Fall 2008 EE 410/510: Microfabrication and Semiconductor Processes M W 12:45 PM – 2:20 PM EB 239 Engineering Bldg. Instructor: John D. Williams, Ph.D. Assistant Professor of Electrical and Computer Engineering Associate Director of the Nano and Micro Devices Center University of Alabama in Huntsville 406 Optics Building Huntsville, AL 35899 Phone: (256) 824-2898 Fax: (256) 824-2898 email: [email protected]
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Fall 2008 EE 410/510:Microfabrication and Semiconductor Processes
M W 12:45 PM – 2:20 PMEB 239 Engineering Bldg.
Instructor: John D. Williams, Ph.D.Assistant Professor of Electrical and Computer Engineering
Associate Director of the Nano and Micro Devices CenterUniversity of Alabama in Huntsville
406 Optics BuildingHuntsville, AL 35899Phone: (256) 824-2898
• Place MEMS die onto dip chip package, wire bond, and vacuum seal
• Issues:– Dip chip packages are plastic– Ceramic dip chip packages are difficult
to seal– Long term metal to metal packaging fails – Difficult to achieve high vacuum for
device performance and maintain it over years
• Solution: Encapsulate the MEMS device on chip then package the MEMS/IC chip using standard technologies
Figures taken from:
High Volume MEMS:Devices, Stability, Packaging
DMD commercial Success
• Robust Manufacturing with high yield and single release process allows for fabrication of Texas Instruments DLPs
• Anodic Bond Package to transparent Pyrex 7740 Glass provides sufficient vacuum for DLP response
• Package is sealed over large area with wide bond seam to prevent long term failure
Figures taken from:
Motorola / FreescalePressure Sensor
• Single Crystal sensor mounted in injection molded thermoplastic case
• Machined cap• Silicone oil (most tested oil in the
history of mankind)• No direct IC package integration.
Simple wire bonds from the package are sufficient
• Process utilizes 25 years of experience in pressure sensors at Motorola
• Very little work in novel MEMS process development
• No vacuum sealing of MEMS component required
Figures taken from:
AMD Accelerometers• First integrated surface microdevice on the market (1993)• Perhaps the largest market device in MEMS today• Package does not include MEMS encapsulation. Entire die is vacuumed hermetically sealed in IC package
Figures taken from:
Motorola’s MMA Air Bag Sensor• 3 layer poly process proven over
multiple years of preproduction• Complete IC integration• Packaging still performed at the die
level• No independent MEMS encapsulation
Figures taken from:
SOI Based Optical MEMS by Analog Devices
• CNP and silicon bonding of multiple SOI wafers allows for complete IC integration of tilt mirror optics
• SOI integration allows for low voltage electronics and high voltage MEMS mirrors to be integrated directly on the same die
• Independence of MEMS is provided by multilayer device fabrication and bonding
• Encapsulation is still performed at the die level
Figures taken from:
Package Protection from Dicing• Dicing Problems with MEMS• MEMS components can be easily
damaged or destroyed by water and particles present during the dicing process
• This is overcome by a number of methods
– Release is often performed after dicing– Motorola and Bosch use glass frit is
used to seal MEMS components prior to dicing then etched away after.
– TI DLPs required a different solution• First mirrors are released• Protective organic film placed on mirrors
allows for normal cleaning processes• Dicing occurs• Singulated chips are mounted on
ceramic packages prior to dry etching organic layers Figures taken from:
Packaging MEMS that need Separate Encapsulation
• Conventional MEMS devices are fabricated, packaged, and connected to IC control circuits for commercial use
• The more compatible the fabrication scheme is with IC processing, the easier the device is to integrate
• However, some devices such as the one pictured, are not directly compatible with IC processing at all
• In both cases, MEMS are manufactured, packaged, integrated either on chip or off chip with an IC, then packaged using dip chip technology and released to the market
• Problem: MEMS encapsulation is not simple or easy
– Issues with bond seams– Issues with material compatibility– Issues with vacuum
• Today: DARPA BAA call currently out to generate a low power MEMS based high vacuum device for integration directly into MEMS packages. Cost will probably be $2- 15M per team over 3 years depending on nature of team and requirements for industrial success Figures taken from:
• The Big Question: How does one get the MEMS component sealed from the remainder of the IC and device package while still providing sufficient interaction with the sensing environment?????
Various Bonding Mechanisms
Figures taken from:
Permeability of Materials for Packaging to Water
• Although some polymers such as BCB are better than others, packaging with polymers does not provide a long term solution for commercial devices
• Glasses provide relatively long term seals if the width of the bond seam is sufficient.
– bond seams are 0.25 -1mm wide• Metals provide best long term
hermiticity– Al-to nitride– Au eutectic:
• 0.08 mm bond seam for 320oC• >0.25 mm bond seam for Temp
below 250 um– AuIn eutectic: >0.3 mm bond seam
BCB Polymer bonding• Advantages
– Low bond temp– No metals– Elastic (less worry about CTE
mismatches)• Disadvantages
– Long term permeability of water– High vapor pressure– Poor mechanical properties
Ideal upper limit: 1*10-9 mbar l/s Sealant used was Si3N4
Gold Compression Bonding• Au/Au eutectic: • 0.08 mm bond seam for 320oC• >0.25 mm bond seam for Temp at