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    • 2. 发明授权
    • Dry etch release of MEMS structures
    • MEMS结构的干蚀刻释放
    • US06666979B2
    • 2003-12-23
    • US10046593
    • 2001-10-29
    • Jeffrey D. ChinnVidyut GopalSofiane SoukaneToi Yue Becky Leung
    • Jeffrey D. ChinnVidyut GopalSofiane SoukaneToi Yue Becky Leung
    • H01L2100
    • B81B3/0005B81B3/0008B81B2201/033B81C2201/016B81C2201/112
    • The present invention pertains to a method of fabricating a surface within a MEM which is free moving in response to stimulation. The free moving surface is fabricated in a series of steps which includes a release method, where release is accomplished by a plasmaless etching of a sacrificial layer material. An etch step is followed by a cleaning step in which by-products from the etch step are removed along with other contaminants which may lead to stiction. There are a series of etch and then clean steps so that a number of “cycles” of these steps are performed. Between each etch step and each clean step, the process chamber pressure is typically abruptly lowered, to create turbulence and aid in the removal of particulates which are evacuated from the structure surface and the process chamber by the pumping action during lowering of the chamber pressure. The final etch/clean cycle may be followed by a surface passivation step in which cleaned surfaces are passivated and/or coated.
    • 本发明涉及制造响应于刺激而自由移动的MEM内的表面的方法。 自由移动表面是在一系列步骤中制造的,其包括释放方法,其中通过牺牲层材料的无质子蚀刻来实现释放。 蚀刻步骤之后是清洁步骤,其中来自蚀刻步骤的副产物与可能导致静电的其它污染物一起被去除。 存在一系列蚀刻然后清洁步骤,使得执行这些步骤的许多“循环”。 在每个蚀刻步骤和每个清洁步骤之间,处理室压力通常突然降低,以产生湍流,并且有助于通过在降低腔室压力期间的泵送作用从结构表面和处理室排出的微粒去除。 最终的蚀刻/清洁循环之后可以是表面钝化步骤,其中清洁的表面被钝化和/或涂覆。
    • 4. 发明授权
    • Controlled deposition of silicon-containing coatings adhered by an oxide layer
    • 由氧化物层附着的含硅涂层的控制沉积
    • US07638167B2
    • 2009-12-29
    • US10862047
    • 2004-06-04
    • Boris KobrinRomuald NowakRichard C. YiJeffrey D. Chinn
    • Boris KobrinRomuald NowakRichard C. YiJeffrey D. Chinn
    • C23C16/00C23C14/10
    • B82Y30/00C23C16/0227C23C16/402
    • We have developed an improved vapor-phase deposition method and apparatus for the application of films/coatings on substrates. The method provides for the addition of a precise amount of each of the reactants to be consumed in a single reaction step of the coating formation process. In addition to the control over the amount of reactants added to the process chamber, the present invention requires precise control over the total pressure (which is less than atmospheric pressure) in the process chamber, the partial vapor pressure of each vaporous component present in the process chamber, the substrate temperature, and typically the temperature of a major processing surface within said process chamber. Control over this combination of variables determines a number of the characteristics of a film/coating or multi-layered film/coating formed using the method. By varying these process parameters, the roughness and the thickness of the films/coatings produced can be controlled.
    • 我们已经开发了一种改进的气相沉积方法和装置,用于在基底上施加膜/涂层。 该方法提供在涂层形成过程的单个反应步骤中添加精确量的每种待消耗的反应物。 除了控制添加到处理室中的反应物的量之外,本发明需要精确控制处理室中的总压力(其小于大气压),存在于处理室中的每种气态组分的部分蒸气压 处理室,衬底温度以及典型地在所述处理室内的主处理表面的温度。 对这种变量组合的控制决定了使用该方法形成的膜/涂层或多层膜/涂层的许多特性。 通过改变这些工艺参数,可以控制所生产的膜/涂层的粗糙度和厚度。
    • 7. 发明授权
    • Method for rounding corners and removing damaged outer surfaces of a trench
    • 用于对角落进行倒角并去除损坏的沟槽外表面的方法
    • US06599842B2
    • 2003-07-29
    • US09450475
    • 1999-11-29
    • John ChaoMohit JainJeffrey D. Chinn
    • John ChaoMohit JainJeffrey D. Chinn
    • H01L21302
    • H01L21/67069H01L21/3065
    • A method for processing a substrate disposed in a substrate processing chamber to modify the contour of a trench formed on the substrate. The substrate processing chamber is the type that has a coil and a plasma generation system including a source power system operatively coupled to the coil and a bias power system operatively coupled to the substrate process chamber. The method includes transferring the substrate into the substrate process chamber. Thereafter, the substrate is exposed to a plasma formed from a first process gas consisting essentially of a sputtering agent by applying RF energy from the source power system to the coil. The plasma is biased toward the substrate by applying bias power to the substrate process chamber. Thereafter, the substrate is exposed to a plasma formed from a second process gas without applying bias power or applying minimal bias power to the substrate process chamber.
    • 一种用于处理设置在基板处理室中以改变形成在基板上的沟槽的轮廓的基板的方法。 衬底处理室是具有线圈和等离子体产生系统的类型,其包括可操作地耦合到线圈的源电力系统和可操作地耦合到衬底处理室的偏置电力系统。 该方法包括将衬底转移到衬底处理室中。 此后,通过将来自源电力系统的RF能量施加到线圈,将衬底暴露于由基本上由溅射剂组成的第一工艺气体形成的等离子体。 通过向衬底处理室施加偏置功率将等离子体偏压到衬底。 此后,将衬底暴露于由第二工艺气体形成的等离子体,而不施加偏置功率或向衬底处理室施加最小的偏置功率。
    • 8. 发明授权
    • Plasma reactor with dry clean apparatus and method
    • 具有干洗装置和方法的等离子体反应器
    • US06518190B1
    • 2003-02-11
    • US09470560
    • 1999-12-23
    • Thorsten LillJeffrey D. Chinn
    • Thorsten LillJeffrey D. Chinn
    • H01L2100
    • H01J37/32862H01J37/321
    • A preferred embodiment of the plasma reactor of the present invention provides a chamber adapted to process a workpiece having at least one wall capable of allowing inductive power coupling into the reactor chamber. A source power antenna, capable of generating a processing plasma, confronts a portion of the at least one wall. A dry clean antenna is located adjacent the chamber beside a portion of the at least one wall not confronted by the source power antenna. During workpiece processing, the dry clean antenna preferably has essentially a floating potential. After workpiece processing has ceased, a dry clean plasma may be generated by inductive coupling using the dry clean antenna. Embodiments of the present invention allow dry clean plasma characteristics to be optimized to improve dry clean effectiveness. The source power antenna also may couple power to the dry clean plasma, preferably in parallel with the dry clean antenna. With such embodiments, the source power antenna may be operated so that it couples less power to the dry clean plasma, while the dry clean antenna couples more. This allows sputtering of the chamber wall under the source power antenna to be reduced and allows more effective removal of accumulated deposits.
    • 本发明的等离子体反应器的一个优选实施例提供了适于处理工件的室,该工件具有至少一个能够将感应功率耦合到反应器室中的壁。 能够产生处理等离子体的源功率天线面对至少一个壁的一部分。 干净的天线位于与源功率天线不相对的至少一个壁的一部分旁边的室附近。 在工件加工过程中,干式天线优选具有基本的浮动电位。 在工件处理停止之后,可以通过使用干式天线的电感耦合来产生干净的等离子体。 本发明的实施例允许优化干洗等离子体特性以改善干洗效果。 源功率天线还可以将功率耦合到干洗等离子体,优选地与干净的天线并联。 通过这样的实施例,源功率天线可以被操作,使得它将更少的功率耦合到干净的等离子体,而干净的天线更多耦合。 这允许在源功率天线下方的室壁的溅射被减少并且允许更有效地去除积累的沉积物。
    • 9. 发明授权
    • Controlled deposition of silicon-containing coatings adhered by an oxide layer
    • 由氧化物层附着的含硅涂层的控制沉积
    • US08178162B2
    • 2012-05-15
    • US12592183
    • 2009-11-19
    • Boris KobrinRomuald NowakRichard C. YiJeffrey D. Chinn
    • Boris KobrinRomuald NowakRichard C. YiJeffrey D. Chinn
    • C23C16/00
    • B82Y30/00C23C16/0227C23C16/402
    • We have developed an improved vapor-phase deposition method and apparatus for the application of films/coatings on substrates. The method provides for the addition of a precise amount of each of the reactants to be consumed in a single reaction step of the coating formation process. In addition to the control over the amount of reactants added to the process chamber, the present invention requires precise control over the total pressure (which is less than atmospheric pressure) in the process chamber, the partial vapor pressure of each vaporous component present in the process chamber, the substrate temperature, and typically the temperature of a major processing surface within said process chamber. Control over this combination of variables determines a number of the characteristics of a film/coating or multi-layered film/coating formed using the method. By varying these process parameters, the roughness and the thickness of the films/coatings produced can be controlled.
    • 我们已经开发了一种改进的气相沉积方法和装置,用于在基底上施加膜/涂层。 该方法提供在涂层形成过程的单个反应步骤中添加精确量的每种待消耗的反应物。 除了控制添加到处理室中的反应物的量之外,本发明需要精确控制处理室中的总压力(其小于大气压),存在于处理室中的每种气态组分的部分蒸气压 处理室,衬底温度以及典型地在所述处理室内的主处理表面的温度。 对这种变量组合的控制决定了使用该方法形成的膜/涂层或多层膜/涂层的许多特性。 通过改变这些工艺参数,可以控制所生产的膜/涂层的粗糙度和厚度。