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    • 1. 发明授权
    • Titanium polycide stabilization with a porous barrier
    • 具有多孔屏障的多晶硅化钛稳定剂
    • US6057220A
    • 2000-05-02
    • US936029
    • 1997-09-23
    • Atul C. AjmeraChristine DehmAnthony G. DomenicucciGeorge G. GiffordStephen K. LohChristopher ParksViraj Y. Sardesai
    • Atul C. AjmeraChristine DehmAnthony G. DomenicucciGeorge G. GiffordStephen K. LohChristopher ParksViraj Y. Sardesai
    • H01L21/28H01L29/49H01L21/44H01L21/425
    • H01L21/28061H01L29/4933
    • A "porous barrier" is formed without formation of a discrete barrier layer by enriching grain boundaries of a body of polysilicon with nitrogen to inhibit thermal mobility of silicon species therealong. In a polycide gate/interconnect structure, the reduced mobility of silicon suppresses agglomeration of silicon in a metal silicide layer formed thereon. Since silicon agglomeration is a precursor of a polycide inversion phenomenon, polycide inversion which can pierce an underlying oxide and cause device failure is effectively avoided. The increased thermal stability of polycide structures and other structures including a body of polysilicon thus increases the heat budget that can be withstood by the structure and increases the manufacturing process window imposed by the presence of polysilicon which can be exploited in other processes such as annealing to develop a low resistance phase of refractory metal silicide included in the polycide structure, drive-in annealing for formation of source/drain regions of field effect transistors and the like.
    • 通过用氮富集多晶硅体的晶界而形成不形成离散阻挡层的“多孔阻挡层”,以抑制硅物质的热迁移率。 在多晶硅栅极/互连结构中,硅的迁移率降低抑制了在其上形成的金属硅化物层中的硅的聚集。 由于硅团聚是多杀线反转现象的前体,因此有效地避免了可能刺穿潜在氧化物并导致器件故障的多硅化物反转。 因此,多晶硅结构和包括多晶硅体在内的其他结构的热稳定性增加,因此增加了可被该结构承受的热量预算,并且增加了存在多晶硅所产生的制造工艺窗口,这可以在其它工艺中被利用,例如退火 开发包括在多晶硅结构中的难熔金属硅化物的低电阻相,用于形成场效应晶体管的源极/漏极区域的驱动退火等。
    • 4. 发明授权
    • Semiconductor wafer edge bead removal method and tool
    • 半导体晶圆边缘除珠方法及工具
    • US06497784B1
    • 2002-12-24
    • US09441862
    • 1999-11-17
    • Bradley P. JonesViraj Y. Sardesai
    • Bradley P. JonesViraj Y. Sardesai
    • H01L2100
    • H01L21/6708H01L21/31053
    • A method for planarizing a dielectric layer on a semiconductor wafer is provided. In one aspect, the wafer is coated with a resist and the resist selectively removed forming an uncoated peripheral portion of the wafer. The partially coated wafer is then exposed to an etchant such as RIE to etch the dielectric material not covered by the resist and forming a profiled dielectric layer having a thinner peripheral dielectric portion and a remaining thicker original dielectric central portion. The profiled wafer is then planarized using CMP. The dielectric layer is typically SiO2, PSG, BSP, or BPSG. In another method and apparatus of the invention, a dielectric coated wafer is secured to a rotating turntable and a liquid etchant sprayed at the periphery of the wafer from a distribution conduit to etch and remove dielectric from a circumferential edge of the wafer forming a profiled dielectric layer as above which is then planarized by CMP. In another aspect of the invention, a CMP polished semiconductor wafer having an edge bead is planarized by polishing only the edge bead of the dielectric layer using a special polishing tool or a CMP apparatus to remove the edge bead from the dielectric layer. Planarized semiconductor wafers made using the method and apparatus of the invention are also provided.
    • 提供了一种用于平坦化半导体晶片上的电介质层的方法。 在一个方面,晶片被涂覆有抗蚀剂,并且抗蚀剂被选择性地去除,形成晶片的未涂覆的周边部分。 然后将部分涂覆的晶片暴露于诸如RIE的蚀刻剂以蚀刻未被抗蚀剂覆盖的介电材料,并形成具有更薄的外围电介质部分和剩余较厚的原始介电中心部分的异型电介质层。 然后使用CMP对异型晶片进行平面化。 电介质层通常是SiO 2,PSG,BSP或BPSG。 在本发明的另一种方法和装置中,将电介质涂覆的晶片固定到旋转转盘和从分配导管在晶片周边喷射的液体蚀刻剂,以从晶圆的周边边缘蚀刻并去除电介质,从而形成异型电介质 层,然后通过CMP平坦化。 在本发明的另一方面,通过使用特殊的抛光工具或CMP装置仅抛光电介质层的边缘珠来平坦化具有边缘珠的CMP抛光的半导体晶片,以从电介质层去除边缘珠。 还提供了使用本发明的方法和装置制造的平面化的半导体晶片。
    • 5. 发明授权
    • Cross-coupling of gate conductor line and active region in semiconductor devices
    • 半导体器件中栅极导线与有源区的交叉耦合
    • US08853700B2
    • 2014-10-07
    • US13207102
    • 2011-08-10
    • Viraj Y. SardesaiRobert C. Wong
    • Viraj Y. SardesaiRobert C. Wong
    • H01L29/10H01L27/092H01L21/768H01L27/11H01L27/02H01L29/66H01L29/51
    • H01L27/1104H01L21/76895H01L27/0211H01L27/092H01L29/517H01L29/66545Y10S257/903Y10S257/904
    • Cross-coupling between a gate conductor and an active region of a semiconductor substrate is provided by forming a gate dielectric layer on the semiconductor substrate and lithographically patterning the gate dielectric layer to form opening therein over a portion of the active region at which electrical contact with the gate conductor is desired. After implanting electrical dopants, a gate conductor layer is deposited and patterned. A remaining portion of the gate conductor layer includes an integral conductor structure, which includes a first portion overlying a gate dielectric over an active region and a second portion contacting the semiconductor material of the same active region or a different active region. The gate dielectric layer can be deposited within gate cavities in planarization dielectric material layer in a replacement gate scheme, or can be deposited on planar surfaces of active regions and/or shallow trench isolation structures in a gate first processing scheme.
    • 通过在半导体衬底上形成栅极电介质层并在栅极电介质层上进行光刻图案以形成开口,在有源区域的一部分上与电极接触 需要栅极导体。 在注入电掺杂物之后,沉积并图案化栅极导体层。 栅极导体层的剩余部分包括整体导体结构,其包括覆盖有源区上的栅极电介质的第一部分和接触相同有源区或不同有源区的半导体材料的第二部分。 栅极电介质层可以以替代栅极方案沉积在平坦化介电材料层的栅极腔内,或者可以在栅极第一处理方案中沉积在有源区和/或浅沟槽隔离结构的平面表面上。
    • 6. 发明申请
    • CROSS-COUPLING OF GATE CONDUCTOR LINE AND ACTIVE REGION IN SEMICONDUCTOR DEVICES
    • 栅极导体线和半导体器件中的主动区域的交叉耦合
    • US20130037864A1
    • 2013-02-14
    • US13207102
    • 2011-08-10
    • Viraj Y. SardesaiRobert C. Wong
    • Viraj Y. SardesaiRobert C. Wong
    • H01L27/085H01L21/28
    • H01L27/1104H01L21/76895H01L27/0211H01L27/092H01L29/517H01L29/66545Y10S257/903Y10S257/904
    • Cross-coupling between a gate conductor and an active region of a semiconductor substrate is provided by forming a gate dielectric layer on the semiconductor substrate and lithographically patterning the gate dielectric layer to form opening therein over a portion of the active region at which electrical contact with the gate conductor is desired. After implanting electrical dopants, a gate conductor layer is deposited and patterned. A remaining portion of the gate conductor layer includes an integral conductor structure, which includes a first portion overlying a gate dielectric over an active region and a second portion contacting the semiconductor material of the same active region or a different active region. The gate dielectric layer can be deposited within gate cavities in planarization dielectric material layer in a replacement gate scheme, or can be deposited on planar surfaces of active regions and/or shallow trench isolation structures in a gate first processing scheme.
    • 通过在半导体衬底上形成栅极电介质层并在栅极电介质层上进行光刻图案以形成开口,在有源区域的一部分上与电极接触 需要栅极导体。 在注入电掺杂物之后,沉积并图案化栅极导体层。 栅极导体层的剩余部分包括整体导体结构,其包括覆盖有源区上的栅极电介质的第一部分和接触相同有源区或不同有源区的半导体材料的第二部分。 栅极电介质层可以以替代栅极方案沉积在平坦化介电材料层的栅极腔内,或者可以在栅极第一处理方案中沉积在有源区和/或浅沟槽隔离结构的平面表面上。
    • 10. 发明申请
    • METHOD OF SILICIDE FORMATION FOR NANO STRUCTURES
    • 纳米结构硅酸盐形成方法
    • US20090029549A1
    • 2009-01-29
    • US11781599
    • 2007-07-23
    • Oh-Jung KwonRobert J. PurtellViraj Y. Sardesai
    • Oh-Jung KwonRobert J. PurtellViraj Y. Sardesai
    • H01L21/44
    • H01L21/28518
    • A method forms a first layer over a second layer that comprises silicon. A mask is formed and patterned over the insulator layer. Then, a heavy inert gas such as Xenon (Xe) is implanted through the openings in the mask, through the insulator layer, and into the regions of the silicon layer that are below the opening in the mask. The portions of the insulator layer that are below the openings in the mask are etched away and the mask is removed. A metal or metal alloy layer is formed over the first layer and the exposed regions of the second layer. At least the second layer is heated in a silicide process such that the metal and the exposed regions of the second layer combine to form silicide regions. After this, any remaining metal material can be removed to remove to leave the silicide regions adjacent non-silicide regions of the second layer.
    • 一种方法在包含硅的第二层上形成第一层。 在绝缘体层上形成并图案化掩模。 然后,将诸如氙(Xe)的重惰性气体通过掩模中的开口通过绝缘体层注入掩模中开口下方的硅层的区域中。 蚀刻绝缘体层中位于掩模中的开口下方的部分,并且去除掩模。 金属或金属合金层形成在第一层和第二层的暴露区域之上。 至少第二层在硅化物工艺中加热,使得金属和第二层的暴露区域结合形成硅化物区域。 此后,可以去除任何剩余的金属材料以除去以留下与第二层的非硅化物区域相邻的硅化物区域。