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    • 1. 发明授权
    • Method for forming polysilicon gate
    • 多晶硅栅极形成方法
    • US6069061A
    • 2000-05-30
    • US245648
    • 1999-02-08
    • Tony LinWater Lur
    • Tony LinWater Lur
    • H01L21/28H01L21/336H01L29/49
    • H01L29/4933H01L21/28052H01L29/6659
    • A method is provided for forming a polysilicon gate. A stacked gate with a first polysilicon layer/an oxide layer/a second polysilicon layer multiple structure is formed. The invention provides another method for forming a polysilicon gate, in which a first polysilicon layer is formed and waits for a period of time. Then, a second polysilicon layer is formed on the first polysilicon layer. A grain boundary is formed between the first polysilicon layer and the second polysilicon layer. The invention provides still another method for forming a polysilicon gate, in which a polysilicon layer is formed at the temperature of about 600-700.degree. C. and the pressure of about 1-5 torr to form a small-grained polysilicon layer. The three methods for forming a polysilicon gate can prevent the heavy ions from passing through the polysilicon gate and the gate oxide layer into the substrate while performing a pre-amorphization implant process. The absence of these heavy ions in the substrate avoids the subthreshold kink side-effect.
    • 提供了形成多晶硅栅极的方法。 形成具有第一多晶硅层/氧化物层/第二多晶硅层多重结构的堆叠栅极。 本发明提供了形成多晶硅栅极的另一种方法,其中形成第一多晶硅层并等待一段时间。 然后,在第一多晶硅层上形成第二多晶硅层。 在第一多晶硅层和第二多晶硅层之间形成晶界。 本发明提供另一种形成多晶硅栅极的方法,其中在约600-700℃的温度和约1-5托的压力下形成多晶硅层以形成小粒度多晶硅层。 用于形成多晶硅栅极的三种方法可以防止重离子在进行预非晶化注入工艺时通过多晶硅栅极和栅极氧化物层进入衬底。 衬底中没有这些重离子避免了亚阈值扭结副作用。
    • 2. 发明授权
    • Method of forming a self-aligned silicide device
    • 形成自对准硅化物器件的方法
    • US5874353A
    • 1999-02-23
    • US927321
    • 1997-09-11
    • Tony LinWater LurShih-Wei Sun
    • Tony LinWater LurShih-Wei Sun
    • H01L21/28H01L21/336H01L29/49H01L21/3205H01L21/4763
    • H01L29/665H01L21/28052H01L21/28061H01L29/4925H01L29/4941
    • A method of forming self-aligned silicide devices which includes providing a silicon substrate having shallow trench isolation regions for defining a device area formed therein; then, forming sequentially a gate oxide layer, a polysilicon layer, a first titanium nitride layer, a titanium silicide layer, a second titanium nitride layer and a silicon nitride layer over the substrate. After a gate electrode is etched out from the above layers, a titanium layer is deposited over the device, and then a self-aligned titanium silicide layer is formed using a heating process. The use of a titanium silicide layer having protective top and bottom titanium nitride layers, compared with a single tungsten silicide layer in a conventional method, provides for a self-aligned silicide device having a rather low gate resistance; being free from narrow width effect of a titanium self-aligned silicide layer; is applicable to self-aligned contact window processes, and avoids the cross-diffusion of doped ions in the polysilicon layer of a dual gate electrode having a tungsten polycide layer.
    • 一种形成自对准硅化物器件的方法,其包括提供具有浅沟槽隔离区域的硅衬底,用于限定其中形成的器件区域; 然后在衬底上依次形成栅氧化层,多晶硅层,第一氮化钛层,硅化钛层,第二氮化钛层和氮化硅层。 在从上述层蚀刻出栅电极之后,在器件上沉积钛层,然后使用加热工艺形成自对准硅化钛层。 与常规方法中的单个硅化钨层相比,使用具有保护性顶部和底部氮化钛层的硅化钛层提供具有相当低的栅极电阻的自对准硅化物器件; 没有钛自对准硅化物层的窄宽度效应; 适用于自对准接触窗工艺,并避免掺杂离子在具有钨多硅化物层的双栅电极的多晶硅层中的交叉扩散。
    • 3. 发明授权
    • Method of fabricating semiconductor devices with self-aligned silicide
    • 制造具有自对准硅化物的半导体器件的方法
    • US6025241A
    • 2000-02-15
    • US73576
    • 1998-05-06
    • Tony LinWater Lur
    • Tony LinWater Lur
    • H01L21/3115H01L21/336H01L21/28
    • H01L29/66507H01L29/6659H01L21/31155Y10S148/147
    • A method for fabricating a semiconductor device, such as a MOS (metal-oxide semiconductor) transistor, with self-aligned silicide is provided. This method can prevent junction leakage between the silicide and the substrate so as to allow the resultant semiconductor device to have reliable performance. The method includes the steps of preparing a semiconductor substrate; forming at least one transistor element over the substrate, the transistor element including a pair of source/drain regions, a gate, a dielectric layer over the gate, and a spacer on the sidewall of the gate; and performing an ion-bombardment process so as to transport one part of the dielectric layer that is adjacent to the top of the spacer to beside the bottom of the spacer. Through this method, the resultant semiconductor device is reliable in operation since the drawback of the occurrence of leakage current or short-circuit that could be otherwise resulted between the self-aligned silicide and the substrate owing to the short-channel effect can be eliminated. Moreover, the resultant semiconductor device has increased anti-static capability that can protect the semiconductor device against electro-static damage.
    • 提供了一种用于制造具有自对准硅化物的半导体器件(例如MOS(金属氧化物半导体)晶体管)的方法。 该方法可以防止硅化物与衬底之间的结漏电,从而使所得的半导体器件具有可靠的性能。 该方法包括制备半导体衬底的步骤; 在所述衬底上形成至少一个晶体管元件,所述晶体管元件包括一对源极/漏极区域,栅极,所述栅极上的电介质层以及所述栅极侧壁上的间隔物; 并且进行离子轰击处理,以将邻近间隔物顶部的电介质层的一部分输送到间隔物的底部旁边。 通过该方法,由于短沟道效应,可以消除由于短路导致的自对准硅化物和衬底之间的漏电流或短路的缺点,所以得到的半导体器件工作可靠。 此外,所得到的半导体器件具有增强的抗静电能力,可以保护半导体器件免受静电损坏。
    • 5. 发明授权
    • Method of forming salicide
    • 形成自杀剂的方法
    • US6001738A
    • 1999-12-14
    • US62115
    • 1998-04-17
    • Tony LinWater LurShih-Wei Sun
    • Tony LinWater LurShih-Wei Sun
    • H01L21/336H01L21/283
    • H01L29/6659H01L29/665
    • A method of forming salicide, of which the characteristics is the formation of a silicon nitride layer before the source/drain being implanted with dopant. The silicon nitride layer avoid the oxygen within the oxide layer to implant into the source/drain. Thus, a better salicide is obtained. In addition, the formation of the parasitic spacers made of silicon nitride at the side wall bottom of the gate spacer increases the distance between the salicide and the junction. Consequently, the leakage current is prevented. While the silicon nitride layer is removed, the polysilicon of gate and the silicon of the source/drain are amorphized. This is advantageous to the formation of salicide without the step of ion implantation.
    • 一种形成硅化物的方法,其特征是在掺杂有掺杂剂的源极/漏极之前形成氮化硅层。 氮化硅层避免氧化物层内的氧气注入到源极/漏极中。 因此,获得更好的自杀剂。 此外,在栅极间隔物的侧壁底部由氮化硅制成的寄生间隔物的形成增加了自对准硅化物与接合部之间的距离。 因此,防止漏电流。 当去除氮化硅层时,栅极和源极/漏极的硅的多晶硅是非晶化的。 这对于没有离子注入步骤的硅化物的形成是有利的。
    • 6. 发明授权
    • Method for forming self-aligned silicide layers on sub-quarter micron
VLSI circuits
    • 在二分之一微米VLSI电路上形成自对准硅化物层的方法
    • US6100191A
    • 2000-08-08
    • US59687
    • 1998-04-14
    • Tony LinWater LurJiun-Yuan WuHsiao-Lin Lu
    • Tony LinWater LurJiun-Yuan WuHsiao-Lin Lu
    • H01L21/285H01L21/44
    • H01L21/28518H01L21/2855
    • The present invention discloses a method to manufacture a self-aligned silicide layer on a substrate. A metal oxide semiconductor (MOS) device and a shallow trench are fabricated in the substrate. The device has a gate structure, spacers of the gate structured and doping regions. The shallow trench is refilled with silicon oxide material for isolation. A silicon layer is nonconformally deposited on the top surface of the gate structure, the spacers and the doping regions by using a physical vapor deposition (PVD) process, such as ion metal plasma (IMP) process. The IMP process, like a sputtering process, is to ionize a silicon material or a refractory-metal material to silicon ions or metal ions and the ions are biased to anisotropically deposit on the top surface of the substrate. A refractory metal layer is defined on the top surface of the silicon layer by the IMP technology. A two-step thermal annealing process, such as rapid thermal annealing (RTA) process is performed to convert the silicon layer and the refractory metal layer into a silicide layer. Since the silicon layer serves as a silicon source for the salicide process, the silicide layer can form on the spacers and the silicon oxide material of the trench.
    • 本发明公开了一种在衬底上制造自对准硅化物层的方法。 在衬底中制造金属氧化物半导体(MOS)器件和浅沟槽。 器件具有栅极结构,栅极结构和掺杂区域的间隔物。 浅沟槽用氧化硅材料再填充以进行隔离。 通过使用诸如离子金属等离子体(IMP)工艺的物理气相沉积(PVD)工艺,硅层不均匀地沉积在栅极结构,间隔物和掺杂区域的顶表面上。 IMP工艺,如溅射工艺,是将硅材料或难熔金属材料离子化成硅离子或金属离子,并将离子偏置成各向异性沉积在衬底的顶表面上。 难熔金属层通过IMP技术限定在硅层的顶表面上。 进行两步热退火处理,例如快速热退火(RTA)工艺,以将硅层和难熔金属层转化为硅化物层。 由于硅层用作自对准硅化物工艺的硅源,硅化物层可以形成在间隔物和沟槽的氧化硅材料上。
    • 7. 发明授权
    • Method of fabricating a salicide layer of a device electrode
    • 制造器件电极的自对准硅化物层的方法
    • US5981383A
    • 1999-11-09
    • US814376
    • 1997-03-11
    • Water LurTony Lin
    • Water LurTony Lin
    • H01L21/28H01L21/285H01L21/3205H01L21/336H01L29/423H01L21/70
    • H01L29/6659H01L21/28052H01L21/28114H01L21/28518H01L21/3205H01L21/32053H01L29/665H01L29/42376
    • Salicide (self-aligned silicide) structures are formed using a process that does not form oxide spacer structures alongside polysilicon gate electrodes and wiring lines. A shaped polysilicon electrode is formed having protrusions extending beyond the sidewalls of the electrode. LDD source/drain regions are formed by ion implantation using only the polysilicon gate electrode as a mask, thereby forming LDD source drain/regions without using spacer oxide regions. Physical vapor deposition is used to deposit a metal layer having discontinuities at or adjacent the protrusions. A first rapid thermal anneal is performed to cause the metal to form a metal silicide over the polysilicon electrode. Unreacted metal is etched and then a second rapid thermal anneal is performed to convert the metal silicide to its lowest resistivity phase. Gate electrodes and wiring lines having this structure generally are formed having lower stress in the silicide layers, producing salicide structures having lower resistance than gate electrodes and wiring lines formed using conventional salicide techniques.
    • 使用不与多晶硅栅电极和布线一起形成氧化物间隔结构的工艺来形成硅化物(自对准硅化物)结构。 形成具有延伸超过电极侧壁的突起的成形多晶硅电极。 通过仅使用多晶硅栅极作为掩模的离子注入形成LDD源极/漏极区域,从而在不使用间隔氧化物区域的情况下形成LDD源极漏极/区域。 物理气相沉积用于沉积在突起处或邻近突起处具有不连续性的金属层。 进行第一快速热退火以使金属在多晶硅电极上形成金属硅化物。 蚀刻未反应的金属,然后进行第二次快速热退火,以将金属硅化物转化为最低电阻率相。 具有这种结构的栅极电极和布线通常形成为在硅化物层中具有较低的应力,产生具有比栅电极低的电阻和使用常规自对准硅化物技术形成的布线的硅化物结构。
    • 8. 发明授权
    • Method of making a self-aligned silicide
    • 制造自对准硅化物的方法
    • US5913124A
    • 1999-06-15
    • US883332
    • 1997-06-26
    • Tony LinWater Lur
    • Tony LinWater Lur
    • H01L21/28H01L21/265H01L21/336H01L21/8234H01L29/78
    • H01L29/6659H01L21/823418H01L21/823443H01L29/665H01L21/26586
    • A method of making a self-aligned silicide which has an impurity diffusion region in a lower part of the source/drain regions adjacent to the isolating region. The method includes performing an ion implantation operation at a large tilt angle, which increases the junction depth of the source/drain regions and prevents the metallic silicide lying at the edge of the isolating region from getting too close to the source/drain junction and causing unwanted current leakages. The isolating regions are overetched, which exposes the surface of the source/drain regions. The metal silicide layer can thus be formed over the exposed source/drain surfaces, resulting in more surface area for the formation of a wide border contact window, resulting in a lowering of both contact resistance and sheet resistance there.
    • 一种制造自对准硅化物的方法,该硅化物在与隔离区相邻的源/漏区的下部具有杂质扩散区。 该方法包括以大的倾斜角执行离子注入操作,这增加了源极/漏极区的结深度,并且防止位于隔离区边缘处的金属硅化物太靠近源极/漏极结并导致 不必要的电流泄漏。 隔离区域被过蚀刻,其暴露源极/漏极区域的表面。 因此,可以在暴露的源极/漏极表面上形成金属硅化物层,导致形成宽边界接触窗的更多的表面积,从而导致接触电阻和薄层电阻的降低。
    • 10. 发明授权
    • One step salicide process without bridging
    • 一步一步的自杀过程没有桥接
    • US6013569A
    • 2000-01-11
    • US888752
    • 1997-07-07
    • Water LurTony Lin
    • Water LurTony Lin
    • H01L21/28H01L21/336H01L21/335H01L21/76H01L21/762
    • H01L29/6659H01L21/28247H01L29/665H01L29/6656H01L29/66545
    • Silicidation of a polysilicon line having frcc upper sidewalls is performed so that no stress is applied to the sidewalls of the polysilicon line, resulting in the formation of a reduced stress silicide structure. This is accomplished by forming a polysilicon line having spacers on either side which extend above the upper surface of the polysilicon line but which are spaced from the edge of the polysilicon line. A layer of a metal such as titanium or tungsten is provided in contact with the top surface polysilicon line. The structure is annealed to cause the metal to react with the polysilicon to form a layer of silicide. Since the upper side portions of the polysilicon line are spaced away from the spacers during the silicidation anneal, the growing silicide region has room to expand without being subjected to lateral stresses in the silicidation process. The suicide is formed in a reduced stress condition, as compared to conventional processes, so that the silicide layer produced will be more readily converted to the desired low resistivity phase of silicide.
    • 执行具有frcc上侧壁的多晶硅线的硅化,使得没有应力施加到多晶硅线的侧壁,导致形成应力减小的硅化物结构。 这是通过在多晶硅线的上表面上方延伸但与多晶硅线的边缘间隔开的任一侧上形成具有间隔物的多晶硅线来实现的。 提供与顶表面多晶硅线接触的诸如钛或钨的金属层。 将该结构退火以使金属与多晶硅反应形成一层硅化物。 由于在硅化退火期间多晶硅线的上侧部分与间隔物间隔开,所以生长的硅化物区域具有膨胀的空间,而不会在硅化过程中受到横向应力。 与常规方法相比,自杀在降低的应力条件下形成,使得所生成的硅化物层将更容易地转化为期望的硅化物的低电阻率相。