Ksjp, 7/01 MEMS Design & Fab Overview Electrostatics Basic equations Early applications Use in systems Scratch drive.

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Presentation transcript:

ksjp, 7/01 MEMS Design & Fab Overview Electrostatics Basic equations Early applications Use in systems Scratch drive

ksjp, 7/01 MEMS Design & Fab Electrostatic Actuators Plate-1 Plate-2 Plate-3 V (volts) x y d Consider parallel plate 1 & 2 Force of attraction (along y direction) F p = (½  V 2  A/g 2 ) dimensionless Consider plate 2 inserted between plate 1 and 3 (Popularly known as a COMB DRIVE) F c = (½  V 2 )(2t/g) Force of attraction (along x direction) Constant with x-directional translation

ksjp, 7/01 MEMS Design & Fab Electrostatics work sheet Assume you have a gap-closing actuator with 1 meter square plates separated by 1 meter. At 15V, what is the force between them? What if the plates are 1 micron square separated by 1 micron? 1mm square, separated by 1 micron, at 150V? Unit force = ½  V 2 Area multiplier=A/g 2 F p = (½  V 2  A/g 2 ) 1m^2x1m1um^2x1um 1mm^2x1um 150V

ksjp, 7/01 MEMS Design & Fab Paschen Curve Distance*pressure (meter*atm) Breakdown voltage E bd ~100MV/m ~200V 1atm

ksjp, 7/01 MEMS Design & Fab Side view of SDMTop view of SDM First polysilicon motors were made at UCB (Fan, Tai, Muller), MIT, ATT Typical starting voltages were >100V, operating >50V Side Drive Motors

ksjp, 7/01 MEMS Design & Fab High-Aspect-Ratio Rotary Polygon Micromotor Scanners A. A. Yasseen, J. N. Mitchell, D. A. Smith, and M. Mehregany Microfabrication Laboratory Department of Electrical Engineering and Applied Physics Case Western Reserve University Cleveland, Ohio Figure 1. SEM photo of a typical DRIE fabricated polygon scanner using a hexagonal rotor. The rotor is 1.4mm in diameter, and the reflecting sidewalls are 200  m-tall. Figure 3. Cross-sectional schematics describing the micromotor fabrication process: (a) after recess definition and patterning to a depth of 8  m; (b) after bushing definition and patterning to a depth of 2  m; (c) after rotor/stator definition and DRIE patterning through the top wafer; and (d) after rotor release and assembly onto the corresponding stator.

ksjp, 7/01 MEMS Design & Fab High-Aspect-Ratio Rotary Polygon Micromotor Scanners

ksjp, 7/01 MEMS Design & Fab A Rotary Electrostatic Micromotor 1  8 Optical Switch Micro Electro Mechanical Systems Jan., 1998 Heidelberg, Germany A Rotary Electrostatic Micromotor 1  8 Optical Switch A. Yasseen, J. Mitchell, T. Streit, D. A. Smith, and M. Mehregany Microfabrication Laboratory Dept. of Electrical Engineering and Applied Physics Case Western Reserve University Cleveland, Ohio Fig. 3 SEM photo of an assembled microswitch with vertical 200  m-tall reflective mirror plate. Fig. 4 Insertion loss and crosstalk measurements for multi- mode optics at 850  m.

ksjp, 7/01 MEMS Design & Fab Fiber Attenuator Solid-State Sensor and Actuator Workshop Hilton Head 1998 Low Insertion Loss Packaged and Fiber-Connectorized Si Surface-Micromachined Reflective Optical Switch V. Aksyuk, B. Barber, C. R. Giles, R. Ruel, L. Stulz, and D. Bishop Bell Laboratories, Lucent Technologies, 700 Mountain Ave. Murray Hill, NJ Figure 1. MEMS optical switch. For clarity the second optical fiber is not shown. Figure 2. Self-Assembling optical shutter. High tensile residual stress metal is deposited on a polysilicon beam anchored at one end. Upon release the metal-poly sandwich structure deforms, moving the free end of the beam upward. The lifting structure engages the cut in the hinged-plate shutter causing it to rotate 90 degrees into tits operating position.

ksjp, 7/01 MEMS Design & Fab Fiber Attenuator Solid-State Sensor and Actuator Workshop Hilton Head 1998 Low Insertion Loss Packaged and Fiber-Connectorized Si Surface-Micromachined Reflective Optical Switch V. Aksyuk, B. Barber, C. R. Giles, R. Ruel, L. Stulz, and D. Bishop Bell Laboratories, Lucent Technologies, 700 Mountain Ave. Murray Hill, NJ Figure 7. Second generation, fast switch operation. 10 times faster operation relative to Switch 1 is achieved with twofold increase in actuation voltage. Figure 8. Switch closing time as a function of actuator voltage. Solid symbols-switch delay time. Open symbols-fall time. Delay time results from the shutter having to accelerate and travel some distance before it starts blocking the beam.

ksjp, 7/01 MEMS Design & Fab Scratch Drive Actuator (SDA) Insulator Substrate Plate Bushing Micro XYZ positioning stages (L. Y. Lin, et. al., 1997; Li Fan, et. al., 1997) Self-assembly of MEMS devices (A. Terunobu, et. al., 1997; Y. Fukuta, et. al., 1997) Free-space fiber optic cross/bar switch (Shi-Sheng Lee, et. al., 1997)

ksjp, 7/01 MEMS Design & Fab SDA operation 1)Applied voltage bends SDA downward 2)When released, SDA returns to original shape 3)Reapplying voltage causes SDA to move a distance ‘dx’ dx Caveat: sometimes they go backward!

ksjp, 7/01 MEMS Design & Fab Tuneable RF components Inductors and Variable Capacitors Ming Wu, UCLA Assembled using scratch-drive actuators

ksjp, 7/01 MEMS Design & Fab Comb Drives Sandia cascaded comb drive (High force) Close-up Tang/Nguyen/Howe

ksjp, 7/01 MEMS Design & Fab Layout of electrostatic-combdrive Ground plate Folded beams (movable comb suspension) Anchors Stationary comb Moving comb Tang, Nguyen, Howe, MEMS89

ksjp, 7/01 MEMS Design & Fab Most complex micro-mechanical system to date?

ksjp, 7/01 MEMS Design & Fab Buckling-beam actuation in the Sandia process Micro Electro Mechanical Systems Jan., 1998 Heidelberg, Germany Micro-Flex Mirror and Instability actuation Technique Ernest J. Garcia Electromechanical Engineering Department Sandia National Laboratories Albuquerque, NM, USA Fig. 9 Drive LinkFig. 10 Actuate Position

ksjp, 7/01 MEMS Design & Fab Buckling-beam actuation in the Sandia process Micro Electro Mechanical Systems Jan., 1998 Heidelberg, Germany Micro-Flex Mirror and Instability actuation Technique Ernest J. Garcia Electromechanical Engineering Department Sandia National Laboratories Albuquerque, NM, USA Fig. 5 Linkage System for Force AmplificationFig. 8 Micro-Flex Mirror Linkage System.

ksjp, 7/01 MEMS Design & Fab Electrostatic instability Parallel-Plate Electrostatic Actuator Pull-in s0s0 k m x V V x s0s0 1/3 s 0 V snap

ksjp, 7/01 MEMS Design & Fab Controlling the instability Charge control Requires on-chip circuitry Series capacitor Increases required voltage Joe Seeger, UCB

ksjp, 7/01 MEMS Design & Fab Electrostatic spring Adjustable stiffness (sensitivity) and resonance frequency

ksjp, 7/01 MEMS Design & Fab Vibromotor k k k k hub slider impact arm M. Daneman et al, JMEMS, vol. 5, no. 3, pp , 1996.

ksjp, 7/01 MEMS Design & Fab Vibromotor-Actuated Micromirror for Fiber-Optic Alignment Daneman, IEEE Photonics Techn. Letters, vol. 8, no. 3, pp , March 1996.

ksjp, 7/01 MEMS Design & Fab Summary Electrostatics use moderate to high voltage Force goes as V 2 /g 2 Paschen limits convenient voltages to 200 Force is scale independent Easy process integration Many mechanism options