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    • 2. 发明授权
    • Method and apparatus for in situ anneal during ion implant
    • 离子注入过程中原位退火的方法和装置
    • US6111260A
    • 2000-08-29
    • US872258
    • 1997-06-10
    • Robert DawsonH. Jim Fulford, Jr.Mark I. GardnerFrederick N. HauseMark W. MichaelBradley T. MooreDerick J. Wristers
    • Robert DawsonH. Jim Fulford, Jr.Mark I. GardnerFrederick N. HauseMark W. MichaelBradley T. MooreDerick J. Wristers
    • H01J37/317
    • H01J37/3171H01J2237/316
    • During a semiconductor substrate ion implant process thermal energy is supplied to raise the temperature of the semiconductor wafer. The increased temperature of the semiconductor wafer during implantation acts to anneal the implanted impurities or dopants in the wafer, reducing impurity diffusion and reducing the number of fabrication process steps. An ion implant device includes an end station that is adapted for application and control of thermal energy to the end station for raising the temperature of a semiconductor substrate wafer during implantation. The adapted end station includes a heating element for heating the semiconductor substrate wafer, a thermocouple for sensing the temperature of the semiconductor substrate wafer, and a controller for monitoring the sensed temperature and controlling the thermal energy applied to the semiconductor substrate wafer by the heating element. An ion implant device including a system for applying and controlling thermal energy applied to a semiconductor substrate wafer during ion implantation raises the temperature of the wafer to a temperature that is sufficient to activate impurities within the semiconductor substrate wafer when an ion beam is implanting ions to the wafer, but the temperature is insufficient to activate impurities when the ion beam is inactive.
    • 在半导体衬底离子注入过程中,提供热能以提高半导体晶片的温度。 在注入期间半导体晶片的温度升高期间用于退火晶片中注入的杂质或掺杂剂,减少杂质扩散并减少制造工艺步骤的数量。 离子注入装置包括终端站,其适于向端站施加和控制热能,以在植入期间提高半导体衬底晶片的温度。 适用的端站包括用于加热半导体衬底晶片的加热元件,用于感测半导体衬底晶片的温度的热电偶,以及用于监测感测温度并通过加热元件控制施加到半导体衬底晶片的热能的控制器 。 包括用于在离子注入期间施加和控制施加到半导体衬底晶片的热能的系统的离子注入装置将晶片的温度升高到当离子束注入离子时足以激活半导体衬底晶片内的杂质的温度 晶片,但当离子束无效时,温度不足以激活杂质。
    • 8. 发明授权
    • Composite gate electrode incorporating dopant diffusion-retarding
barrier layer adjacent to underlying gate dielectric
    • 复合栅电极,其与掺杂剂扩散阻滞层结合,邻近底层栅极电介质
    • US5885877A
    • 1999-03-23
    • US837581
    • 1997-04-21
    • Mark I. GardnerRobert DawsonH. Jim Fulford, Jr.Frederick N. HauseDaniel KadoshMark W. MichaelBradley T. MooreDerick J. Wristers
    • Mark I. GardnerRobert DawsonH. Jim Fulford, Jr.Frederick N. HauseDaniel KadoshMark W. MichaelBradley T. MooreDerick J. Wristers
    • H01L21/28H01L29/49H01L21/336H01L21/3205
    • H01L21/28035H01L29/4916
    • A composite gate electrode layer incorporates a diffusion-retarding barrier layer disposed at the bottom of the gate electrode layer to reduce the amount of dopant which diffuses into the gate dielectric layer from the gate electrode layer. A lower nitrogen-containing gate electrode layer provides a diffusion-retarding barrier layer against dopant diffusion into the gate dielectric layer disposed therebelow, and an upper gate electrode layer is formed upon the lower layer and is doped to form a highly conductive layer. Together the first and second gate electrode layers form a composite gate electrode layer which incorporates a diffusion-retarding barrier layer adjacent to the underlying gate dielectric layer. The barrier layer may be formed by annealing a first polysilicon layer in a nitrogen-containing ambient, such as N.sub.2, NO, N.sub.2 O, and NH.sub.3, by implanting a nitrogen-containing material, such as elemental or molecular nitrogen, into a first polysilicon layer, and by in-situ depositing a nitrogen-doped first polysilicon layer. Diffusion of dopants into the gate dielectric layer may be retarded, as most dopant atoms are prevented from diffusing from the composite gate electrode layer at all. In addition, the nitrogen concentration within the gate dielectric layer, particularly at or near the substrate interface, may be maintained at lower concentrations than otherwise necessary to prevent dopant diffusion into the underlying substrate. The present invention is particularly well suited to thin gate dielectrics, such as a those having a thickness less than approximately 60 .ANG. when using a p-type dopant, such as boron.
    • 复合栅极电极层包括设置在栅极电极层底部的扩散阻挡层,以减少从栅极电极层扩散到栅极电介质层中的掺杂剂的量。 下部含氮栅电极层提供阻止扩散阻挡层,以阻止掺杂剂扩散到设置在其下方的栅介质层中,并且在下层上形成上栅极电极层,并且被掺杂以形成高导电层。 第一和第二栅极电极层一起形成复合栅极电极层,该复合栅极电极层包含与下面的栅极电介质层相邻的扩散阻滞阻挡层。 通过将含氮材料(例如元素或分子氮)注入到第一多晶硅层中,可以通过在氮气环境如N 2,NO,N 2 O和NH 3中退火第一多晶硅层来形成阻挡层 ,并通过原位沉积氮掺杂的第一多晶硅层。 完全可以防止掺杂剂扩散到栅极电介质层中,因为大多数掺杂剂原子被阻止从复合栅极电极层扩散。 此外,栅极电介质层内,特别是在衬底界面处或附近的氮浓度可以保持在比防止掺杂剂扩散到下面的衬底中所必需的更低的浓度。 本发明特别适用于薄栅电介质,例如当使用诸如硼的p型掺杂剂时厚度小于约60的薄电介质。
    • 9. 发明授权
    • Photolithographic system including light filter that compensates for lens error
    • 光刻系统包括补偿透镜误差的滤光片
    • US06552776B1
    • 2003-04-22
    • US09183176
    • 1998-10-30
    • Derick J. WristersRobert DawsonH. Jim Fulford, Jr.Mark I. GardnerFrederick N. HauseBradley T. MooreMark W. Michael
    • Derick J. WristersRobert DawsonH. Jim Fulford, Jr.Mark I. GardnerFrederick N. HauseBradley T. MooreMark W. Michael
    • G03B2754
    • G03F7/70558G03F7/70191G03F7/706
    • A photolithographic system including a light filter that varies light intensity according to measured dimensional data that characterizes a lens error is disclosed. The light filter compensates for the lens error by reducing the light intensity of the image pattern as the lens error increases. In this manner, when the lens error causes focusing variations that result in enlarged portions of the image pattern, the light filter reduces the light intensity transmitted to the enlarged portions of the image pattern. This, in turn, reduces the rate in which regions of the photoresist layer beneath the enlarged portions of the image pattern are rendered soluble to a subsequent developer. As a result, after the photoresist layer is developed, linewidth variations that otherwise result from the lens error are reduced due to the light filter. Preferably, the light filter includes a light-absorbing film such as a semi-transparent layer such as calcium fluoride on a light-transmitting base such as a quartz plate, and the thickness of the light-absorbing film varies in accordance with the measured dimensional data to provide the desired variations in light intensity. The invention is particularly well-suited for patterning a photoresist layer that defines polysilicon gates of an integrated circuit device.
    • 公开了一种光刻系统,其包括根据测量的尺寸数据来表征透镜误差来改变光强度的滤光器。 光滤波器通过降低镜头误差增大时图像图案的光强度来补偿镜头误差。 以这种方式,当透镜错误导致导致图像图案的放大部分的聚焦变化时,光过滤器降低传输到图像图案的扩大部分的光强度。 这又降低了图像图案的放大部分之下的光致抗蚀剂层的区域变得可溶于后续显影剂的速率。 结果,在光致抗蚀剂层显影之后,由于滤光器而导致透镜误差导致的线宽变化会降低。 优选地,光滤波器包括诸如石英板等透光基底上的诸如氟化钙的半透明层的光吸收膜,并且光吸收膜的厚度根据测量的尺寸而变化 数据以提供所需的光强度变化。 本发明特别适用于图案化限定集成电路器件的多晶硅栅极的光致抗蚀剂层。
    • 10. 发明授权
    • Method of making NMOS and PMOS devices with reduced masking steps
    • 制造具有减少掩蔽步骤的NMOS和PMOS器件的方法
    • US6060345A
    • 2000-05-09
    • US844924
    • 1997-04-21
    • Frederick N. HauseRobert DawsonH. Jim Fulford, Jr.Mark I. GardnerMark W. MichaelBradley T. MooreDerick J. Wristers
    • Frederick N. HauseRobert DawsonH. Jim Fulford, Jr.Mark I. GardnerMark W. MichaelBradley T. MooreDerick J. Wristers
    • H01L21/8238H01L27/092
    • H01L21/823814
    • A method of making NMOS and PMOS devices with reduced masking steps is disclosed. The method includes providing a semiconductor substrate with a first active region of first conductivity type and a second active region of second conductivity type, forming a gate material over the first and second active regions, forming a first masking layer over the gate material, etching the gate material using the first masking layer as an etch mask to form a first gate over the first active region and a second gate over the second active region, implanting a dopant of second conductivity type into the first and second active regions using the first masking layer as an implant mask, forming a second masking layer that covers the first active region and includes an opening above the second active region, and implanting a dopant of first conductivity type into the second active region using the first and second masking layers as an implant mask. Advantageously, the dopant of first conductivity type counterdopes the dopant of second conductivity type in the second active region, thereby providing source and drain regions of second conductivity type in the first active region and source and drain regions of first conductivity type in the second active region with a single masking step and without subjecting either gate to dopants of first and second conductivity type.
    • 公开了一种制造具有减小的掩蔽步骤的NMOS和PMOS器件的方法。 该方法包括提供具有第一导电类型的第一有源区和第二导电类型的第二有源区的半导体衬底,在第一和第二有源区上形成栅极材料,在栅极材料上形成第一掩模层, 栅极材料,使用第一掩模层作为蚀刻掩模,以在第一有源区上形成第一栅极,在第二有源区上形成第二栅极,使用第一掩模层将第二导电类型的掺杂剂注入到第一和第二有源区中 作为注入掩模,形成覆盖第一有源区并且包括在第二有源区上方的开口的第二掩模层,以及使用第一和第二掩模层作为注入掩模将第一导电类型的掺杂剂注入到第二有源区中 。 有利地,第一导电类型的掺杂剂在第二有源区域中抵消第二导电类型的掺杂剂,从而在第一有源区域中提供第二导电类型的源极和漏极区域,并且在第二有源区域中提供第一导电类型的源极和漏极区域 具有单个掩蔽步骤,并且不对任一个栅极施加第一和第二导电类型的掺杂剂。