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    • 1. 发明申请
    • ION MANIPULATION DEVICE
    • 离子操作装置
    • US20140299766A1
    • 2014-10-09
    • US14146922
    • 2014-01-03
    • Gordon A. AndersonRichard D. SmithYehia M. IbrahimErin M. Baker
    • Gordon A. AndersonRichard D. SmithYehia M. IbrahimErin M. Baker
    • H01J49/06
    • H01J49/062G01N27/622H01J49/06
    • An ion manipulation method and device is disclosed. The device includes a pair of substantially parallel surfaces. An array of inner electrodes is contained within, and extends substantially along the length of, each parallel surface. The device includes a first outer array of electrodes and a second outer array of electrodes. Each outer array of electrodes is positioned on either side of the inner electrodes, and is contained within and extends substantially along the length of each parallel surface. A DC voltage is applied to the first and second outer array of electrodes. A RF voltage, with a superimposed electric field, is applied to the inner electrodes by applying the DC voltages to each electrode. Ions either move between the parallel surfaces within an ion confinement area or along paths in the direction of the electric field, or can be trapped in the ion confinement area.
    • 公开了一种离子操作方法和装置。 该装置包括一对基本上平行的表面。 内部电极的阵列包含在每个平行表面内并且基本上沿着每个平行表面的长度延伸。 该装置包括电极的第一外部阵列和第二外部电极阵列。 每个外部电极阵列位于内部电极的任一侧上,并且基本上沿着每个平行表面的长度容纳并延伸。 DC电压施加到第一和第二外部电极阵列。 通过向每个电极施加直流电压,将具有叠加电场的RF电压施加到内部电极。 离子在离子限制区域内的平行表面之间或沿着电场方向的路径移动,或者可以被捕获在离子限制区域中。
    • 3. 发明授权
    • Vacuum chamber for ion manipulation device
    • 离子操作装置真空室
    • US08907273B1
    • 2014-12-09
    • US14292437
    • 2014-05-30
    • Tsung-Chi ChenKeqi TangYehia M. IbrahimRichard D. SmithGordon A. AndersonErin M. Baker
    • Tsung-Chi ChenKeqi TangYehia M. IbrahimRichard D. SmithGordon A. AndersonErin M. Baker
    • H01J49/06
    • H01J49/062G01N27/622H01J49/06
    • An ion manipulation method and device is disclosed. The device includes a pair of substantially parallel surfaces. An array of inner electrodes is contained within, and extends substantially along the length of, each parallel surface. The device includes a first outer array of electrodes and a second outer array of electrodes. Each outer array of electrodes is positioned on either side of the inner electrodes, and is contained within and extends substantially along the length of each parallel surface. A DC voltage is applied to the first and second outer array of electrodes. A RF voltage, with a superimposed electric field, is applied to the inner electrodes by applying the DC voltages to each electrode. Ions either move between the parallel surfaces within an ion confinement area or along paths in the direction of the electric field, or can be trapped in the ion confinement area. A predetermined number of pairs of surfaces are disposed in one or more chambers, forming a multiple-layer ion mobility cyclotron device.
    • 公开了一种离子操作方法和装置。 该装置包括一对基本平行的表面。 内部电极的阵列包含在每个平行表面内并且基本上沿着每个平行表面的长度延伸。 该装置包括电极的第一外部阵列和第二外部电极阵列。 每个外部电极阵列位于内部电极的任一侧上,并且基本上沿着每个平行表面的长度容纳并延伸。 DC电压施加到第一和第二外部电极阵列。 通过向每个电极施加直流电压,将具有叠加电场的RF电压施加到内部电极。 离子在离子限制区域内的平行表面之间或沿着电场方向的路径移动,或者可以被捕获在离子限制区域中。 预定数量的一对表面设置在一个或多个室中,形成多层离子迁移回旋加速器装置。
    • 5. 发明授权
    • Ion manipulation device with electrical breakdown protection
    • 离子操纵装置具有电击穿保护
    • US08901490B1
    • 2014-12-02
    • US14292448
    • 2014-05-30
    • Tsung-Chi ChenKeqi TangYehia M. IbrahimRichard D. SmithGordon A. AndersonErin M. Baker
    • Tsung-Chi ChenKeqi TangYehia M. IbrahimRichard D. SmithGordon A. AndersonErin M. Baker
    • H01J49/42
    • H01J49/062G01N27/622H01J49/06
    • An ion manipulation method and device is disclosed. The device includes a pair of substantially parallel surfaces. An array of inner electrodes is contained within, and extends substantially along the length of, each parallel surface. The device includes a first outer array of electrodes and a second outer array of electrodes. Each outer array of electrodes is positioned on either side of the inner electrodes, and is contained within and extends substantially along the length of each parallel surface. A DC voltage is applied to the first and second outer array of electrodes. A RF voltage, with a superimposed electric field, is applied to the inner electrodes by applying the DC voltages to each electrode. Ions either move between the parallel surfaces within an ion confinement area or along paths in the direction of the electric field, or can be trapped in the ion confinement area. The surfaces are housed in a chamber, and at least one electrically insulative shield is coupled to an inner surface of the chamber for increasing a mean-free-path between two adjacent electrodes in the chamber.
    • 公开了一种离子操作方法和装置。 该装置包括一对基本平行的表面。 内部电极的阵列包含在每个平行表面内并且基本上沿着每个平行表面的长度延伸。 该装置包括电极的第一外部阵列和第二外部电极阵列。 每个外部电极阵列位于内部电极的任一侧上,并且基本上沿着每个平行表面的长度容纳并延伸。 DC电压施加到第一和第二外部电极阵列。 通过向每个电极施加直流电压,将具有叠加电场的RF电压施加到内部电极。 离子在离子限制区域内的平行表面之间或沿着电场方向的路径移动,或者可以被捕获在离子限制区域中。 表面容纳在腔室中,并且至少一个电绝缘屏蔽件联接到腔室的内表面,以增加腔室中两个相邻电极之间的平均自由程。
    • 6. 发明授权
    • Ion manipulation device
    • 离子操纵装置
    • US08835839B1
    • 2014-09-16
    • US14146922
    • 2014-01-03
    • Gordon A. AndersonRichard D. SmithYehia M. IbrahimErin M. Baker
    • Gordon A. AndersonRichard D. SmithYehia M. IbrahimErin M. Baker
    • H01J49/06
    • H01J49/062G01N27/622H01J49/06
    • An ion manipulation method and device is disclosed. The device includes a pair of substantially parallel surfaces. An array of inner electrodes is contained within, and extends substantially along the length of, each parallel surface. The device includes a first outer array of electrodes and a second outer array of electrodes. Each outer array of electrodes is positioned on either side of the inner electrodes, and is contained within and extends substantially along the length of each parallel surface. A DC voltage is applied to the first and second outer array of electrodes. A RF voltage, with a superimposed electric field, is applied to the inner electrodes by applying the DC voltages to each electrode. Ions either move between the parallel surfaces within an ion confinement area or along paths in the direction of the electric field, or can be trapped in the ion confinement area.
    • 公开了一种离子操作方法和装置。 该装置包括一对基本上平行的表面。 内部电极的阵列包含在每个平行表面内并且基本上沿着每个平行表面的长度延伸。 该装置包括电极的第一外部阵列和第二外部电极阵列。 每个外部电极阵列位于内部电极的任一侧上,并且基本上沿着每个平行表面的长度容纳并延伸。 DC电压施加到第一和第二外部电极阵列。 通过向每个电极施加直流电压,将具有叠加电场的RF电压施加到内部电极。 离子在离子限制区域内的平行表面之间或沿着电场方向的路径移动,或者可以被捕获在离子限制区域中。
    • 10. 发明授权
    • Microchip and wedge ion funnels and planar ion beam analyzers using same
    • Microchip和楔形离子漏斗以及使用其的平面离子束分析仪
    • US08299443B1
    • 2012-10-30
    • US13087100
    • 2011-04-14
    • Alexandre A. ShvartsburgGordon A. AndersonRichard D. Smith
    • Alexandre A. ShvartsburgGordon A. AndersonRichard D. Smith
    • H01J49/42H01J49/04
    • H01J49/0018H01J49/066
    • Electrodynamic ion funnels confine, guide, or focus ions in gases using the Dehmelt potential of oscillatory electric field. New funnel designs operating at or close to atmospheric gas pressure are described. Effective ion focusing at such pressures is enabled by fields of extreme amplitude and frequency, allowed in microscopic gaps that have much higher electrical breakdown thresholds in any gas than the macroscopic gaps of present funnels. The new microscopic-gap funnels are useful for interfacing atmospheric-pressure ionization sources to mass spectrometry (MS) and ion mobility separation (IMS) stages including differential IMS or FAIMS, as well as IMS and MS stages in various configurations. In particular, “wedge” funnels comprising two planar surfaces positioned at an angle and wedge funnel traps derived therefrom can compress ion beams in one dimension, producing narrow belt-shaped beams and laterally elongated cuboid packets. This beam profile reduces the ion density and thus space-charge effects, mitigating the adverse impact thereof on the resolving power, measurement accuracy, and dynamic range of MS and IMS analyzers, while a greater overlap with coplanar light or particle beams can benefit spectroscopic methods.
    • 电动离子漏斗使用振荡电场的Dehmelt电位限制,引导或聚焦气体中的离子。 描述了处于或接近大气压力的新漏斗设计。 在这种压力下的有效离子聚焦是通过极大幅度和频率的场来实现的,微观间隙允许在任何气体中具有比当前漏斗的宏观间隙高得多的电击穿阈值。 新的微间隙漏斗可用于将大气压电离源与包括差分IMS或FAIMS的质谱(MS)和离子迁移率分离(IMS)阶段以及各种配置的IMS和MS阶段进行接口。 特别地,包括两个定位在一个角度的平坦表面的楔形漏斗和从其衍生的楔形漏斗捕获器可以在一个维度上压缩离子束,产生窄的带状波束和横向细长的长方体分组。 这种光束轮廓降低了离子密度,从而降低了空间电荷效应,减轻了MS和IMS分析仪的分辨率,测量精度和动态范围的不利影响,而与共面光或粒子束的更大重叠可有利于光谱方法 。