1. A brief history of MEMS fabrication
Chang Liu
Micro Actuators, Sensors, Systems Group
University of Illinois at Urbana-Champaign
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UIUC

2. To Do …
Get a better diagram of MOS process flow.
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3. Outline Traditional silicon micromachining technology
Common microfabrication technology for IC
Bulk micromachining
Etching, bonding, planarization
Surface micromachining
Suspended structures, antistiction methods, 3D microstructures
Methods for merging micromechanics and IC
Extended microfabrication technology in 90’s
LIGA
Deep reactive ion etching
Polymer based microfabrication
Future foundry based processes
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4. A Standard IC Process http://www.chips.ibm.com/gallery/
Draw a diagram of a circuit.
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5. Basic Fabrication Processes
Deposition (Material addition)
spin coating, evaporation, electroplating, reactive growth, CVD, sputtering
Lithography
various wavelengths, mask making, alignment, exposure
Etching (Material removal)
wet chemical etching, dry plasma etching, gas phase etching,
Wafer bonding
Silicon on insulator wafers (SOI)
Packaging
adhesion, wire bonding
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6. From wafer to device
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8. Processing Equipments
A tour of lab is arranged in the middle of semester
Wafer aligner
and exposure tool
Metal Evaporator
Plasma etcher
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9. Micro Fabrication Technology
start
Cycle 1
Cycle 2
Cycle 3
Cycle 4
Cycle 5
Cycle 6
Starting
wafer
MEMS
subtracting
(etching)
pattern
Adding
(deposition)
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10. Silicon Bulk Etching
Anisotropic Etching
Isotropic etching
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13. First Idea for Surface Micromachining …
Physicist Richard Feynman
“There is plenty of room at the bottom”
Excerpt
How can we make such a device? What kind of manufacturing processes would we use? One possibility we might consider, since we have talked about writing by putting atoms down in a certain arrangement, would be to evaporate the material, then evaporate the insulator next to it. Then, for the next layer, evaporate another position of a wire, another insulator, and so on. So, you simply evaporate until you have a block of stuff which has the elements--- coils and condensers, transistors and so on---of exceedingly fine dimensions.
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14. Polysilicon as a Mechanical Material
Invented by Dr. Muller and Dr. Howe of Berkeley
Established sacrificial etching process using
polysilicon as a mechanical structural material
oxide as a sacrificial material
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15. How to represent process using cross-sectional view?
Surface Micromachining Fabrication Process for Micro Motor (1st pass description)
Learning objectives:
How to represent process using cross-sectional view?
Build ability to correlate mask and sideviews.
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16. Step 1: Starting wafer Mask top view Side view mask
Start with blank silicon wafer (one side polished with optical finish). Wafer orientation is not critical. The thickness of the wafer is not drawn to scale- the typical thickness of mm.
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17. Step 2: Deposition of sacrificial layer
Top view (mask)
Side view
mask
Deposit silicon oxide film (with phosphorous doping) as the sacrificial layer.
- conformal coating
- thickness 1-3 micrometers
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18. Step 3: Deposition of structural layer
Top view (mask)
Side view
mask
Deposit polycrystalline silicon film (without phosphorous doping) as the structural layer.
- conformal coating
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19. Step 4: Pattern the top polysilicon layer
Top view (mask)
Side view
Pattern the silicon layer with the first mask to form the shape of the rotor and the hole for the anchor.
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20. Step 5: Deposit a second sacrificial layer
Mask top view
Side view
mask
Conformal deposition of P-doped oxide again.
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21. Step 6: Pattern and Etch the sacrificial layers
Top view (mask)
Side view
Pattern the wafer with the photoresist layer and the first mask.
Using HF solutions to etch through the two oxide layers. Lateral etching will occur and the dimension control is critical.
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22. Step 7: Deposit polysilicon structural layer.
Top view (mask)
Side view
mask
Conformal deposition of polysilicon again.
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23. Step 8: Pattern Polysilicon.
Top view (mask)
Side view
mask
Pattern the top layer polysilicon to form the confinement structure and anchor.
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24. Step 9: Sacrificial layer removal and freeing of structures
Top view (mask)
Side view
mask
Remove the oxide using 49% HF solutions, which etches oxide fast (1 micron/minute) and the polysilicon slowly.
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25. High Aspect Ratio Devices
Thick photoresist
*: Lithographie, galvanoformung, abformung
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26. New Materials and Processes
Inorganic Materials and processes
High temperature materials processing (SiC)
Silicon Ge (SiGe)
Diamond (electrical conductance and mechanical toughness)
Laser Micromachining
Deep Reactive Ion Etching
Focused ion beam etching
Chemical mechanical polishing
Permanent magnet and electromagnetic materials
Rapid prototyping
Organic Materials
Silicone elastomer
Elastic polymer
Chemical vapor deposition of plastic films (Parylene)
Electroactive Materials …
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27. How to ? Micro guitar – Cornell University Sandia Photonic lattice
IBM Supercone
tip
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28. Man-made Submarine … in your artery MicroTEC Inc.
RMPD is a micro stereo lithography method for rapid creation of 3-D micro structures of any shape as prototypes or for series production
Das micro-U-Boot, das kleinste U-Boot der Welt!
Duisburg, Germany
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30. Focused Ion Beam Etching
energy: 30 keV
current: 6 pA - 7 nA
resolution: 16 nm
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31. FIB process (continued)
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32. Ferrari MEMS vs. Suzuki MEMS
Suzuki Swift 1997
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33. MUMPS 3 poly surface micromachining Process
One process, different devices.
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34. MEMS Foundry - MEMS Exchange
Distributed, Virtue fab
UC Berkeley
Cornell Nanofabrication Facility (CNF)
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35. Polymer MEMS Polymer materials as substrate Polymer as structures
Replaces silicon
Lower costs
Examples: liquid crystal polymer, polyimide, glass
Drawbacks: cannot integrate circuitry. However, circuits can be wire-bonded to the polymer chip
Polymer as structures
Replaces silicon, silicon nitride, silicon oxide, etc
Lower costs, greater mechanical flexibility
Examples: Parylene, photoresist, polyimide
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36. LCP for MEMS packaging 15mm
Copper-LCP laminates for flexible circuit boards
LCP thermal bonding for environmental encapsualtion
LCP substrates for robust devices
15mm
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37. Tactile Sensor Fabrication
Double-sided alignment, deposition and patterning of NiCr Strain gauges and Al RIE mask on 2mil (50μm) thick LCP
Dry etching (RIE O2 plasma) of 35μm deep, 500μm square backside cavity, remove Al
Deposition and patterning of Au interconnects
Spin and pattern 20μm tall polyimide tactile bumps
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38. Tactile Sensor Operation
Converts normal applied load into change in resistance
Array can image tactile contact
Similar fabrication techniques can provide shear data
1400μm
Applied Load
Compressive Strain (x-dir)
Tactile Bump
Strain Gauge
Area
Membrane
Perimeter
Tensile Strain (x-dir)
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39. Conclusions
Microfabrication technology is a dynamically advancing field.
Technology push
New microfab processes and materials are developed in response to application needs
Technology pull
New fabrication techniques enables new devices and new applications
Micromachining involves silicon, glass, and polymer materials, not just silicon alone.
The microfabrication process is an integral part of the device design and material selection. The capability and practicality of microfabrication must be taken into consideration when considering candidate designs.
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