公开(公告)号：US20120181614A1

公开(公告)日：2012-07-19

申请号：US13309473

申请日：2011-12-01

Applicant: Chih Sieh Teng ,  Constantin Bulucea ,  Chin-Miin Shyu ,  Fu-Cheng Wang ,  Prasad Chaparala

Inventor： Chih Sieh Teng ,  Constantin Bulucea ,  Chin-Miin Shyu ,  Fu-Cheng Wang ,  Prasad Chaparala

IPC: H01L27/088

CPC classification number: H01L29/1083 ,  H01L21/823807 ,  H01L21/823814 ,  H01L29/105

Abstract: An IGFET (40 or 42) has a channel zone (64 or 84) situated in body material (50). Short-channel threshold voltage roll-off and punchthrough are alleviated by arranging for the net dopant concentration in the channel zone to longitudinally reach a local surface minimum at a location between the IGFET's source/drain zones (60 and 62 or 80 and 82) and by arranging for the net dopant concentration in the body material to reach a local subsurface maximum more than 0.1 μm deep into the body material but not more than 0.1 μm deep into the body material. The source/drain zones (140 and 142 or 160 and 162) of a p-channel IGFET (120 or 122) are provided with graded-junction characteristics to reduce junction capacitance, thereby increasing switching speed.

Abstract translation: IGFET（40或42）具有位于主体材料（50）中的通道区（64或84）。 通过设置通道区域中的净掺杂剂浓度以在IGFET的源极/漏极区域（60和62或80和82）之间的位置处纵向达到局部表面最小值来减轻短通道阈值电压滚降和穿透，以及 通过排列主体材料中的净掺杂剂浓度达到主体材料深度超过0.1μm的局部表面最大深度，但不超过体积材料的0.1μm深。 p沟道IGFET（120或122）的源极/漏极区（140和142或160和162）具有渐变结特征以减小结电容，从而提高开关速度。

公开(公告)号：US08148777B1

公开(公告)日：2012-04-03

申请号：US12883147

申请日：2010-09-15

Applicant: Constantin Bulucea

Inventor： Constantin Bulucea

IPC: H01L29/02

CPC classification number: H01L21/823892 ,  H01L21/823807 ,  H01L21/823878 ,  H01L27/1203 ,  H01L29/1045 ,  H01L29/665 ,  H01L29/66659 ,  H01L29/7835

Abstract: An insulated-gate field-effect transistor (100, 100V, 140, 150, 150V, 160, 170, 170V, 180, 180V, 190, 210, 210W, 500, 510, or 530; or 220, 220W, or 540) is provided with a hypoabrupt vertical dopant profile below one (104; or 264 or 564) of its source/drain zones for reducing the parasitic capacitance along the pn junction between that source/drain zone and adjoining body material (108; or 268 or 568). In particular, the concentration of semiconductor dopant which defines the conductivity type of the body material increases by at least a factor of 10 in moving from that source/drain zone down to an underlying body-material location no more than 10 times deeper below the upper semiconductor surface than that source/drain zone.

Abstract translation: 绝缘栅场效应晶体管（100,100V，140,150,150V，160,170,170V，180,180V，190,210,210W，500,510或530;或220,220W或540） 在其源极/漏极区的一个（104或264或564）的下方设置有低破坏的垂直掺杂剂轮廓，用于减小沿着该源极/漏极区与相邻主体材料（108;或268或568）之间的pn结的寄生电容 ）。 特别地，限定主体材料的导电类型的半导体掺杂剂的浓度在从该源极/漏极区向下移动到下面的物体 - 物质位置之前至少增加10倍，不超过上部的10倍 半导体表面比该源/漏区。

公开(公告)号：US07973372B2

公开(公告)日：2011-07-05

申请号：US12382972

申请日：2009-03-27

Applicant: Sandeep R. Bahl ,  William D. French ,  Constantin Bulucea

Inventor： Sandeep R. Bahl ,  William D. French ,  Constantin Bulucea

IPC: H01L29/76 ,  H01L29/94 ,  H01L31/062 ,  H01L31/113 ,  H01L31/119

CPC classification number: H01L29/7835 ,  H01L21/26513 ,  H01L21/26586 ,  H01L21/82285 ,  H01L21/823807 ,  H01L21/823814 ,  H01L21/8249 ,  H01L27/0623 ,  H01L27/0922 ,  H01L29/0653 ,  H01L29/0847 ,  H01L29/1045 ,  H01L29/1083 ,  H01L29/167 ,  H01L29/6659 ,  H01L29/66659

Abstract: An insulated-gate field-effect transistor (100) provided along an upper surface of a semiconductor body contains a pair of source/drain zones (240 and 242) laterally separated by a channel zone (244). A gate electrode (262) overlies a gate dielectric layer (260) above the channel zone. Each source/drain zone includes a main portion (240M or 242M) and a more lightly doped lateral extension (240E or 242E) laterally continuous with the main portion and extending laterally under the gate electrode. The lateral extensions, which terminate the channel zone along the upper semiconductor surface, are respectively largely defined by a pair of semiconductor dopants of different atomic weights. With the transistor being an asymmetric device, the source/drain zones constitute a source and a drain. The lateral extension of the source is defined with dopant of higher atomic weight than the lateral extension of the drain.

Abstract translation: 沿着半导体主体的上表面设置的绝缘栅场效应晶体管（100）包含由沟道区（244）横向隔开的一对源极/漏极区（240和242）。 栅电极（262）覆盖沟道区上方的栅介电层（260）。 每个源极/漏极区域包括与主要部分横向连续并在栅电极下方横向延伸的主要部分（240M或242M）和更轻掺杂的侧向延伸部（240E或242E）。 沿着上半导体表面终止通道区域的侧向延伸部分分别由不同原子量的一对半导体掺杂剂限定。 在晶体管是非对称器件的情况下，源极/漏极区域构成源极和漏极。 源的横向延伸由比排水管的横向延伸更高的原子量的掺杂剂限定。

公开(公告)号：US07972918B1

公开(公告)日：2011-07-05

申请号：US12545014

申请日：2009-08-20

Applicant: Constantin Bulucea

Inventor： Constantin Bulucea

IPC: H01L21/8238

CPC classification number: H01L21/823807 ,  H01L21/823878 ,  H01L21/823892 ,  H01L27/1203

Abstract: A semiconductor structure is provided with (i) an empty well having relatively little well dopant near the top of the well and (ii) a filled well having considerably more well dopant near the top of the well. Each well is defined by a corresponding body-material region (108 or 308) of a selected conductivity type. The regions respectively meet overlying zones (104 and 304) of the opposite conductivity type. The concentration of well dopant of the selected conductivity type locally reaches a maximum in each body-material region at a location no more than 10 times deeper below the upper semiconductor surface than the overlying zone's depth, decreases by at least a factor of 10 in moving from the empty-well maximum-concentration location through the overlying zone to the upper surface, and reaches at least one other maximum in moving from the filled-well maximum-concentration location through the other zone to the upper surface.

Abstract translation: 半导体结构设置有（i）在井的顶部附近具有相对少的阱掺杂物的空阱，以及（ii）在阱的顶部附近具有相当好的掺杂剂的填充阱。 每个孔由所选择的导电类型的对应的主体材料区域（108或308）限定。 这些区域分别满足相反导电类型的覆盖区域（104和304）。 所选择的导电类型的阱掺杂剂的浓度在上半导体表面以上的深度比上覆层的深度低10倍的位置在每个主体材料区域局部达到最大值，在移动中减小至少10倍 从空井最大浓度位置通过上覆区域到上表面，并且从填充井最大浓度位置通过另一区域移动到上表面时达到至少另一个最大值。

公开(公告)号：US07838930B1

公开(公告)日：2010-11-23

申请号：US11977213

申请日：2007-10-23

Applicant: Constantin Bulucea

Inventor： Constantin Bulucea

IPC: H01L29/02

CPC classification number: H01L21/823892 ,  H01L21/823807 ,  H01L21/823878 ,  H01L27/1203 ,  H01L29/1045 ,  H01L29/665 ,  H01L29/66659 ,  H01L29/7835

Abstract: An insulated-gate field-effect transistor (500, 510, 530, or 540) has a hypoabrupt step-change vertical dopant profile below one (104 or 564) of its source/drain zones for reducing the parasitic capacitance along the pn junction between that source/drain zone and adjoining body material (108 or 568). In particular, the concentration of semiconductor dopant which defines the conductivity type of the body material largely undergoes a step increase by at least a factor of 10 in moving from that source/drain zone down to an underlying body-material location no more than 10 times deeper below the upper semiconductor surface than that source/drain zone.

Abstract translation: 绝缘栅场效应晶体管（500,510,530或540）在其源极/漏极区的一个（104或564）下方具有低于一个（104或564）的垂直掺杂剂轮廓，用于减小沿pn结的寄生电容 该源极/漏极区域和相邻的主体材料（108或568）。 特别地，限定主体材料的导电类型的半导体掺杂剂的浓度在从该源极/漏极区向下移动到下面的主体 - 材料位置时，会大大增加至少10倍，不超过10倍 比上部半导体表面更深于该源/漏区。

公开(公告)号：US20100244149A1

公开(公告)日：2010-09-30

申请号：US12382971

申请日：2009-03-27

Applicant: Constantin Bulucea ,  William D. French ,  Donald M. Archer ,  Jeng-Jiun Yang ,  Sandeep R. Bahl ,  D. Courtney Parker

Inventor： Constantin Bulucea ,  William D. French ,  Donald M. Archer ,  Jeng-Jiun Yang ,  Sandeep R. Bahl ,  D. Courtney Parker

IPC: H01L29/78 ,  H01L21/336

CPC classification number: H01L29/1083 ,  H01L21/26513 ,  H01L21/2652 ,  H01L21/26586 ,  H01L21/823412 ,  H01L21/823418 ,  H01L21/823807 ,  H01L21/823814 ,  H01L21/823892 ,  H01L27/088 ,  H01L27/0922 ,  H01L29/0653 ,  H01L29/0847 ,  H01L29/1045 ,  H01L29/105 ,  H01L29/518 ,  H01L29/66659 ,  H01L29/7835

Abstract: A group of high-performance like-polarity insulated-gate field-effect transistors (100, 108, 112, 116, 120, and 124 or 102, 110, 114, 118, 122, and 126) have selectably different configurations of lateral source/drain extensions, halo pockets, and gate dielectric thicknesses suitable for a semiconductor fabrication platform that provides a wide variety of transistors for analog and/or digital applications. Each transistor has a pair of source/drain zones, a gate dielectric layer, and a gate electrode. Each source/drain zone includes a main portion and a more lightly doped lateral extension. The lateral extension of one of the source/drain zones of one of the transistors is more heavily doped or/and extends less deeply below the upper semiconductor surface than the lateral extension of one of the source/drain zones of another of the transistors.

Abstract translation: 一组高性能类似极性的绝缘栅场效应晶体管（100,108,112,116,120和124或102,110,114,118,122和126）具有可选择地不同的侧向源 /漏极延伸，光晕口和栅介质厚度，适用于为模拟和/或数字应用提供各种晶体管的半导体制造平台。 每个晶体管具有一对源极/漏极区，栅极介电层和栅电极。 每个源极/漏极区域包括主要部分和更轻掺杂的横向延伸部分。 一个晶体管的一个源极/漏极区域的横向延伸比另一个晶体管的源极/漏极区域之一的横向延伸更深地掺杂或/并且在上部半导体表面之下更深地延伸。

公开(公告)号：US07595244B1

公开(公告)日：2009-09-29

申请号：US11975042

申请日：2007-10-16

Applicant: Constantin Bulucea ,  Fu-Cheng Wang ,  Prasad Chaparala

Inventor： Constantin Bulucea ,  Fu-Cheng Wang ,  Prasad Chaparala

IPC: H01L21/336

CPC classification number: H01L29/1083 ,  H01L21/823807 ,  H01L21/823814 ,  H01L29/105

Abstract: Fabrication of two differently configured like-polarity insulated-gate field-effect transistors (40 or 42 and 240 or 242) entails introducing multiple body-material semiconductor dopants of the same conductivity type into a semiconductor body. Gate electrodes (74 or 94) are defined such that each body-material dopant reaches a maximum concentration below the channel surface depletion regions, below all gate-electrode material overlying the channel zones (64 or 84), and at a different depth than each other body-material dopant. The transistors are provided with source/drain zones (60 or 80) of opposite conductivity type to, and with halo pocket portions of the same conductivity type as, the body-material dopants. One pocket portion (100/102 or 104) extends along both source/drain zones of one of the transistors. Another pocket portion (244 or 246) extends largely along only one of the source/drain zones of the other transistor so that it is asymmetrical.

Abstract translation: 两个不同构造的同极性绝缘栅场效应晶体管（40或42和240或242）的制造需要将相同导电类型的多个体材料半导体掺杂剂引入半导体本体。 限定栅电极（74或94），使得每个主体材料掺杂剂在沟道表面耗尽区下方达到最大浓度，低于覆盖沟道区（64或84）的所有栅电极材料，并且在不同于每个 其他体材料掺杂剂。 晶体管具有与体材料掺杂剂相同的导电类型的源极/漏极区（60或80）以及具有相同导电类型的卤素口袋部分。 一个口袋部分（100/102或104）沿着一个晶体管的源极/漏极区域延伸。 另一个口袋部分（244或246）沿着另一个晶体管的源极/漏极区域中的一个较大地延伸，使得它是不对称的。

公开(公告)号：US07176530B1

公开(公告)日：2007-02-13

申请号：US10803203

申请日：2004-03-17

Applicant: Constantin Bulucea ,  Philipp Lindorfer

Inventor： Constantin Bulucea ,  Philipp Lindorfer

IPC: H01L29/76

CPC classification number: H01L21/823807 ,  H01L21/26586 ,  H01L27/0883 ,  H01L27/0928 ,  H01L29/1041 ,  H01L29/105 ,  H01L29/665 ,  H01L29/7833

Abstract: A semiconductor technology combines a normally off n-channel channel-junction insulated-gate field-effect transistor (“IGFET”) (104) and an n-channel surface-channel IGFET (100 or 160) to reduce low-frequency 1/f noise. The channel-junction IGFET is normally of materially greater gate dielectric thickness than the surface-channel IGFET so as to operate across a greater voltage range than the surface-channel IGFET. Alternatively or additionally, the channel-junction IGFET may conduct current through a field-induced surface channel. A p-channel surface-channel IGFET (102 or 162), which is typically of approximately the same gate-dielectric thickness as the n-channel surface-channel IGFET, is preferably combined with the two n-channel IGFETs to produce a complementary-IGFET structure. A further p-channel IGFET (106, 180, 184, or 192), which is typically of approximately the same gate dielectric thickness as the n-channel channel-junction IGFET, is also preferably included. The further p-channel IGFET can be a surface-channel or channel-junction device.

Abstract translation: 半导体技术结合了正常n沟道沟道结绝缘栅场效应晶体管（“IGFET”）（104）和n沟道表面沟道IGFET（100或160），以降低低频1 / f 噪声。 沟道结IGFET通常具有比表面沟道IGFET大得多的栅介质厚度，以便在比表面沟道IGFET更大的电压范围内工作。 或者或另外，通道结IGFET可以传导电流通过场诱导的表面通道。 通常与n沟道表面沟道IGFET大致相同的栅介质厚度的p沟道表面沟道IGFET（102或162）优选与两个n沟道IGFET组合， IGFET结构。 还优选包括通常具有与n沟道沟道结IGFET大致相同的栅介质厚度的另外的p沟道IGFET（106,180,184或192）。 另外的p沟道IGFET可以是表面沟道或沟道结器件。

公开(公告)号：US06797576B1

公开(公告)日：2004-09-28

申请号：US10327352

申请日：2002-12-20

Applicant: Chih Sieh Teng ,  Constantin Bulucea ,  Chin-Miin Shyu ,  Fu-Cheng Wang ,  Prasad Chaparala

Inventor： Chih Sieh Teng ,  Constantin Bulucea ,  Chin-Miin Shyu ,  Fu-Cheng Wang ,  Prasad Chaparala

IPC: H01L21336

CPC classification number: H01L29/66492 ,  H01L21/26586 ,  H01L21/823807 ,  H01L21/823892 ,  H01L29/1045 ,  H01L29/105 ,  H01L29/665

Abstract: An IGFET (40 or 42) has a channel zone (64 or 84) situated in body material (50). Short-channel threshold voltage roll-off and punchthrough are alleviated by arranging for the net dopant concentration in the channel zone to longitudinally reach a local surface minimum at a location between the IGFET's source/drain zones (60 and 62 or 80 and 82) and by arranging for the net dopant concentration in the body material to reach a local subsurface maximum more than 0.1 &mgr;m deep into the body material but not more than 0.1 &mgr;m deep into the body material. The source/drain zones (140 and 142 or 160 and 162) of a p-channel IGFET (120 or 122) are provided with graded-junction characteristics to reduce junction capacitance, thereby increasing switching speed.

Abstract translation: IGFET（40或42）具有位于主体材料（50）中的通道区（64或84）。 通过设置通道区域中的净掺杂剂浓度以在IGFET的源极/漏极区域（60和62或80和82）之间的位置处纵向达到局部表面最小值来减轻短通道阈值电压滚降和穿透，以及 通过布置主体材料中的净掺杂剂浓度达到主体材料深度超过0.1μm的局部地下最大深度，但不超过0.1μm深的主体材料。 p沟道IGFET（120或122）的源极/漏极区（140和142或160和162）具有渐变结特征以减小结电容，从而提高开关速度。

公开(公告)号：US06627950B1

公开(公告)日：2003-09-30

申请号：US08851608

申请日：1997-05-05

Applicant: Constantin Bulucea ,  Rebecca Rossen

Inventor： Constantin Bulucea ,  Rebecca Rossen

IPC: H01L2976

CPC classification number: H01L29/7813 ,  H01L29/0696 ,  H01L29/1095 ,  H01L29/402 ,  H01L29/4232 ,  H01L29/4238 ,  H01L29/7811 ,  Y10S148/126

Abstract: Power MOSFET apparatus, and method for its production, that suppresses voltage breakdown near the gate, using a polygon-shaped trench in which the gate is positioned, using a shaped deep body junction that partly lies below the trench bottom, and using special procedures for growth of gate oxide at various trench corners.

Abstract translation: 功率MOSFET器件及其制造方法，使用位于沟槽底部下方的成形深体结，使用位于栅极的多边形沟槽来抑制栅极附近的电压击穿，并使用特殊程序 栅极氧化物在各种沟角处的生长。