homework: resemble the case of trapezoid cross section in page 47-48, try to calculate the moment of...
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Homework:
Resemble the case of trapezoid cross section in Page 47-48, try to calculate the moment of inertia of a “T”-shaped cross-sectional beam
a1
a2
b1
b2
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Review of important formulas for bending stress and strain of a beam
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Uniform acceleration
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How about a double-clamped beam with self-weight loading?
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Analysis and design rule of the beam bending problem
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Cantilever can be used not only for mechanical sensors and probes, but also for bio/chemical sensors
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1.1. How Cantilever as a Sensing Platform?
Cantilever-mass micromachining structures have been long-period used in MEMS inertial sensors: Accelerometers and Gyroscopes, etc.
Piezoresistor embedded axial beams
Reference resistors
Bending cantilever beam
Mass legs
Seismic mass
a
Comb damper
S. Huang, Xinxin Li, Transducers’03
Xinxin Li, M. Bao, Transducers’99
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• In an inertial sensor, the spring deformation is forced by a seismic mass, i.e. a bulk effect
• In a bio/chemical sensing cantilever, the seismic mass is no use but surface effect becomes to work
Antibodies with bacteria
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What causes this change?
Different sensing mechanism for bio/chemicals
Bio/Chemical Physical Informatics
Analyte Circuit Recognizing
materials Transducers Signal
Electrochemical: Amperometer, Potentiometer, I SFET, …
Thermal: Calorimeters, DSC…
Mass or Mechanical: SAW, QCM, Cantilever, …
Optical: I nterferometer, Spectrometer, SPR, …
…
Signal
Processing
Circuit
Enzymatic
Microbial / Cell
Immunological
DNA
Organic
…
Two sensing interfaces: both contribute to sensitivity/selectivity in different ways
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Science, 1997 by IBM Zurich reported that self-assembly of SAM on Au surface generates nano-mechanical surface-stress that was measured by a micro-cantilever and signal read out by an AFM photonic detector.
Although studies have tried to find the origin of surface-stress generation, the molecule-level mechanism on the self-assembly induced surface-stress is still ambiguous.
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During the chemical sensing experiment in last section, using ammonia to replace the tri-methylamine vapor in the experiment results in no significant frequency-shift measured. Though their chemical principles are similar, apparently the size of the ammonia molecule is much smaller than that of the tri-methylamine.
Thus, the mechanism of surface-stress generation during specific molecules binding on a solid surface is strongly dependent of the molecule size or other principles.
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1.2. Why Cantilever Promising for Bio/Chemical Detection?
(1) Static cantilever for specific-reaction-induced surface-stress sensing
“Translating Bio-molecular Recognition into Nano-mechanics”
Science 288 (2000) by IBMP. Li, Xinxin Li, APL 2000
Single DNA hybridization recognizedSub-nanometer bending is self-sensed
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Proxi-Lever with thiol-SAM of 6MNA on Au surface for 20ppt-resoluble trace TNT detection
S S S S S
Cu2+
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
Si
O
OSi
O
OSi
O
O
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
Si
O
O
SS
Cu2+Cu2+Cu2+Cu2+Cu2+
Sens. cant.
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
Si
O
OSi
O
OSi
O
O
CF2F2C
CF2F2C
CF2F2C
CF2F2C
CF3
Si
O
O
CF2
F2CCF2
F2CCF2
F2CCF2
F2CCF3
CF2
F2CCF2
F2CCF2
F2CCF2
F2CCF3
CF2
F2CCF2
F2CCF2
F2CCF2
F2CCF3
Si
O
O Si
O
O Si
O
O
CF2
F2CCF2
F2CCF2
F2CCF2
F2CCF3
Si
O
O
Ref. Cant.
SiO2 surface
SiO2 surface
Au surface
P. Li, Xinxin Li, et al, APL 2006 and JMM 2007
0 5 10 15 20 25
0
20
40
60
80
100
95%
74%
51%
33%Res
pons
e vo
ltage
(V
)
Time (min)
SiO2 surface w/o FAS-17 modification
SiO2 surface modifed with FAS-17
11%
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Sensing Canti.
Sensing Canti.
0 5 10 15 20 25 30
-12
-10
-8
-6
-4
-2
0
2
Resp
on
e V
olt
ag
e(V
)
Time(min)
quad-cantilever sensor
Siloxane-head bi-layer modified on SiO2 surface for long life-time TNT detection
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How to design the static cantilever for specific-reaction induced surface-stress
Stoney’s equation:
sEt
Lz
2
2 )1(3
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When the cantilever is bent by uniformly distributed loading surface stressσs, the free-end bending moment is M=Δσst/2, where w is the cantilever width.
eff
ns
eff EI
wh
EI
M
R )(
1
)))(12/(1
()( 23niii
i
i
ieff hhttE
wEI
i i iiiiin tEthEh )/()(
the radius of the deflective cantilever, R, can be expressed as
and
.
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The bending stress at the piezoresistive layer can be expressed is
RhhE tnsi
1)(
where Esi is Young’s module of silicon, ht is the distance between the upper s
urface of the cantilever and the piezoresistor layer.
represents the mechanical sensitivity of the piezoresistive cantilever
( )
( )si n n t
s eff
E h h h
EI
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How to know the surface-stress value induced by a certain specific molecule binding? Only be experimental results? Is there and design model?
By now no people in the world knows it in details? You can try and publish the results in Science or Nature
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Top down
Bottom upCombination
Atomic behavior Continuum mechanismSeamless coupling
Bio-molecule
Nano
Informatics BNIFusion
Key points for micro-nano compatible cantilevers:
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Bio-Nano Binding Nano-Micro CouplingBio-Nano-Informatics (BNI) Fusion
Road map for recent work
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In farther future … …
“There's plenty of room at the bottom” (R. P. Feynman)