1 Absolute Pressure Sensors Z. Celik-Butler, D. Butler and M. Chitteboyina Nanotechnology Research...
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1 Absolute Pressure Sensors Absolute Pressure Sensors Z. Celik-Butler, D. Butler and M. Chitteboyina Nanotechnology Research and Teaching Facility University of Texas at Arlington http://www.uta.edu/engineering/nano/
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Transcript of 1 Absolute Pressure Sensors Z. Celik-Butler, D. Butler and M. Chitteboyina Nanotechnology Research...
1
Absolute Pressure SensorsAbsolute Pressure Sensors
Z. Celik-Butler, D. Butler
and M. ChitteboyinaNanotechnology Research and Teaching Facility
University of Texas at Arlingtonhttp://www.uta.edu/engineering/nano/
Absolute Pressure Sensor Model in CoventorWare
Cavity
Flexible superstrate
Flexible substrate
Sealed Pressure SensorWheatstone Bridge
Configuration
Bond Pads
Stress, Strain and Displacement simulations for the pressure sensor
is currently on-going
0.14cm x 0.14cm
Clean silicon wafer
Fabrication Process Flow for the Absolute Pressure Sensor
40 µm flexible polyimide substrate
Fabrication Process Flow for the Absolute Pressure Sensor
Insulation layer 0.5 µm
Fabrication Process Flow for the Absolute Pressure Sensor
Thick polyimide sacrificial layer 2.5 µm
Fabrication Process Flow for the Absolute Pressure Sensor
Thin polyimide sacrificial layer 0.5 µm
Fabrication Process Flow for the Absolute Pressure Sensor
Membrane layer 1µm
Etch holes
Fabrication Process Flow for the Absolute Pressure Sensor
Piezoresistors 0.5 µm
Fabrication Process Flow for the Absolute Pressure Sensor
Aluminum metallization 0.5 µm
Fabrication Process Flow for the Absolute Pressure Sensor
Encapsulant layer 0.5 µm
Bond pads
Etch holes
Fabrication Process Flow for the Absolute Pressure Sensor
Release both the sacrificial layers
Release both the sacrificial layers
Cavity
cross-section
Fabrication Process Flow for the Absolute Pressure Sensor
Deposit final sealing layer 0.6 µm
Bond padscross-section
Cavity
Fabrication Process Flow for the Absolute Pressure Sensor
Bond pads
Spin coat 40 µm flexible polyimide superstrate
Fabrication Process Flow for the Absolute Pressure Sensor
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Absolute Pressure Sensor ResultsSensor A (0.0 – 2.0 psi)
DISPLACEMENT PLOTSTRAIN YY PLOT STRAIN XX PLOTMISES STRESS PLOT
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STRAIN YY PLOT STRAIN XX PLOT
Absolute Pressure Sensor DesignSensor H (14.0 – 16.0 psi)
DISPLACEMENT PLOTMISES STRESS PLOT
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Absolute Pressure Sensor Fabrication Steps
STEP 1 On a clean wafer spin-coat ~ 40 µm flexible polyimide as the substrate layer followed by 600 nm passivation layer
STEP 2 Spin coat thick polyimide and cure
STEP 3
STEP 4
NEXT STEPS Deposit ~ 500 nm thick aluminum as the metallization layer
Ash the sacrificial layer using oxygen plasma to suspend the membrane
Deposit 0.5 µm encapsulation layer followed by 0.5 µm as the final sealing layer
Etch the silicon wafer from the back side to get access to the bond pads and characterize the absolute pressure sensors
Piezoresistors ~ 25 nm
Passivation layer ~ 600 nm
membrane layer ~ 0.1 µm
Thick Sacrificial layer ~ 7 µm
Spin coat thin polyimide and cure
Deposit 0.1 µm membrane layer
STEP 5 Deposit ~ 25 nm piezoresistor layer
Thin Sacrificial layer ~ 0.5 µm
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Absolute Pressure Sensor Fabrication Steps
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Absolute Pressure Sensor Characterization
1 2 3 4Vout Vin Vout Vin
R1
R2 R3
R4
Vin Vout
R1
R3R2 R4
The electrical circuit is complete with two active piezoresistors (R1 and R3) and two passive piezoresistors (R2 and R4) in a Wheatstone bridge configuration
The current-voltage characteristics is plotted and the true resistances are found
Pressure is applied on top of the membrane and the change in output voltage vs. input voltage is plotted
