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    • 3. 发明授权
    • Microfabricated ion trap array
    • 微型离子阱阵列
    • US07154088B1
    • 2006-12-26
    • US11089318
    • 2005-03-23
    • Matthew G. BlainJames G. Fleming
    • Matthew G. BlainJames G. Fleming
    • H01J49/42
    • H01J49/424H01J49/0018
    • A microfabricated ion trap array, comprising a plurality of ion traps having an inner radius of order one micron, can be fabricated using surface micromachining techniques and materials known to the integrated circuits manufacturing and microelectromechanical systems industries. Micromachining methods enable batch fabrication, reduced manufacturing costs, dimensional and positional precision, and monolithic integration of massive arrays of ion traps with microscale ion generation and detection devices. Massive arraying enables the microscale ion traps to retain the resolution, sensitivity, and mass range advantages necessary for high chemical selectivity. The reduced electrode voltage enables integration of the microfabricated ion trap array with on-chip circuit-based rf operation and detection electronics (i.e., cell phone electronics). Therefore, the full performance advantages of the microfabricated ion trap array can be realized in truly field portable, handheld microanalysis systems.
    • 可以使用集成电路制造和微机电系统工业已知的表面微加工技术和材料来制造包括多个具有1微米的内半径的离子阱的微加工离子阱阵列。 微加工方法可以批量制造,降低制造成本,尺寸和位置精度,以及大规模集成离子阱与微量离子产生和检测装置的整体集成。 大规模阵列使微型离子阱能够保持高化学选择性所需的分辨率,灵敏度和质量范围优势。 降低的电极电压使得可以将微加工离子阱阵列与基于片上电路的射频操作和检测电子装置(即手机电子设备)集成。 因此,微型离子阱阵列的全部性能优势可以在真正的便携式手持式微量分析系统中实现。
    • 4. 发明授权
    • Microfabricated cylindrical ion trap
    • 微型圆柱形离子阱
    • US06870158B1
    • 2005-03-22
    • US10456310
    • 2003-06-05
    • Matthew G. Blain
    • Matthew G. Blain
    • H01J49/26H01J49/38H01J49/42
    • H01J49/424H01J49/0018H01J49/38
    • A microscale cylindrical ion trap, having an inner radius of order one micron, can be fabricated using surface micromachining techniques and materials known to the integrated circuits manufacturing and microelectromechanical systems industries. Micromachining methods enable batch fabrication, reduced manufacturing costs, dimensional and positional precision, and monolithic integration of massive arrays of ion traps with microscale ion generation and detection devices. Massive arraying enables the microscale cylindrical ion trap to retain the resolution, sensitivity, and mass range advantages necessary for high chemical selectivity. The microscale CIT has a reduced ion mean free path, allowing operation at higher pressures with less expensive and less bulky vacuum pumping system, and with lower battery power than conventional- and miniature-sized ion traps. The reduced electrode voltage enables integration of the microscale cylindrical ion trap with on-chip integrated circuit-based rf operation and detection electronics (i.e., cell phone electronics). Therefore, the full performance advantages of microscale cylindrical ion traps can be realized in truly field portable, handheld microanalysis systems.
    • 可以使用集成电路制造和微机电系统工业已知的表面微加工技术和材料来制造具有1微米内径的微米级圆柱形离子阱。 微加工方法可以批量制造,降低制造成本,尺寸和位置精度,以及大规模集成离子阱与微量离子产生和检测装置的整体集成。 大规模阵列使微型圆柱形离子阱能够保持高化学选择性所需的分辨率,灵敏度和质量范围优势。 微型CIT具有减小的离子平均自由程,允许在较低压力下操作,成本较低且体积较小的真空泵系统,并且具有比常规和微型尺寸离子阱更低的电池功率。 降低的电极电压使得微型圆柱形离子阱与基于片上集成电路的RF操作和检测电子装置(即,手机电子设备)的集成。 因此,微型圆柱形离子阱的全部性能优势可以在真正的便携式手持式微量分析系统中实现。