the bottom of the trench, such as the double trench structure of Rohm, the asymmetric trench structure of Infineon, and so on, as shown in figure 4 and figure 5.
Figure 4:Rohm double trench structure
Figure 5:Infineon asymmetric trench structure.
The core of these structures is to either add a buffer layer at the bottom of the groove or move the P region down to form a depletion layer between P and N at the bottom of the groove, as shown in figures 6 and 7 so that the electric field of the oxide layer at the bottom of the groove is partially transferred to the P region depletion layer to reduce the electric field at the bottom of the groove.
Figure 6: Schematic diagram of reducing the working electric field at the bottom of the groove
Figure 7:Infineon asymmetrical groove structure internal electric field distribution (picture source network).
The basic process and cost proportion of planar structure SiC MOSFET is shown in figure 8 and figure 9.
It can be seen that at present, the substrate of SiC crystal still accounts for a very large proportion, reaching 38%. If the substrate thinning and polishing process of SiC crystal is added, the proportion is as high as 50%.
The main reason is that SiC grows slowly, the temperature is high, the process is complex, and it is easy to produce all kinds of lattice defects.
The growth rate of Si is 100mm/hour, the maximum diameter is 450mm, and the maximum thickness is 2m. The growth rate of sic is 100300 um/ hours, 2100 °C, the maximum diameter 150mm, and the maximum thickness 50mm.
The proportion of the cost of the epitaxial process is about 17%, the proportion of the packaging cost is about 11%, and the cost caused by the yield of the product is 21%.
How to control the defects in the SiC MOSFET production process and improve the yield in the production process is still an important problem that manufacturers need to face, which is not only related to the cost of the product but also related to the reliability of the product application in the customer.
Figure 8: basic process of planar structure SiC MOSFET
Figure 9: Proportion of process cost of planar structure SiC MOSFET
- |
- +1 赞 0
- 收藏
- 评论 0
本文由李凤婷转载自HI-SEMICON News,原文标题为:Structure and characteristics of SiC MOSFET,本站所有转载文章系出于传递更多信息之目的,且明确注明来源,不希望被转载的媒体或个人可与我们联系,我们将立即进行删除处理。
相关推荐
【技术】探究碳化硅SiC MOSFET器件的UIS可靠性
近年来,SiC器件的发展取得了重大进展,尤其是在其可靠性方面,这使得SiC基器件已成为硅基功率器件的可行替代品。本文中HI-SEMICON将与大家一起探讨碳化硅SiC MOSFET器件的UIS可靠性。
【技术】解析SiC MOSFET结构及特性
本文中HI-SEMICON将为大家解析SiC MOSFET结构及特性。
解读SiC MOSFET关键参数——Vth
当代电子技术的发展不仅需要高效性能,还需要可靠和可持续的解决方案。而SiC MOSFET作为一种新型的功率器件,我们要聊的是碳化硅MOSFET中另一个关键参数——Vth,这个参数不仅关系到器件的开启与关闭,还直接影响到器件的导通损耗和开关速度,进而影响到整个系统的效率和可靠性。本文解读SiC MOSFET关键参数——Vth ,希望通过本文的介绍,您能对SiC MOSFET的Vth有更深入的了解。
HI-SEMICON(深鸿盛)MOSFET/SiC肖特基二极管/SiC MOSFET选型指南
目录- 公司简介 MOSFET Product Introduction VDMOS 超结MOSFET 中低压MOSFET 碳化硅肖特基二极管 碳化硅MOS MOSFET/SiC肖特基二极管封装
型号- SCF60R190C,SFD3006T,SFD6003T,SGP104R5T,SFS0406T4,SFM6005DT,SFD7N70,SFW90N25,SFQ0320T4,SFD18N20,SFM4009T,SFE6001T2,SFM6004T5,SFK2N50,SFF60N06,SFN4006T5,SFM0420T4,SFP10003PT,SFF18N20,SCF65R190TF,SFD2N50,SFM4004PT,SFS6003PT,SFP33N10,SFS4010T,SGS6001T4,SGP6008T,SFS3401,SFQ0318T4,SC3D40120D,SFS3400,SFK1N65,SCD65R960C,SFS4010T2,SFF5N80,SFS0407T4,SFS3407,SFD6005T,SFD10003PT,SFD7N50,SFM6005ST,SFF18N50,SFP40P10,SGS15HR430T,SFA10015T,SFP50N06,SCF65R640C,SFD3003T,SFQ0322T4,SFF12N65,SFD6006T,SGD105R5T,SFP11P20,SFD6N70,SFS6007T,SGM10HR14T,SCF65R380C6,SFS3400.A,SFS3001T2,SCD70R600C,SFQ0420T4,SCF60R580C,SGXXXXXPT,SGM062R3T,SFS4525T,SFD3004T5,SFS3401A,SGM066R5T,SFN3009T,SGM031R7T,SFB11N90,SCD70R900C,SFU3006T,SFP9N20,SFA110P06,SFR0305T2,SFF50N06,SFD6007T,SCD80R500S,SC3D08065G,SCF65R380C,SFD4006T,SC3D08065I,SFN0315T4,SFN3003PT,SFA6005T,SFS4008T2,SFS2300,SGP157R5T,SFS2301,SFM10015T,SFH8402DW,SC3D04065E,SCU70R900C,SCF60R280C,SFS2304,SFS2303,SFF13N50,SFS2305,SC3D04065I,SFF7N50,SCF65R540T,SFD50N06,SFP20007,SFU18N20,SGP104R0T,SCD65R1K2C,SFN0330T2,SFD6008T,SGM107R7T,SC3D04065A,SFM4010T,SFF20N50,SC3D20065D,SFP40N20,SFS0307T4,SFD3012T,SFF7N65,SCD60R580C,SFU5N20,SC3D10065A,SGM105R0T,SCF65R310C,SCF60R360C6,SFS0405T4,SC3D10065G,SC3D10065I,SFP6P10,SFM4005DT,SC3K080120,SCK65R1K15C,SFW50N25,SFU4N65,SFN0413T4,SFD5N65,SFP30P10,SFM10003PT,SC3D08065A,SFP18P10,SFD4N90,SFF7N70,SCF60R125C,SFXXXXXPTX,SFD4006PT,SFD4003T,SCF70R600C,SFF6005T,SFS0306T4,SCF80R950C,SGA104R0T,SFD3010T,SFE3007T,SFD5N50,SFP3006T,SFP3018T,SFP18N20,SGP103R0T,SCW65R075CF,SCF65R170C,SFS6012T2,SGD6008T,SGM041R8T,SFD4001PT4,SFD4001PT5,SFF8N65,SFN3006PT,SC3K040120,SGM6008T,SFD4N70,SCW60R030CF,SFB50N25,SCW65R041CF,SFP6005T,SFS2013PT,SCF70R420C,SCW65R090C,SGM031R1T,SCD70R420C,SC3K075120,SFD33N10,SCW65R099TF,SFP5P03,SCF60R160C,SFR0206T2,SFD4N65,SC3D15120H,SFS2N7002,SFF33N10,SCF70R360C6,SFD2008T,SFN3003T,SFS2302B,SGM109R5T,SFM6008T,SFD3006PT,SFD6003PT,SGA104R5T,SFF20N65,SFK4N65,SFB90N25,SFD5N20,SFR0205PT2,SGM030R7T,SFF8N80,SC3D30065D,SFN3002T,SFU9N20,SFD7N65E,SFD9N65,SFD4004PT,SFF20N70,SGM042R4T,SFP6007T,SFS3401B,SFS4435,SFU6003T,SGU6008T,SFM0430T2,SFF10N70,SCF60R360C,SFD2006T,SC3D06065E,SC3D06065G,SFP75P55,SC3D10120H,SFF3N80,SC3D06065A,SCD70R600C6,SCD65R380C,SFD14N25,SC3K015120,SFSAP4580,SFS6010T2,SCD65R540T,SGP105R5T,SFF4N65,SFF10N65,SC3D30120H,SFM0320T4,SC3D30120D,SC3D16065A,SC3D16065D,SC3D16065G,SFP27P20,SC3K050120,SFU6005T,SFW10P04,SFD3N50,SFF4N70,SFM10008T,SFF9N90,SCXXXXXXXXFX,SFD2003T,SFN0318T2,SFD3009T,SFM3011T,SFD6005PT,SC3K032120,SFP110N55,SFF16N65,SC3D12065A,SFF10N80,SFF5N50,SC3D12065G,SGD10HR20T,SC3D12065I,SC3D20120H,SFP59N10,SFN6004T5,SXXXXXXX,SFD9N20,SCF65R240C,SC3D06065I,SCD65R640C,SFS2012PT,SGA105R5T,SFN0250T2,SFM3012T,SC3D20120D,SGM041R3T
HI-SEMICON 产品电机行业分享
描述- 本文介绍了深鸿盛电子有限公司,一家专注于半导体功率器件设计、制造、技术服务与销售的公司的产品和应用。文章涵盖了公司简介、发展历程、专利技术、封装展示、电机行业介绍、常用电机类型、电动工具行业分析以及未来发展趋势等内容。
型号- SGX10HR10T,SGM066R5T,SGM105R0T,SFN3009T,SGM031R7T,SGP104R5T,SFN3003T,MUR1660T,SGM109R5T,SFN3002PT,SFN3003PT,SFD6003PT,SGM041R8T,SFP6008T,SCX65R380C,SFD6005PT,SGM042R1T,SFN4006T5,SGP105R5T,SCF65R640C,MUR1560T,SCF65R540T,SGM107R7T,SC3D08060A,SFS4010T,SGM031R1T,SFDP12N65,SCF65R240C,SFN4009T,SFM3012T,SGM041R3T
HI-SEMICON深鸿盛公司介绍 以奋斗者为本,争做半导体功率器件领航者
型号- SFM0420T4,SFN3009T,SFS0407T4,SGD15N10,SFN3006PT,SFS300T12,SFD2006T,SGM6008T,SFM0320T4,SGD10HR20T,SFD6008T,SGS6001T4,SFN3003PT,SFQ0320T4,SFQ0420T4,SGM041R8T,SFM4009T,SFM041R1T,SFS4525T
HI-SEMICON 产品储能行业分享
描述- 本文介绍了深鸿盛电子有限公司,一家专注于半导体功率器件设计、制造、技术服务与销售的公司的产品和应用。文章涵盖了公司简介、封装展示、储能行业介绍、新型储能产业链分析、储能系统发展趋势等内容。
型号- SCF60R190C,SGM066R5T,SFF16N50,SFP9N20,SFF50N06,SFP3018T,SC3D06065A,SGP103R0T,SFP18N20,SCF65R170C,HGN042N10A,SGM042R1T,XNP40N60TH,SCF65R190TF,SFF13N50,IXFH22N65,SCW65R090CF,SGM6008T,SGM105R5T,SGS10HR11T,SGM107R7T,SFP6005T,SFM4010T,SCW65R090C,SC3D20065A,SFF20N50,MUR1660CT,SCW65R099TF,SCP65R090CF,SCF60R160C,SC3D10065A,SGM105R0T,SFF33N10,SGP105R0T,SFM10008T,SGM109R5T,SFM6008T,SFM6005ST,SFF18N50,MUR1560G,SFF20N65,SFP110N55,SFF16N65,SFP50N06,SC3D08065A,SC3D12065I,SCF60R125C,SFP59N10,SGM10HR14T,SC3D06065I,SCF65R240C,SGM042R4T,SFP6007T
HI-SEMICON多款MOSFET在户用储能上的应用,具有稳定性强、内阻低、体积小等特性
户用储能又称为家庭储能系统,是一种安装在家庭或小型商业建筑中的储能系统。这种系统的主要功能是将太阳能知、风能等可再生能源转化为电能并储存起来,以供家庭或商业建筑使用。本文介绍HI-SEMICON MOSFET在户用储能上的应用。
HI-SEMICON 产品 DC-DC 电源分享
描述- 本资料介绍了深鸿盛电子有限公司的DC-DC电源产品及相关知识。内容包括公司简介、发展历程、专利情况、封装展示、电源模块介绍、DC-DC模块拓扑、电子元器件温度标准、DC-DC模块选型、发展趋势、产业链全景图以及主要器件型号。
型号- SC3D40065D,SC3D40120D,SC3D40065I,SC3D40065H,SC3D15120H,SC3D40065G,SGP104R5T,SC3D10120H,SGP103R0T,SGM15HR11T,S3M015120K3,SFM6008T,S3M040120K3,S3M065120K3,SGD6008T,SGA104R5T,S3M032120K3,SC3D40065A,SFA10015T,SGP157R5T,SGP105R5T,SC3D30065I,SC3D30065G,SC3D30065H,SC3D30120H,S3M050120K3,SFP20007,SGD105R5T,SGP104R0T,SC3D30065D,SC3D30120D,SC3D30065A,SGP10HR10T,S3M075120K3,SC3D20065I,SC3D20065H,SC3D20120H,SFP4024T,TSFD6008T,SC3D20065A,SGP6008T,SGA105R5T,SGA104R0T,SC3D20065D,SC3D20065G,SC3D20120D
【元件】HI-SEMICON MOSFET可用在充电桩上,为系统设计提供更多选择
深鸿盛MOSFET系列产品,通过优化器件结构设计,采用先进的工艺制造技术,进一步提高了产品性能,具有更优的雪崩耐量,提高了器件应用中的可靠性。同时,采用自主创新先进的多层外延技术,优化了器件开关特性,使其在系统应用中具有更好的表现,为系统设计提供更多选择。
SiC MOSFET以其工作频率高、低导通、开关损耗低等优点,在感应加热电源中广泛应用
感应加热是通过电磁感应加热导电物体(通常是金属)的过程,通过物体内部的涡流产生热量。SiC MOSFET以其工作频率高、低导通、开关损耗低等优点,是感应加热电源最有前途的半导体器件。
HI-SEMICON(深鸿盛)公司简介及MOSFET产品介绍 ∣视频
本视频主要分四个部分对HISEMICON(深鸿盛)的MOSFET产品做出如下简要介绍:1、公司简介;2、产品介绍;3、品质管理;4、应用领域。
HI-SEMICON 产品 OBC 行业分享
型号- SCP65R090CF,SFS3401,SC3D40065D,SC3D40120D,SFS3400,SC3D40065I,SC3D40065H,SC3D15120H,SC3D40065G,SC3D10120H,SGP103R0T,SCW65R075CF,S3M040120K3,S3M065120K3,SCW65R050CF,SFA1G015T,S3M032120K3,SGA104R5T,SC3D40065A,SCW65RG41CF,SCF65R110CF,SC3D30065I,SC3D30065G,SC3D30065H,SC3D30120H,SC3D30065D,SC3D30120D,SGP104R0T,SC3D30065A,S3M075120K3,SC3D20065I,SC3D20065H,SC3D20120H,SCT65R090CF,SFP4024T,SC3D20065A,SGP1G4R5T,SC3D20065D,SGA104R0T,SFS2W7002,SC3D20065G,SC3D20120D
HI-SEMICON多款MOSFET产品满足光伏逆变器的不同应用需求
SiC MOSFET产品在光伏逆变器中是一种重要的功率开关器件,可以承担关键的电源开关和电流控制功能。在光伏逆变器中,SiC MOSFET产品通常作为主开关管使用,用于控制输入直流电源的开关和输出交流电源的频率和电压。HI-SEMICON提供多款MOSFET产品满足光伏逆变器的不同应用需求。
SC3K040120 40MΩ,1200V碳化硅功率MOSFET
描述- 本资料介绍了SC3K040120型碳化硅功率MOSFET的特性。该器件采用第三代SiC MOSFET技术,具有高阻断电压、低导通电阻和高速度开关等特点。其主要优点包括降低开关损耗、提高系统效率、适用于高温应用和硬切换,并具有较高的可靠性。
型号- SC3K040120
电子商城
现货市场
服务
定制液冷板尺寸5mm*5mm~3m*1.8m,厚度2mm-100mm,单相液冷板散热能力最高300W/cm²。
最小起订量: 1片 提交需求>
登录 | 立即注册
提交评论