4.5 Article

Assembled Comb-Drive XYZ-Microstage With Large Displacements and Low Crosstalk for Scanning Force Microscopy

Journal

JOURNAL OF MICROELECTROMECHANICAL SYSTEMS
Volume 31, Issue 1, Pages 54-62

Publisher

IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/JMEMS.2021.3123962

Keywords

Crosstalk; Springs; Capacitance; Force; Magnetic force microscopy; Electrodes; Voltage measurement; Microassembly; comb-drive; stroke; crosstalk; XYZ-microstage; scanning force microscopy

Funding

  1. National Natural Science Foundation of China [52005291]
  2. Guangdong Basic and Applied Basic Research Foundation [2019A1515110373]
  3. Shenzhen Science and Technology Program [RCBS20200714114957381]

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This study introduces and demonstrates a novel XYZ microstage capable of providing large displacements and low crosstalk in scanning force microscopy applications at low temperatures. The microstage's three-dimensional structure, constructed using microassembly technology, includes an in-plane XY microstage and two out-of-plane Z actuators.
This paper proposes and demonstrates a chip-level-microassembly comb-drive XYZ-microstage for providing large displacements and low crosstalk in scanning force microscopy applications at low temperatures. The three-dimensional structure of the comb-drive XYZ-microstage, consisting of an in-plane XY-microstage, two out-of-plane Z-actuators, and a base substrate, was accurately and orderly constructed using microassembly technology. This configuration can overcome the out-of-plane stroke-space limitation of conventional monolithic-wafer-based XYZ-microstages, and the crosstalk movements resulting from the coupling connection between in-plane and out-of-plane actuation units can be avoided. The in-plane actuation unit of the XY-microstage can provide low-crosstalk movements in the X- and Y-directions, due to the design of the decoupling-motion structure and constraint of the capacitance-coupling crosstalk of the actuation voltages. Folded-flexure springs with high stiffness were adopted in the XYZ-microstage to enhance the lateral stability of movable combs and improve the range of achievable strokes. The assembled comb-drive XYZ-microstage could provide quite large displacements of 49.2 mu m, 27.9 mu m, and 50.5 mu m in the X-, Y-, and Z-directions, respectively. Furthermore, to demonstrate the feasibility of the fabricated XYZ-microstage, a magnetic resonance force microscopy measurement system was constructed using the scanning XYZ-microstage with a specimen of 1, 1-Diphenyl-2-picrylhydrazyl radical. The magnetic resonance force from the electron spin resonance excited in the specimen could be detected by scanning the specimen in a specific resonance region. The results demonstrate that the proposed microassembly with the optimized actuation-unit structure is a promising means of establishing a comb-drive XYZ-microstage with large displacements, low crosstalk, and high adaptability. [2021-0112]

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