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    • 3. 发明授权
    • Semiconductor device for radiation detection
    • 用于辐射检测的半导体器件
    • US08729652B2
    • 2014-05-20
    • US12282932
    • 2007-03-13
    • Anco HeringaErik Jan LousWibo Daniel Van NoortWilhelmus Cornelis Maria PetersJoost Willem Christiaan Veltkamp
    • Anco HeringaErik Jan LousWibo Daniel Van NoortWilhelmus Cornelis Maria PetersJoost Willem Christiaan Veltkamp
    • H01L31/115
    • G01T1/2018H01L27/14659H01L27/14663H01L31/115
    • The invention provides a semiconductor device (11) for radiation detection, which comprises a substrate region (1) of a substrate semiconductor material, such as silicon, and a detection region (3) at a surface of the semiconductor device (11), in which detection region (3) charge carriers of a first conductivity type, such as electrons, are generated and detected upon incidence of electromagnetic radiation (L) on the semiconductor device (11). The semiconductor device (11) further comprises a barrier region (2,5,14) of a barrier semiconductor material or an isolation material, which barrier region (2,5,14) is an obstacle between the substrate region (1) and the detection region (3) for charge carriers that are generated in the substrate region (1) by penetration of ionizing radiation (X), such as X-rays, into the substrate region (1). This way the invention provides a semiconductor device (11) for radiation detection in which the influence on the performance of the semiconductor device (11) of ionizing radiation (X), such as X-rays, that penetrates into the substrate region (1) is reduced.
    • 本发明提供了一种用于放射线检测的半导体器件(11),其包括诸如硅的衬底半导体材料的衬底区域(1)和在半导体器件(11)的表面处的检测区域(3) 在半导体器件(11)上的电磁辐射(L)入射时,产生并检测出检测区域(3)对第一导电类型(例如电子)的载流子。 半导体器件(11)还包括阻挡半导体材料或隔离材料的阻挡区域(2,5,14),所述阻挡区域(2,5,14)是衬底区域(1)和衬底区域 用于通过诸如X射线的电离辐射(X)穿透而在衬底区域(1)中产生的电荷载体的检测区域(3)。 这样,本发明提供了一种用于放射线检测的半导体器件(11),其中对穿透到衬底区域(1)中的诸如X射线的电离辐射(X)的半导体器件(11)的性能的影响, 降低了。
    • 4. 发明授权
    • Semiconductor device and method of manufacturing such a device
    • 半导体装置及其制造方法
    • US07659600B2
    • 2010-02-09
    • US11568196
    • 2005-04-12
    • Wibo Daniel Van Noort
    • Wibo Daniel Van Noort
    • H01L29/00
    • H01L29/0638H01L21/761H01L27/08
    • The invention relates to a semiconductor device (10) with a semiconductor body (1) comprising a high-ohmic semiconductor substrate (2) which is covered with a dielectric layer (3) containing charges, on which dielectric layer one or more passive electronic components (4) comprising conductor tracks (4) are present, and at the location of the passive elements (4) a semiconductor region (5) is present at the interface between the semiconductor substrate (2) and the dielectric layer (3, 4), a first conductivity-type conducting channel induced in the semiconductor substrate (2) by the charges being interrupted by, and at the location of, the semiconductor region (5).According to the invention, the semiconductor region (5) is monocrystalline and of a second conductivity type, opposite to the first conductivity type. In this way the charge of an induced channel is locally compensated by the charge of the semiconductor regions (5). The device (10) has a very low high-frequency power loss, because the inversion channel is interrupted at the location of the semiconductor region (5). The device (10) further allows for a higher thermal budget and thus for the integration of active semiconductor elements (8) into the semiconductor body (1). Preferably, the semiconductor region (5) comprises a large number of strip-shaped sub-regions (5A, 5B, 5C).
    • 本发明涉及一种具有半导体本体(1)的半导体器件(10),该半导体器件(1)包括用包含电荷的介电层(3)覆盖的高欧姆半导体衬底(2),电介质层上有一个或多个无源电子部件 (4),并且在无源元件(4)的位置处,在半导体衬底(2)和电介质层(3,4)之间的界面处存在半导体区域(5) 由在半导体区域(5)中间和位置处的电荷在半导体衬底(2)中感应的第一导电型导电沟道。 根据本发明,半导体区域(5)是与第一导电类型相反的单晶并且具有第二导电类型。 以这种方式,通过半导体区域(5)的电荷对感应通道的电荷进行局部补偿。 由于反转通道在半导体区域(5)的位置被中断,所以器件(10)具有非常低的高频功率损耗。 器件(10)进一步允许较高的热预算,从而将有源半导体元件(8)集成到半导体本体(1)中。 优选地,半导体区域(5)包括大量条形子区域(5A,5B,5C)。
    • 5. 发明申请
    • Semiconductor Device And Method Of Manufacturing Such A Device
    • 半导体器件及其制造方法
    • US20080169527A1
    • 2008-07-17
    • US11568196
    • 2005-04-12
    • Wibo Daniel Van Noort
    • Wibo Daniel Van Noort
    • H01L29/00H01L21/02
    • H01L29/0638H01L21/761H01L27/08
    • The invention relates to a semiconductor device (10) with a semiconductor body (1) comprising a high-ohmic semiconductor substrate (2) which is covered with a dielectric layer (3) containing charges, on which dielectric layer one or more passive electronic components (4) comprising conductor tracks (4) are present, and at the location of the passive elements (4) a semiconductor region (5) is present at the interface between the semiconductor substrate (2) and the dielectric layer (3, 4), a first conductivity-type conducting channel induced in the semiconductor substrate (2) by the charges being interrupted by, and at the location of, the semiconductor region (5).According to the invention, the semiconductor region (5) is monocrystalline and of a second conductivity type, opposite to the first conductivity type. In this way the charge of an induced channel is locally compensated by the charge of the semiconductor regions (5). The device (10) has a very low high-frequency power loss, because the inversion channel is interrupted at the location of the semiconductor region (5). The device (10) further allows for a higher thermal budget and thus for the integration of active semiconductor elements (8) into the semiconductor body (1). Preferably, the semiconductor region (5) comprises a large number of strip-shaped sub-regions (5A, 5B, 5C).
    • 本发明涉及一种具有半导体本体(1)的半导体器件(10),该半导体器件(1)包括用包含电荷的介电层(3)覆盖的高欧姆半导体衬底(2),电介质层上有一个或多个无源电子部件 (4),并且在无源元件(4)的位置处,在半导体衬底(2)和电介质层(3,4)之间的界面处存在半导体区域(5) 由在半导体区域(5)中间和位置处的电荷在半导体衬底(2)中感应的第一导电型导电沟道。 根据本发明,半导体区域(5)是与第一导电类型相反的单晶并且具有第二导电类型。 以这种方式,通过半导体区域(5)的电荷对感应通道的电荷进行局部补偿。 由于反转通道在半导体区域(5)的位置被中断,所以器件(10)具有非常低的高频功率损耗。 器件(10)进一步允许较高的热预算,从而将有源半导体元件(8)集成到半导体本体(1)中。 优选地,半导体区域(5)包括大量条形子区域(5A,5B,5C)。
    • 6. 发明授权
    • Method of manufacturing a semiconductor device and semiconductor device obtained by means of said method
    • 通过所述方法获得的制造半导体器件和半导体器件的方法
    • US07381656B2
    • 2008-06-03
    • US10599032
    • 2005-03-11
    • Wibo Daniel Van NoortEyup Aksen
    • Wibo Daniel Van NoortEyup Aksen
    • H01L21/31H01L21/469
    • H01L21/76229H01L21/02002
    • The invention relates to a method of manufacturing a semiconductor device comprising a substrate (1) and a semiconductor body (2) in which at least one semiconductor element is formed, wherein, in the semiconductor body (2), a semiconductor island (3) is formed by forming a first cavity (4) in the surface of the semiconductor body (2), the walls of said first cavity being covered with a first dielectric layer (6), after which, by means of underetching through the bottom of the cavity (4), a lateral part of the semiconductor body (2) is removed, thereby forming a cavity (20) in the semiconductor body (2) above which the semiconductor island (3) is formed, and wherein a second cavity (5) is formed in the surface of the semiconductor body (2), the walls of said second cavity being covered with a second dielectric layer, and one of the walls covered with said second dielectric layer forming a side wall of the semiconductor island (3).According to the invention, the same dielectric layer (6) is chosen for the first and the second dielectric layer, a lateral size of the second cavity (5) and the thickness of the dielectric layer (6) are chosen such that the second cavity (5) becomes nearly completely filled by the dielectric layer (6), and the lateral sizes of the first cavity (4) are chosen such that the walls and the bottom of the first cavity (4) are provided with a uniform coating by the dielectric layer (6). In this way, a semiconductor island (3) which is isolated from its environment can be made using a minimum number of (masking) steps.
    • 本发明涉及一种制造半导体器件的方法,该半导体器件包括其中形成有至少一个半导体元件的衬底(1)和半导体本体(2),其中在半导体本体(2)中,半导体岛(3) 通过在半导体本体(2)的表面中形成第一空腔(4)形成,所述第一腔的壁被第一介电层(6)覆盖,之后借助于穿过半导体本体 空腔(4),半导体主体(2)的侧面部分被去除,从而在半导体主体(2)中形成空腔(20),在半导体主体(2)之上形成半导体岛(3),并且其中第二腔 )形成在半导体本体(2)的表面中,所述第二腔的壁被第二电介质层覆盖,并且覆盖有形成半导体岛(3)的侧壁的所述第二电介质层的一个壁, 。 根据本发明,为第一和第二介电层选择相同的介电层(6),第二腔(5)的横向尺寸和电介质层(6)的厚度被选择为使得第二腔 (5)变得几乎完全被电介质层(6)填充,并且第一空腔(4)的横向尺寸被选择为使得第一空腔(4)的壁和底部被均匀地涂覆 电介质层(6)。 以这种方式,可以使用最少数量(掩蔽)步骤来制造与其环境隔离的半导体岛(3)。
    • 7. 发明申请
    • Method of Fabricating a Duel-Gate Fet
    • 制造决斗门的方法
    • US20080318375A1
    • 2008-12-25
    • US11815100
    • 2006-01-23
    • Wibo Daniel Van NoortFranciscus Petrus WiddershovenRadu Surdeanu
    • Wibo Daniel Van NoortFranciscus Petrus WiddershovenRadu Surdeanu
    • H01L21/8238
    • H01L29/785H01L29/66795H01L29/7854
    • The invention provides a method of fabricating an extremely short-length dual-gate FET, using conventional semi-conductor processing techniques, with extremely small and reproducible fins with a pitch and a width that are both smaller than can be obtained with photolithographic techniques. On a protrusion (2) on a substrate (1), a first layer (3) and a second layer (4) are formed, after which the top surface of the protrusion (2) is exposed. A portion of the first layer (3) is selectively removed relative to the protrusion (2) and the second layer (4), thereby creating a fin (6) and a trench (5). Also a method is presented to form a plurality of fins (6) and trenches (5). The dual-gate FET is created by forming a gate electrode (7) in the trench(es) (5) and a source and drain region. Further a method is presented to fabricate an extremely short-length asymmetric dual-gate FET with two gate electrodes that can be biased separately.
    • 本发明提供了一种使用常规半导体处理技术制造极短的双栅极FET的方法,其具有非常小且可重现的鳍,其间距和宽度都小于可以用光刻技术获得的。 在基板(1)上的突起(2)上形成第一层(3)和第二层(4),然后露出突起(2)的上表面。 相对于突起(2)和第二层(4),第一层(3)的一部分被选择性地去除,从而形成翅片(6)和沟槽(5)。 还提出了形成多个翅片(6)和沟槽(5)的方法。 通过在沟槽(5)中形成栅电极(7)和源极和漏极区域来产生双栅极FET。 此外,提出了一种制造具有可分别偏置的两个栅电极的极短的非对称双栅极FET的方法。
    • 9. 发明授权
    • Contacting and filling deep-trench-isolation with tungsten
    • 与钨接触并填充深沟隔离
    • US08294203B2
    • 2012-10-23
    • US11574337
    • 2005-09-02
    • Wibo Daniel Van NoortPeter Deixler
    • Wibo Daniel Van NoortPeter Deixler
    • H01L29/76
    • H01L21/743H01L21/763
    • Electrically isolated, deep trench isolation (DTI) structures, are formed in a wafer, and a portion of the DTI structures are converted to electrically connected structures to provide a shielding function, or to provide connection to deep buried layers. In one aspect, DTI structures include a polysilicon filling over a liner layer disposed on the inner surface of a deep trench, the polysilicon is removed by isotropic etching, and the deep trench is re-filled with a conductive material. Alternatively, the polysilicon filling remains and a contact is formed to provide an electrical connection to the polysilicon. In another aspect, a deep trench is disposed in the wafer such that a lower portion thereof is located within a deep buried layer, and after the polysilicon is removed, an anisotropic etch removes a portion of the deep trench liner from the bottom of the deep trench, thereby allowing a tungsten deposition to make electrical contact with the deep buried layer.
    • 在晶片中形成电隔离的深沟槽隔离(DTI)结构,并且将DTI结构的一部分转换成电连接的结构以提供屏蔽功能,或提供与深埋层的连接。 一方面,DTI结构包括在深沟槽的内表面上的衬垫层上的多晶硅填充,通过各向同性蚀刻去除多晶硅,并且用导电材料重新填充深沟槽。 或者,残留多晶硅填充物并形成接触以提供与多晶硅的电连接。 在另一方面,深沟槽设置在晶片中,使得其下部位于深埋层内,并且在多晶硅被去除之后,各向异性蚀刻从深层底部去除一部分深沟槽衬垫 沟槽,从而允许钨沉积与深埋层电接触。
    • 10. 发明申请
    • Contacting and Filling Deep-Trench-Isolation with Tungsten
    • 接触和填充与钨的深沟槽隔离
    • US20110147884A1
    • 2011-06-23
    • US11574337
    • 2005-09-02
    • Wibo Daniel Van NoortPeter Deixler
    • Wibo Daniel Van NoortPeter Deixler
    • H01L29/06H01L21/762
    • H01L21/743H01L21/763
    • Electrically isolated, deep trench isolation (DTI) structures, are formed in a wafer, and a portion of the DTI structures are converted to electrically connected structures to provide a shielding function, or to provide connection to deep buried layers. In one aspect, DTI structures include a polysilicon filling over a liner layer disposed on the inner surface of a deep trench, the polysilicon is removed by isotropic etching, and the deep trench is re-filled with a conductive material. Alternatively, the polysilicon filling remains and a contact is formed to provide an electrical connection to the polysilicon. In another aspect, a deep trench is disposed in the wafer such that a lower portion thereof is located within a deep buried layer, and after the polysilicon is removed, an anisotropic etch removes a portion of the deep trench liner from the bottom of the deep trench, thereby allowing a tungsten deposition to make electrical contact with the deep buried layer.
    • 在晶片中形成电隔离的深沟槽隔离(DTI)结构,并且将一部分DTI结构转换成电连接的结构以提供屏蔽功能,或提供与深埋层的连接。 一方面,DTI结构包括在深沟槽的内表面上的衬垫层上的多晶硅填充,通过各向同性蚀刻去除多晶硅,并且用导电材料重新填充深沟槽。 或者,残留多晶硅填充物并形成接触以提供与多晶硅的电连接。 在另一方面,深沟槽设置在晶片中,使得其下部位于深埋层内,并且在去除多晶硅之后,各向异性蚀刻从深层底部去除一部分深沟槽衬垫 沟槽,从而允许钨沉积与深埋层电接触。