公开(公告)号：EP1790003A4

公开(公告)日：2011-01-12

申请号：EP05784302

申请日：2005-08-04

Applicant: IBM

Inventor： BEDELL STEPHEN W ,  CHEN HUAJIE ,  FOGEL KEITH ,  MITCHELL RYAN M ,  SADANA DEVENDRA K

IPC: H01L21/36 ,  H01L21/02 ,  H01L21/20 ,  H01L31/117

CPC classification number: H01L29/1054 ,  H01L21/02381 ,  H01L21/0245 ,  H01L21/02507 ,  H01L21/02532

公开(公告)号：WO2006017640B1

公开(公告)日：2006-04-27

申请号：PCT/US2005027691

申请日：2005-08-04

Applicant: IBM ,  BEDELL STEPHEN W ,  CHEN HUAJIE ,  FOGEL KEITH ,  MITCHELL RYAN M ,  SADANA DEVENDRA K

Inventor： BEDELL STEPHEN W ,  CHEN HUAJIE ,  FOGEL KEITH ,  MITCHELL RYAN M ,  SADANA DEVENDRA K

IPC: H01L21/36 ,  H01L21/20 ,  H01L31/117

CPC classification number: H01L29/1054 ,  H01L21/02381 ,  H01L21/0245 ,  H01L21/02507 ,  H01L21/02532

Abstract: A method is disclosed for forming a strained Si layer on SiGe, where the SiGe layer has improved thermal conductivity. A first layer (41) of Si or Ge is deposited on a substrate (10) in a first depositing step; a second layer (42) of the other element is deposited on the first layer in a second depositing step; and the first and second depositing steps are repeated so as to form a combined SiGe layer (50) having a plurality of Si layers and a plurality of Ge layers (41-44). The respective thicknesses of the Si layers and Ge layers are in accordance with a desired composition ratio of the combined SiGe layer. The combined SiGe layer (50) is characterized as a digital alloy of Si and Ge having a thermal conductivity greater than that of a random alloy of Si and Ge. This method may further include the step of depositing a Si layer (61) on the combined SiGe layer (50); the combined SiGe layer is characterized as a relaxed SiGe layer, and the Si layer (61) is a strained Si layer. For still greater thermal conductivity in the SiGe layer, the first layer and second layer may be deposited so that each layer consists essentially of a single isotope.

Abstract translation: 公开了一种在SiGe上形成应变Si层的方法，其中SiGe层具有改善的导热性。 在第一沉积步骤中，在衬底（10）上沉积Si或Ge的第一层（41） 在第二沉积步骤中将另一元素的第二层（42）沉积在第一层上; 并重复第一沉积步骤和第二沉积步骤以形成具有多个Si层和多个Ge层（41-44）的组合SiGe层（50）。 Si层和Ge层的各自厚度符合组合SiGe层的所需组成比。 组合的SiGe层（50）的特征在于Si和Ge的数字合金，其导热率大于Si和Ge的无规合金的导热率。 该方法可以进一步包括在组合的SiGe层（50）上沉积Si层（61）的步骤; 组合的SiGe层的特征在于弛豫SiGe层，并且Si层（61）是应变Si层。 为了在SiGe层中具有更大的导热性，可以沉积第一层和第二层，使得每个层基本上由单一的同位素组成。

公开(公告)号：WO2005034209A3

公开(公告)日：2005-05-19

申请号：PCT/US2004031823

申请日：2004-09-28

Applicant: IBM ,  CHOE KWANG SU ,  FOGEL KEITH E ,  MAURER SIEGFRIED L ,  MITCHELL RYAN M ,  SADANA DEVENDRA K

Inventor： CHOE KWANG SU ,  FOGEL KEITH E ,  MAURER SIEGFRIED L ,  MITCHELL RYAN M ,  SADANA DEVENDRA K

IPC: H01L21/265 ,  H01L21/3063 ,  H01L21/316 ,  H01L21/762 ,  H01L21/20

CPC classification number: H01L21/76243 ,  H01L21/26533 ,  H01L21/3063 ,  H01L21/31662

Abstract: A method of fabricating silicon-on-insulators (SOIs) having a thin, but uniform buried oxide region beneath a Si-containing over-layer is provided. The SOI structures are fabricated by first modifying a surface of a Si-containing substrate to contain a large concentration of vacancies or voids. Next, a Si-containing layer is typically, but not always, formed atop the substrate and then oxygen ions are implanted into the structure utilizing a low-oxygen dose. The structure is then annealed to convert the implanted oxygen ions into a thin, but uniform thermal buried oxide region.

Abstract translation: 提供了一种制造在含Si的上层下方具有薄但均匀的掩埋氧化物区域的硅绝缘体（SOI）的方法。 通过首先修饰含Si衬底的表面以包含大量的空位或空隙的浓度来制造SOI结构。 接下来，含硅层通常但不总是形成在衬底顶上，然后使用低氧剂量将氧离子注入到结构中。 然后将结构退火以将注入的氧离子转化成薄但均匀的热掩埋氧化物区域。