SEMICONDUCTOR POWER DEVICE WITH MULTIPLE DRAIN STRUCTURE AND CORRESPONDING MANUFACTURING PROCESS
    12.
    发明公开
    SEMICONDUCTOR POWER DEVICE WITH MULTIPLE DRAIN STRUCTURE AND CORRESPONDING MANUFACTURING PROCESS 审中-公开
    具有多漏结构及相关制造工艺半导体功率器件

    公开(公告)号:EP1911075A1

    公开(公告)日:2008-04-16

    申请号:EP06776161.9

    申请日:2006-07-07

    Abstract: Process for manufacturing a multi-drain power electronic device (30) integrated on a semiconductor substrate (100) of a first type of conductivity whereon a drain semiconductor layer (20) is formed, characterised in that it comprises the following steps: - forming at least a first semiconductor epitaxial layer (21) of the first type of conductivity of a first value of resistivity (Á 1 ) forming the drain epitaxial layer (20) on the semiconductor substrate (100), - forming first sub-regions (51) of a second type of conductivity by means of a first selective implant step with a first implant dose (¦ 1P ), - forming second sub-regions (D1,D1a) of the first type of conductivity by means of a second implant step with a second implant dose (¦ 1N ), - forming a surface semiconductor layer (23) wherein body regions (40) of the second type of conductivity are formed being aligned with the first sub-regions (51), - carrying out a thermal diffusion process so that the first sub-regions (51) form a single electrically continuous column region (50) being aligned and in electric contact with the body regions (40).

    POWER FIELD EFFECT TRANSISTOR AND MANUFACTURING METHOD THEREOF
    13.
    发明公开
    POWER FIELD EFFECT TRANSISTOR AND MANUFACTURING METHOD THEREOF 审中-公开
    功率场效应晶体管及其制造方法

    公开(公告)号:EP1908117A2

    公开(公告)日:2008-04-09

    申请号:EP06762482.5

    申请日:2006-07-07

    Abstract: Method for manufacturing electronic devices on a semiconductor substrate (1,1a;10,11) with wide band gap comprising the steps of: - forming a screening structure (3a,20) on said semiconductor substrate (1,1a;10,11) comprising at least a dielectric layer (2,20) which leaves a plurality of areas of said semiconductor substrate (1,1a;10,11) exposed, - carrying out at least a ion implantation of a first type of dopant in said semiconductor substrate (1,1a;10,11) to form at least a first implanted region (4,40), carrying out at least a ion implantation of a second type of dopant in said semiconductor substrate (1,1a;10,11) to form at least a second implanted region (6,6c;60,61) inside said at least a first implanted region (4,40), - carrying out an activation thermal process of the first type and second type of dopant with low thermal budget suitable to complete said formation of said at least first and second implanted regions (4,40;6,60).

    Abstract translation: 用于在具有宽带隙的半导体衬底(1,1a; 10,11)上制造电子器件的方法,包括以下步骤:在所述半导体衬底(1,1a; 10,11)上形成屏蔽结构(3a,20),其包括 至少使所述半导体衬底(1,1a,10,11)的多个区域露出的电介质层(2,20),在所述半导体衬底(1,1a,10,11)中至少进行第一类型掺杂物的离子注入 ,1a; 10,11)以形成至少第一注入区(4,40),在所述半导体衬底(1,1a; 10,11)中执行至少第二类型掺杂物的离子注入以形成在 在所述至少第一注入区域(4,40)内部的至少第二注入区域(6,6c; 60,61),以低热预算执行适合完成的第一类型和第二类型掺杂物的激活热处理 所述至少第一和第二注入区域(4,40; 6,60)的所述形成。

    SEMICONDUCTOR POWER DEVICE WITH MULTIPLE DRAIN AND CORRESPONDING MANUFACTURING PROCESS
    14.
    发明公开
    SEMICONDUCTOR POWER DEVICE WITH MULTIPLE DRAIN AND CORRESPONDING MANUFACTURING PROCESS 有权
    具有多个排出及相关制造工艺半导体功率器件

    公开(公告)号:EP1908101A1

    公开(公告)日:2008-04-09

    申请号:EP06762481.7

    申请日:2006-07-07

    Abstract: Process for manufacturing a multi-drain power electronic device (30) integrated on a semiconductor substrate (100) of a first type of conductivity, comprising the following steps: forming a first semiconductor layer (21) of the first type of conductivity and of a first resistivity (Á 1 ) value on the semiconductor substrate (100), forming at least a second semiconductor layer (22) of a second type of conductivity of a second resistivity (Á 2 ) value on the first semiconductor layer (21), forming, in this at least a second semiconductor layer (22), a first plurality of implanted regions (D1) of the first type of conductivity by means of a first selective implant step with a first implant dose (¦ 1 ) , forming, above this at least a second semiconductor layer (22), a superficial semiconductor layer (26) of the first type of conductivity of a third resistivity (Á 6 ) value, forming in the surface semiconductor layer (26) body regions (40) of the second type of conductivity, the body regions (40) being aligned with portions of the semiconductor layer (22) free from the plurality of implanted regions (D1), carrying out a thermal diffusion step so that the plurality of implanted regions (D1) form a plurality of electrically continuous implanted column regions (D) along this at least a second semiconductor layer (22), the plurality of column implanted regions (D) delimiting a plurality of column regions (50) of the second type of conductivity aligned with the body regions (40).

    POWER ELECTRONIC DEVICE OF MULTI-DRAIN TYPE INTEGRATED ON A SEMICONDUCTOR SUBSTRATE AND RELATIVE MANUFACTURING PROCESS
    15.
    发明公开
    POWER ELECTRONIC DEVICE OF MULTI-DRAIN TYPE INTEGRATED ON A SEMICONDUCTOR SUBSTRATE AND RELATIVE MANUFACTURING PROCESS 有权
    在HALF-线路基板及相关制造工艺多漏式电子电子元器件性能

    公开(公告)号:EP1851804A2

    公开(公告)日:2007-11-07

    申请号:EP06723076.3

    申请日:2006-02-22

    CPC classification number: H01L29/66712 H01L29/0634 H01L29/0847 H01L29/1095

    Abstract: Power semiconductor device (30) integrated on a semiconductor substrate (100) of a first type of conductivity comprising a plurality of elemental units, each elemental unit comprising a body region (40) of a second type of conductivity realised on a semiconductor layer (20) of the first type of conductivity formed on the semiconductor substrate (100), and a column region (50) of the first type of conductivity realised in said semiconductor layer (20) below the body region (40), wherein the semiconductor layer (20) comprises a plurality of semiconductor layers (21, 22, 23, 24), overlying each other, the resistivity of each layer being different from that of the other layers, and wherein said column region (50) comprises a plurality of doped sub-regions (51, 52, 53, 54), each realised in one of said semiconductor layers (21, 22, 23, 24), wherein the amount of charge of each doped sub-regions (51, 52, 53, 54) balances the amount of charge of the semiconductor layer (21, 22, 23, 24).

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