MEMS, Micromachining & Sensors: Prof. Glenn
H. Chapman
This page contains the paper abstract and full PDF versions of
publications
on Micromachining and Microsensors. Click on the link to download pdf
version.
See also the sensor array papers in the WSI
papers
section, micromachined systems in the Angular
Domain Imaging papers , and grayscale mask 3D structures in the Inorganic Thermal Resist papers.
Papers here are listed in order of
publication
Note: These papers are for academic use only and are not
available
for distribution or publication for other purposes.
Refereed Journal Papers
M. Salomon, J. Armitage, G.H. Chapman, M. Dixit,
W. Faszer, J-L. Hamel and G. Oakham, "Passivation of Gas Microstrip
Detectors
and Long Term Operation Stability", Nuclear Instruments and Methods in
Physics, A351, 313-316 (1994) nimpr94.pdf
256KB
We have studied the long-term operation of gas microstrip detectors
which have been passivated with a layer of nickel oxide. We have used
as
the active gas CF4/isobutane (80: 20) and three different types of
substrates:
Tedlar, glass and Upilex. In all three cases we found that the
detectors
are stable after passivation and can operate for a month without
changes
in gain at rates of MHz. The total accumulated charge was approximately
100 mC.
V. Ward,
M.J. Syrzycki, and G.H. Chapman, "CMOS
Photodetector with Built-In Light Adaptation Mechanism,"
Microelectronic
Journal, 24, 547-553, (1993). micro93.pdf
458KB
This paper reports research results on a new class of silicon
photodetectors
with built-.in light adaptation mechanisms. Previously used devices
feature
a limited dynamic range which is much smaller than a range of light
intensity
present in our environment. Intelligent vision systems functioning
similarly
to human vision systems require new photodetectors with abilities not
only
to cover wider dynamic range, but also able to accomplish background
adaptation
and dark adaptation mechanisms similar to those existing in human
retina.
The proposed class of devices uses the same silicon structure operating
in two or more operating modes of different sensitivity, with light-
controllable
switching between different modes. The measurements conducted on CMOS
photodetectors
fabricated in the 3 micron CMOS technology show that the new
photodetectors
have a dynamic range increased by at least two orders of magnitude and
feature limited power consumption, which is especially attractive for
large
area transducer systems.
Stoev, I.,
Surzycki, M., Parameswaran, M., Chapman,
G., and Rawicz, A. "Process Optimization for Micromachined Silicon
Non-Reverse
Valve", Can. Jour. of Physics, 70, 881-885 (1992). cjp92c.pdf
6960KB
The paper targets the development and optimization of technology for
a micromachined silicon nonreverse valve, intended for fluid delivering
applications in miniature fluidic systems. Several combinations of
valve
geometries and semiconductor process parameters were investigated,
resulting
in fabrication of different structures. Two-dimensional simulations
were
used to optimize the process parameters necessary to obtain V-grooved
silicon
membranes of specific thicknesses. The mechanical performance of the
valve
was also tested. Finally, modifications of valve structure for possible
integration with a pressure sensor were proposed.
Refereed Conference Proceedings
J.M.
Dykes, D.K. Poon, J. Wang, D. Sameoto, J.T.K. Tsui, C. Choo,
G.H. Chapman, A.M. Parameswaren, and B.L. Gray, “Creation of embedded
structures in SU-8”, Proc. SPIE Photonics West Microfluidics, BioMEMS,
and Medical Microsystems V, v 6465, pp 64650N1-N12, San Jose, Jan 2007.
photonw07mems.pdf
2,425KB
Two methods were investigated for the creation of encapsulated
micro-fluidic channels and bridges in negative tone SU-8
photoresist. The first uses two exposures at different
wavelengths to create the channel sidewalls and micro-channel
encapsulation layer; the other method creates both using a single
I-line (365 nm) exposure and a grayscale photomask. These methods
can define structures with vertical dimensions ranging to hundreds of
microns and introduces very little extra processing complexity.
For the dual wavelength method, an I-line light source is used to
define the channel walls while a non-collimated deep-UV (254 nm) light
source provides a large energy dose to the top surface of the SU-8 to
produce a membrane over all the channels. Using the dual
wavelength method allows SU-8 to be used as the material for the
channels and the encapsulation method is self-limiting avoiding the
requirement for precise control over the exposure dose. The rate
of UV dose and the post-exposure baking parameters are critical to the
quality and strength of the micro-channels. Properly designed
channels have been successfully developed in lengths up to 1
cm. Alternatively using a grayscale Zn/Al bimetallic
photomask and a single I-line exposure, 3D bridge micro-structures were
successfully made on SU-8. The use of grayscale masks for both
techniques also provides the possibility of shaping the channel.
With the ability to create micro-bridges, further research will be
performed to investigate how well the single exposure technique can be
used to produce micro-channels of various sizes and dimensions.
C. Hu, X. Qu,
J.Q.M Wu, and G.H. Chapman, “MOS hydrogen sensor
array for 2D gas distribution mapping”, Conf. of Metallurgists 2005, pp
497-504, Calgary, Canada, Aug., 2005. com05.pdf 118KB
A MOS capacitor hydrogen sensor array is reported for hydrogen gas
distribution mapping. Si(100) was used as substrate for film
deposition. After silicon oxide growing on the silicon surface with dry
thermal oxidation, palladium film was sputtered on silicon oxide as
hydrogen-sensitive gate material in MOS structure. The 3x3 sensor array
was patterned on silicon substrate and packaged in one chip. Sensors’
response was test with impedance analyzer. The sensors in array were
calibrated in the hydrogen concentration range from 10ppm to 10000ppm.
The 2D hydrogen concentration distribution was obtained with the
calibrated sensor array.
G.H.
Chapman, N. Sawadsky and P.P.S. Juneja, "Phase sensitive
techniques applied to a micromachined vacuum sensor", Proc. SPIE
Micromachined Devices and Components Conf., v 2882, pg
266-277, Austin, TX, (Oct. 1996) micromachined95.pdf
2,294KB
Phase sensitive AC measurement techniques are particularly applicable
to micromachined sensors detecting temperature changes at a sensor
caused by a microheater. The small mass produces rapid thermal response
to AC signals which are easily detectable with lock-in amplifiers.
Phase sensitive measurements were applied to a CMOS compatible
micromachined pressure sensor consisting a polysilicon sense line, 760
microns long, on an oxide microbridge separated by 6 microns on each
horizontal side from similar polysilicon heaters, all over a
micromachined cavity. Sinusoidal heater signals at 32 Hz induced
temperature caused sense line resistance changes at 64 Hz. The lock-in
detected this as a first harmonic sense resistor voltage from a DC
constant sense current. By observing the first harmonic the lock-in
rejects all AC coupling of noise by capacitance or inductance, by
measuring only those signals at the 64 Hz frequency and with a fixed
phase relationship to the heater driver signals. This sensor produces
large signals near atmospheric pressure, declining to 7 (mu) V below
0.1 mTorr. Phase measurements between 760 and 100 Torr where the air's
thermal conductivity changes little, combined with amplitude changes at
low pressure generate a pressure measurement accurate at 5 percent from
760 Torr to 10 mTorr, sensing of induced temperature changes of 0.001
degree C.
P.P.S.
Juneja and G.H. Chapman, "A Wide-Range
Vacuum
Sensor using Phase-Sensitive Detection", Proceedings of CCVLSI'93, 3A
7-12,
Banff, Alb (1993). ccvlsi93.pdf
532KB
A CMOS compatible micromachined pressure sensor has been developed
with a wide operating range of 760- 1E-4 Torr. It employs a unique
design,
and measures the pressure dependent heat flow from a thermally isolated
microheater across a 6 micron gap to a sense resistor. The sensor’s
rapid
thermal response allows the application of phase-sensitive AC
measurement
technique, and enables detection of temperature changes of less than
0.5
millidegree Celsius. The measurement technique also eliminates the
various
compensations required by Wheatstone- bridge method, widely employed in
the existing vacuum gauges.
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Last updated June 4, 2008