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    • 2. 发明授权
    • Apparatus and method for forming a battery in an integrated circuit
    • 用于在集成电路中形成电池的装置和方法
    • US06650000B2
    • 2003-11-18
    • US09761123
    • 2001-01-16
    • Arne W. BallantineRobert A. GrovesJennifer L. LundJames S. NakosMichael B. RiceAnthony K. Stamper
    • Arne W. BallantineRobert A. GrovesJennifer L. LundJames S. NakosMichael B. RiceAnthony K. Stamper
    • H01L2900
    • H01M10/052H01L23/522H01L23/58H01L2924/0002H01M4/5825H01M6/42H01M10/0562H01M10/058H01M10/425H01L2924/00
    • A method and structure that provides a battery within an integrated circuit for providing voltage to low-current electronic devices that exist within the integrated circuit. The method includes Front-End-Of-Line (FEOL) processing for generating a layer of electronic devices on a semiconductor wafer, followed by Back-End-Of-Line (BEOL) integration for wires connecting the electronic devices together to form completed electrical circuits of the integrated circuit. The BEOL integration includes forming a multilayered structure of wiring levels on the layer of electronic devices. Each wiring level includes conductive metallization (e.g., metal-plated vias, conductive wiring lines, etc.) embedded in insulative material. The battery is formed during BEOL integration within one or more wiring levels, and the conductive metallization conductively couples positive and negative terminals of the battery to the electronic devices. The battery may have several different topologies relative to the structural and geometrical relationships among the battery electrodes and electrolyte. Multiple batteries may be formed within one or more wiring levels, and may be conductively coupled to the electronic devices. The multiple batteries may be connected in series or in parallel.
    • 在集成电路内提供电池的方法和结构,用于向存在于集成电路内的低电流电子器件提供电压。 该方法包括用于在半导体晶片上产生电子器件层的前端在线(FEOL)处理,随后是用于将电子器件连接在一起的线的后端(BEOL)集成,以形成完整的电 集成电路的电路。 BEOL集成包括在电子设备层上形成布线层的多层结构。 每个布线层包括嵌入在绝缘材料中的导电金属化(例如,金属镀通孔,导电布线等)。 电池在BEOL集成期间在一个或多个布线层次内形成,并且导电金属化将电池的正端子和负极端子电连接到电子设备。 相对于电池电极和电解质之间的结构和几何关系,电池可能具有几种不同的拓扑结构。 多个电池可以形成在一个或多个布线层中,并且可以导电地耦合到电子设备。 多个电池可以串联或并联连接。
    • 4. 发明授权
    • Increasing an electrical resistance of a resistor by oxidation or nitridization
    • US07351639B2
    • 2008-04-01
    • US10753241
    • 2004-01-08
    • Arne W. BallantineDaniel C. EdelsteinAnthony K. Stamper
    • Arne W. BallantineDaniel C. EdelsteinAnthony K. Stamper
    • H01L21/20
    • C23C8/02C23C8/04C23C8/10C23C8/24C25D11/00C25D11/02C25D11/026H01C7/006H01C17/26H01L21/263H01L27/0802H01L29/8605Y10S257/904Y10S257/914
    • A method and structure for increasing an electrical resistance of a resistor that is within a semiconductor structure, by oxidizing or nitridizing a fraction of a surface layer of the resistor with oxygen/nitrogen (i.e., oxygen or nitrogen) particles, respectively. The semiconductor structure may include a semiconductor wafer, a semiconductor chip, and an integrated circuit. The method and structure comprises five embodiments. The first embodiment comprises heating an interior of a heating chamber that includes the oxygen/nitrogen particles as gaseous oxygen/nitrogen-comprising molecules (e.g., molecular oxygen/nitrogen). The second embodiment comprises heating the fraction of the surface layer by a beam of radiation (e.g., laser radiation), or a beam of particles, such that the semiconductor structure is within a chamber that includes the oxygen/particles as gaseous oxygen/nitrogen-comprising molecules (e.g., molecular oxygen/nitrogen). The third embodiment comprises: using a plasma chamber to generate plasma oxygen/nitrogen ions; and applying a DC voltage to the plasma oxygen/nitrogen ions to accelerate the plasma oxygen/nitrogen ions into the resistor such that the oxygen/nitrogen particles include the plasma oxygen/nitrogen ions. The fourth embodiment comprises using an anodization circuit to electrolytically generate oxygen/nitrogen ions in an electrolytic solution in which the resistor is immersed, wherein the oxygen/nitrogen particles include the electrolytically-generated oxygen/nitrogen ions. The fifth embodiment comprises immersing the semiconductor structure in a chemical solution which includes the oxygen/nitrogen particles, wherein the oxygen/nitrogen particles may include oxygen/nitrogen-comprising liquid molecules, oxygen/nitrogen ions, or an oxygen/nitrogen-comprising gas dissolved in the chemical solution under pressurization.
    • 6. 发明授权
    • Increasing an electrical resistance of a resistor by oxidation or nitridization
    • US06730984B1
    • 2004-05-04
    • US09712391
    • 2000-11-14
    • Arne W. BallantineDaniel C. EdelsteinAnthony K. Stamper
    • Arne W. BallantineDaniel C. EdelsteinAnthony K. Stamper
    • H01L2900
    • C23C8/02C23C8/04C23C8/10C23C8/24C25D11/00C25D11/02C25D11/026H01C7/006H01C17/26H01L21/263H01L27/0802H01L29/8605Y10S257/904Y10S257/914
    • A method and structure for increasing an electrical resistance of a resistor that is within a semiconductor structure, by oxidizing or nitridizing a fraction of a surface layer of the resistor with oxygen/nitrogen (i.e., oxygen or nitrogen) particles, respectively. The semiconductor structure may include a semiconductor wafer, a semiconductor chip, and an integrated circuit. The method and structure comprises five embodiments. The first embodiment comprises heating an interior of a heating chamber that includes the oxygen/nitrogen particles as gaseous oxygen/nitrogen-comprising molecules (e.g., molecular oxygen/nitrogen). The second embodiment comprises heating the fraction of the surface layer by a beam of radiation (e.g., laser radiation), or a beam of particles, such that the semiconductor structure is within a chamber that includes the oxygen/particles as gaseous oxygen/nitrogen-comprising molecules (e.g., molecular oxygen/nitrogen). The third embodiment comprises: using a plasma chamber to generate plasma oxygen/nitrogen ions; and applying a DC voltage to the plasma oxygen/nitrogen ions to accelerate the plasma oxygen/nitrogen ions into the resistor such that the oxygen/nitrogen particles include the plasma oxygen/nitrogen ions. The fourth embodiment comprises using an anodization circuit to electrolytically generate oxygen/nitrogen ions in an electrolytic solution in which the resistor is immersed, wherein the oxygen/nitrogen particles include the electrolytically-generated oxygen/nitrogen ions. The fifth embodiment comprises immersing the semiconductor structure in a chemical solution which includes the oxygen/nitrogen particles, wherein the oxygen/nitrogen particles may include oxygen/nitrogen-comprising liquid molecules, oxygen/nitrogen ions, or an oxygen/nitrogen-comprising gas dissolved in the chemical solution under pressurization.