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    • 1. 发明申请
    • NANOTUBE DEVICE STRUCTURE AND METHODS OF FABRICATION
    • 纳米管装置结构和制造方法
    • WO2005017967A3
    • 2005-09-15
    • PCT/US2004026075
    • 2004-08-12
    • NANTERO INCBERTIN CLAUDE LRUECKES THOMASSEGAL BRENT M
    • BERTIN CLAUDE LRUECKES THOMASSEGAL BRENT M
    • G11C13/02H01H1/027H01H59/00H01L21/00H01L27/28H01L29/06H01L29/73H01L29/78H01L51/30
    • H01L29/0665B82Y10/00G11C13/025G11C23/00H01H1/0094H01H1/027H01H2001/0005H01L27/28H01L29/0673H01L29/73H01L29/78H01L51/0048H01L51/0508Y10S977/725Y10S977/733Y10S977/755Y10S977/938Y10T29/49105
    • Under one embodiment, a method of forming a nanotube switching element includes forming a first structure having at least one output electrode, forming a conductive article having at least one nanotube, and forming a second structure having at least one output electrode and positioning said second structure in relation to the first structure and the conductive article such that the output electrode of the first structure is opposite the output electrode of the second structure and such that a portion of the conductive article is positioned therebetween. At least one signal electrode is provided in electrical communication with the conductive article having at least one nanotube, and at least one control electrode is provided in relation to the conductive article such that the conductive electrode may control the conductive article to form a channel between the signal electrode and at least one of the output electrodes. The first and second structures each include a respective second output electrode and wherein the second electrodes are positioned opposite each other with the conductive article positioned therebetween. The control electrode and the second control electrode includes an insulator layer on a surface facing the conductive article.
    • 在一个实施方案中,形成纳米管开关元件的方法包括形成具有至少一个输出电极的第一结构,形成具有至少一个纳米管的导电制品,以及形成具有至少一个输出电极的第二结构和将所述第二结构 相对于第一结构和导电制品,使得第一结构的输出电极与第二结构的输出电极相对,并且使得导电制品的一部分位于它们之间。 至少一个信号电极被提供为与具有至少一个纳米管的导电制品电连通,并且相对于导电制品提供至少一个控制电极,使得导电电极可以控制导电制品以在 信号电极和至少一个输出电极。 第一和第二结构各自包括相应的第二输出电极,并且其中第二电极彼此相对定位,导电制品位于其间。 控制电极和第二控制电极在面向导电制品的表面上包括绝缘体层。
    • 2. 发明申请
    • ENERGY CONVERSION SYSTEMS UTILIZING PARALLEL ARRAY OF AUTOMATIC SWITCHES AND GENERATORS
    • 使用自动切换和发电机并联阵列的能量转换系统
    • WO2004109104A3
    • 2005-04-28
    • PCT/US0340488
    • 2003-12-18
    • AMBIENT SYSTEMS INC
    • PINKERTON JOSEPH FHARLAN JOHN C
    • H01L41/113H02N11/00H02N2/00
    • H01L41/1136H02N2/18H02N11/002H02N11/006Y02T10/166Y10S977/708Y10S977/724Y10S977/725Y10S977/796Y10S977/837Y10S977/936Y10S977/948
    • Nanoéléctromechanical systems utilizing nanometer-scale assemblies are provided that convert thermal energy into another form of energy that can be used to perform useful work at a macroscopic level. These systems may be used to, for example; produce Useful quantities of electric or mechanical energy, heat or cool an external substance or propel an object in a controllable direction. In particular, the present invention includes nanometer-scale beams that reduce the velocity of working substance molecules that collide with this nanometer-scale beam by converting some of the kinetic energy of a colliding molecule into kinetic energy of the nanometer-scale beam. In embodiments that operate without a working substance, the thermal vibrations of the beam itself create-the necessary beam motion. In some embodiments, an -automatic switch is added to realize a regulator such that the nanometer-scale beams only deliver voltages that exceed a-particular amount. Various devices including piezoelectric, electromagnetic and electromotive force generators, are used to convert the kinetic energy of the nanometer-scale beam into electromagnetic, electric or thermal energy. Systems in which the output energy of millions of these devices is efficiently summed together are also disclosed as well as systems that include nanometer-scale transistors.
    • 提供了利用纳米级组件的纳米机电系统,其将热能转换成另一形式的能量,其可用于在宏观层面执行有用的工作。 这些系统可以用于例如 产生有用的电力或机械能量,加热或冷却外部物质或以可控方向推进物体。 特别地,本发明包括通过将碰撞分子的一些动能转化成纳米级光束的动能来降低与该纳米级光束碰撞的工作物质分子的速度的纳米级光束。 在没有工作物质的情况下运行的实施例中,光束本身的热振动产生必要的光束运动。 在一些实施例中,添加自动开关以实现调节器,使得纳米级光束仅传递超过特定量的电压。 使用包括压电,电磁和电动势发生器在内的各种装置将纳米级光束的动能转换成电磁,电或热能。 还公开了将数百万个这些器件的输出能量有效地相加在一起的系统以及包括纳米级晶体管的系统。
    • 3. 发明申请
    • NANOSTRUCTURE BASED MICROFLUIDIC PUMPING DEVICE AND METHOD
    • 基于纳米结构的微流体泵送装置及方法
    • WO2004054811A3
    • 2005-01-27
    • PCT/US0338322
    • 2003-12-03
    • BROTHER INT
    • LEWIS HOWARDMOHAMADINEJAD HABIB
    • B41J2/14B41J2/04
    • B41J2/14Y10S977/725Y10S977/902
    • A microfluidic actuator suitable for effecting drop on demand inkjet printing by ejecting fluid (110) through at least one nozzle (115) from at least one cavity (105) being at least partially formed by a deflectable membrane (130), the actuator including: and actuator chamber (14) operatively coupled to the membrane and containing at least one electrolytic fluid (135) and; at least one nanostructure (145) contained in the electrolytic fluid; and, wherein, the nanostructure is adapted to deflect toward the membrane in response to an operating voltage being applied to at least the nanostructure thereby deflecting the membrane and causing the fluid to be ejected through the nozzle.
    • 一种微流体致动器,适于通过至少一个腔(105)从至少部分地由可偏转膜(130)形成的至少一个喷嘴(115)喷射流体(110)来实现喷墨打印,所述致动器包括: 和致动器室(14),其可操作地耦合到所述膜并且包含至少一个电解液(135);和 包含在所述电解液中的至少一个纳米结构(145) 并且其中,所述纳米结构适于响应于施加到至少所述纳米结构的操作电压而朝向所述膜偏转,从而偏转所述膜并使所述流体通过所述喷嘴喷射。
    • 5. 发明申请
    • THERAPEUTIC FIELD GENERATOR
    • 治疗领域发电机
    • WO1996032158A1
    • 1996-10-17
    • PCT/GB1996000908
    • 1996-04-15
    • WALPOLE, Stephen, JohnLONG, Sharon, Alice, Jane
    • A61N01/40
    • A61N1/40A61N2/02Y10S977/725Y10S977/838Y10S977/948
    • The invention relates to a therapeutic field generator (10), particularly generating an electromagnetic or electric field. The invention is particularly but not exclusively concerned with generators adapted to be portable, self-contained units, and worn by a person. There is described an electromagnetic or electric field generator apparatus (10), for therapeutic use, comprising monitoring means (12) for determining the heartbeat frequency of the user; one or more generators (11) adapted to generate a first signal and a second signal, wherein the frequency of the first signal is dependent upon the determined heartbeat frequency; and means for outputting the signals (14) as an electromagnetic or electric field. Preferably the second signal is a train of pulses each having a width substantially equal to the width of a neuron depolarisation pulse-typically about 125 mu sec.
    • 本发明涉及治疗场发生器(10),特别是产生电磁场或电场。 本发明特别但不排他地涉及适于便携式,独立的单元并由人佩戴的发电机。 描述了用于治疗用途的电磁或电场发生器装置(10),包括用于确定用户的心跳频率的监测装置(12) 适于产生第一信号和第二信号的一个或多个发生器(11),其中所述第一信号的频率取决于确定的心跳频率; 以及用于输出信号(14)作为电磁场或电场的装置。 优选地,第二信号是脉冲串,每个脉冲具有基本上等于神经元去极化脉冲的宽度的宽度 - 通常约为125μsec。
    • 10. 发明申请
    • ACTUATORS USING DOUBLE-LAYER CHARGING OF HIGH SURFACE AREA MATERIALS
    • 使用高层表面材料双层充电的执行器
    • WO00050771A1
    • 2000-08-31
    • PCT/US2000/004633
    • 2000-02-24
    • F03G7/00H02N11/00
    • H02N11/006F03G7/005Y10S136/291Y10S977/725
    • Actuators are described that operate as a result of double-layer charge injection in electrodes having very high gravimetric surgace areas and gravimetric capacitances. The actuator output of the actuators may be a mechanical displacement that can be used to accomplish mechanical work. As a result of the non-faradaic process and the actuator materials utilized, such as carbon nanotubes, the actuators have improved work capacity, power density, cycle life, and force generation capabilities. Other benefits include low voltage operation and high temperature performance. The actuators also convert a mechanical energy input to an electrical energy output. The actuators may be used to control either thermal, electrical or fluid transport or cause either the switching, phase shift, or attenuation of electromagnetic radiation.
    • 描述了在具有非常高的重量手术区域和重量电容的电极中作为双层电荷注入的结果来操作的致动器。 致动器的致动器输出可以是可用于完成机械作业的机械位移。 由于采用非法拉第工艺和所使用的致动器材料,例如碳纳米管,致动器具有改进的工作能力,功率密度,循环寿命和力产生能力。 其他优点包括低电压操作和高温性能。 执行器还将机械能量输入转换为电能输出。 致动器可用于控制热,电或流体输送或导致电磁辐射的切换,相移或衰减。