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    • 3. 发明授权
    • Prevention of post CMP defects in CU/FSG process
    • 预防CU / FSG过程中的后CMP缺陷
    • US07091600B2
    • 2006-08-15
    • US10791014
    • 2004-03-02
    • Chung-Shi LiuShau-Lin Shue
    • Chung-Shi LiuShau-Lin Shue
    • H01L23/48
    • H01L21/76829H01L21/76807H01L21/76832H01L21/7684H01L21/76877
    • A common problem associated with damascene structures made of copper inlaid in FSG (fluorinated silicate glass) is the formation of defects near the top surface of the structure. The present invention avoids this problem by laying down a layer of USG (undoped silicate glass) over the surface of the FSG layer prior to patterning and etching the latter to form the via hole and (for a dual damascene structure) the trench. After over-filling with copper, the structure is planarized using CMP. The USG layer acts both to prevent any fluorine from the FSG layer from reaching the copper and as an end-point detector during CMP. In this way defects that result from copper-fluorine interaction do not form and precise planarization is achieved.
    • 与镶嵌在FSG(氟化硅酸盐玻璃)中的铜构成的镶嵌结构相关的常见问题是在结构顶表面附近形成缺陷。 本发明通过在图案化之前放置一层USG(未掺杂的硅酸盐玻璃)以避免这种问题,然后在图案化之前对其进行蚀刻,以形成通孔和(用于双镶嵌结构)沟槽。 用铜填充后,使用CMP对结构进行平面化处理。 USG层既可以防止FSG层中的任何氟达到铜,也可以作为CMP中的终点检测器。 以这种方式,铜 - 氟相互作用产生的缺陷不能形成并且实现精确的平坦化。
    • 4. 发明授权
    • Stress management of barrier metal for resolving CU line corrosion
    • 用于解决CU线腐蚀的隔离金属的应力管理
    • US06297158B1
    • 2001-10-02
    • US09583402
    • 2000-05-31
    • Chung-Shi LiuShau-Lin ShueChen-Hua Yu
    • Chung-Shi LiuShau-Lin ShueChen-Hua Yu
    • H01L214763
    • H01L21/76873H01L21/76843H01L21/76864
    • In the presently disclosed invention, a method is provided to avoid damage to a copper interconnect while subjecting the interconnect to chemical-mechanical polishing (CMP). First, a copper barrier layer is formed in a damascene structure. Then, prior to the deposition of copper metal into the damascene openings, a barrier layer is formed on the inside walls of the damascene structure. In a first embodiment, the copper barrier layer is deposited at high temperature. Then, it is cooled down in a prescribed manner. Subsequently, a copper seed layer is formed over the barrier, which is followed by the electro-chemical deposition (ECD) of copper, to form the copper damascene interconnect. Alternatively, in a second embodiment, the copper layer is formed at low temperature. Then it is annealed at a high temperature, followed by wafer cooling. Subsequently, copper seed layer is formed over the barrier layer. Next, ECD copper is formed in the damascene structure. Finally, the interconnect so formed by either of the embodiments is subjected to CMP. It is found that, through the disclosed method of treatment of the barrier layer, process stresses that are normally formed within the barrier layer are relieved, and hence no damage is incurred during the final steps of chemical-mechanical polishing.
    • 在本公开的发明中,提供了一种方法,以避免对互连线进行化学机械抛光(CMP)的铜互连的损坏。 首先,在大马士革结构中形成铜阻挡层。 然后,在将铜金属沉积到镶嵌开口之前,在镶嵌结构的内壁上形成阻挡层。 在第一实施例中,铜阻挡层在高温下沉积。 然后,以规定的方式冷却。 随后,在屏障上形成铜籽晶层,随后是铜的电化学沉积(ECD),以形成铜镶嵌互连。 或者,在第二实施例中,铜层在低温下形成。 然后在高温下进行退火,然后进行晶片冷却。 随后,在阻挡层上形成铜籽晶层。 接下来,在镶嵌结构中形成ECD铜。 最后,将由这两个实施例形成的互连件进行CMP处理。 发现通过公开的阻挡层处理方法,通常在阻挡层内形成的工艺应力被释放,因此在化学机械抛光的最终步骤期间不会产生损伤。
    • 7. 发明申请
    • PREVENTION OF POST CMP DEFECTS IN CU/FSG PROCESS
    • 防止CU / FSG过程中的CMP缺陷
    • US20060292860A1
    • 2006-12-28
    • US11463515
    • 2006-08-09
    • Chung-Shi LiuShau-Lin Shue
    • Chung-Shi LiuShau-Lin Shue
    • H01L21/4763
    • H01L21/76829H01L21/76807H01L21/76832H01L21/7684H01L21/76877
    • A common problem associated with damascene structures made of copper inlaid in FSG (fluorinated silicate glass) is the formation of defects near the top surface of the structure. The present invention avoids this problem by laying down a layer of USG (undoped silicate glass) over the surface of the FSG layer prior to patterning and etching the latter to form the via hole and (for a dual damascene structure) the trench. After over-filling with copper, the structure is planarized using CMP. The USG layer acts both to prevent any fluorine from the FSG layer from reaching the copper and as an end-point detector during CMP. In this way defects that result from copper-fluorine interaction do not form and precise planarization is achieved.
    • 与镶嵌在FSG(氟化硅酸盐玻璃)中的铜构成的镶嵌结构相关的常见问题是在结构顶表面附近形成缺陷。 本发明通过在图案化之前放置一层USG(未掺杂的硅酸盐玻璃)以避免这种问题,然后在图案化之前对其进行蚀刻,以形成通孔和(用于双镶嵌结构)沟槽。 用铜填充后,使用CMP对结构进行平面化处理。 USG层既可以防止FSG层中的任何氟达到铜,也可以作为CMP中的终点检测器。 以这种方式,铜 - 氟相互作用产生的缺陷不能形成并且实现精确的平坦化。
    • 8. 发明授权
    • Prevention of post CMP defects in Cu/FSG process
    • 预防Cu / FSG工艺中的后CMP缺陷
    • US06723639B1
    • 2004-04-20
    • US09863223
    • 2001-05-24
    • Chung-Shi LiuShau-Lin Shue
    • Chung-Shi LiuShau-Lin Shue
    • H01L2144
    • H01L21/76829H01L21/76807H01L21/76832H01L21/7684H01L21/76877
    • A common problem associated with damascene structures made of copper inlaid in FSG (flourinated silicate glass) is the formation of defects near the top surface of the structure. The present invention avoids this problem by laying down a layer of USG (undoped silicate glass) over the surface of the FSG layer prior to patterning and etching the latter to form the via hole and (for a dual damascene structure) the trench. After over-filling with copper, the structure is planarized using CMP. The USG layer acts both to prevent any flourine from the FSG layer from reaching the copper and as an end-point detector during CMP. In this way defects that result from copper-fluorine interaction do not form and precise planarization is achieved.
    • 与镶嵌在FSG(含氟硅酸盐玻璃)中的铜制成的镶嵌结构相关的常见问题是在结构顶表面附近形成缺陷。 本发明通过在图案化之前放置一层USG(未掺杂的硅酸盐玻璃)以避免这种问题,然后在图案化之前对其进行蚀刻,以形成通孔和(用于双镶嵌结构)沟槽。 用铜填充后,使用CMP对结构进行平面化处理。 USG层既可以防止FSG层的任何粉末到达铜,也可以作为CMP中的终点检测器。 以这种方式,铜 - 氟相互作用产生的缺陷不能形成并且实现精确的平坦化。
    • 9. 发明授权
    • Effective diffusion barrier
    • 有效的扩散屏障
    • US06353260B2
    • 2002-03-05
    • US09785106
    • 2001-02-20
    • Chung-Shi LiuShau-Lin ShueChen-Hua Yu
    • Chung-Shi LiuShau-Lin ShueChen-Hua Yu
    • H01L2348
    • H01L21/76856H01L21/76805H01L21/76843
    • In forming a semiconductor device in which an electrically conductive substrate is covered with a dielectric layer by the following steps, form a trench with a trench line on top and a contact hole on the bottom in the dielectric layer with the overall trench reaching down to the substrate. Preclean the trench. Form a tantalum film over the dielectric layer including the trench walls, covering the exposed the substrate surface. Fill grain boundaries of the tantalum film with at least one of tantalum oxide and tantalum nitride forming a filled tantalum film. Form a redeposited tantalum layer above the filled tantalum film. Form a copper seed film above the redeposited tantalum film. Plate the device filling the trench with a plated bulk copper layer on the seed film. Planarize the device to expose the top surface of the dielectric layer, removing surplus portions of the filled tantalum film, the copper seed film, and the bulk copper layer. The filled tantalum film is formed by exposing the tantalum to air under STP atmospheric conditions or by exposure to a nitrous oxide (N2O) gas in a plasma at a temperature of about 400° C.
    • 在通过以下步骤形成其中导电基板被电介质层覆盖的半导体器件中,在电介质层的顶部形成有沟槽线的沟槽和底部的接触孔,其中整个沟槽到达 基质。 清洁沟槽。 在包括沟槽壁的电介质层上形成钽膜,覆盖暴露的衬底表面。 用钽氧化物和氮化钽中的至少一种填充钽膜的晶界,形成填充的钽膜。 在填充的钽膜上方形成再沉积的钽层。 在再沉积的钽膜上方形成铜籽晶膜。 将装有填充沟槽的装置用种子膜上的电镀体铜层铺平。 平面化器件以暴露电介质层的顶表面,去除填充的钽膜,铜籽晶膜和块状铜层的剩余部分。 填充的钽膜通过在STP大气条件下暴露于空气或通过在约400℃的温度下暴露于等离子体中的一氧化二氮(N 2 O)气体而形成。