IEEE, AVS, and ECS Fellow
Department
of Electrical Engineering and Computer Science
2304
1301 Beal Avenue
Telephone: 734-936-2962
Fax: 734-763-9324
Email: pang@umich.edu
On Sabbatical (2007-2008)
Hong Kong University of
Science and Technology
Department of Electronic and Computer
Engineering
Room 2523
Telephone: 852-2358-5034
Fax: 852-2358-1485
Email: eepang@ust.hk
Education
Ph.D., Department of Electrical Engineering and Computer
Science (Electronic Materials and Devices),
MSc., Electrical Engineering and Computer Science,
ScB., Electrical and Computer Engineering,
Nanofabrication Technology, Nanoimprint, Dry Etching, Dry
Deposition, Biomedical, Microelectronic, Optical, and Microelectromechanical
Devices
Research areas include nanofabrication technology, nanoimprint,
fluidic systems for DNA analysis, nanostructures for cell growth, MEMS based
chemical sensors, plasma etching and deposition technology, process induced
damage, micromachining technology and devices, field emission devices, and
quantum effect devices. High-resolution patterning and plasma processing are
used to generate devices and systems with features below 100 nm. Reversal
nanoimprint has been developed to generate patterns on flexible substrates,
three dimensional nanostructures, and sealed multiple levels fluidic
systems. Plasma process induced
defects are identified and techniques to minimize, remove, and passivate damage
have been developed. Novel techniques in micromachining are developed to create
high sensitivity and high frequency resonators and sensors with merged
circuits. Optical switching arrays in Si are formed using vertical Si micromirrors
and high aspect ratio resonators. Uniform arrays of gated Si field emission
devices are fabricated with sharp emitters and close gate-tip spacing. These
high efficiency field emitters have low threshold voltage and high emission
current, especially after plasma passivation or HfC coating. Controllable and
low damage dry etching technology is applied to single electron transistors,
in-plane gated quantum wire transistors, heterojunction bipolar transistors,
optical waveguides and mirrors with high performance.
- Develop reversal nanoimprint
to pattern nanostructures over topography and to create 3D devices and
systems.
- Develop microfluidic systems
to immobilize, move, and stretch DNA molecules in sealed channels.
- Demonstrate control of cell
growth on patterned nanostructures.
- Develop and characterize
multiple stage preconcentrators with high sensitivity.
- Identify process induced
defects and relate changes in electrical characteristics to optical
responses. Develop novel techniques to minimize or passivate damage to
provide substantial performance improvements. Model and control defect
generation and distribution in Si and III-V devices.
- Develop and characterize
quantum effect devices including single electron transistors, in-plane
gated quantum wire transistors and quantum wires/dots for lasers and
waveguides. Patterning and etching technologies are developed to fabricate
high quality devices down to 20 nm.
- Develop direct nano-printing
technology in metal and polymer using SiC molds for high resolution and
high throughput patterning. This is the first demonstration that
nanostructures down to 20 nm can be printed in metal repeatedly using a
SiC mold.
- Develop novel micromachining
technology to fabricate thick resonators with higher sensitivity. With
this new technology, device thickness is no longer limited and the process
is simplified significantly since bonding to glass is not needed and it
requires only 1 mask level.
- Implementation of merged MEMS
devices with on-chip circuits using thick (>10 µm) single crystal Si
microstructures without bonding to glass or another wafer. Without
bonding, the process is simplified significantly. The thick single crystal
Si also provides higher sensitivity and higher quality factor.
- Demonstration of vertical
mirrors and lenses in Si that can be controlled by integrated
electrostatic drivers. Optical switching arrays with Si vertical mirrors
were fabricated with large modulations of the optical signals at low
power.
- Develop new technology for
self-aligned field emitter arrays with sharp emitters and close gate-tip
spacings. Emitters with radius of 8 nm and density >107 tips/cm2
have been demonstrated. Low turn-on voltage (16 V), high emission current
(6 µA/tip), and good stability (¡À0.25%) were obtained which are substantially
better than previously reported results.
- Develop low damage emitter etch and precise end point techniques for self-aligned HBTs. Emitter etching is stopped within 5 nm with low damage and high device performance.
Last Updated: November 19, 2007
E-Mail: pang@umich.edu