A novel microfluidic pressure sensor which can be fully integrated into polydimethylsiloxane (PDMS) is reported. The sensor produces electrical signals directly. We integrated PDMS-based conductive composites into a 30μm thick membrane and bonded it to the microchannel side wall. The response time of the sensor is approximately 100 ms and can work within a pressure range as wide as 0–100 kPa. The resolution of this micropressure sensor is generally 0.1 kPa but can be increased to 0.01 kPa at high pressures as a result of the quadratic relationship between resistance and pressure. The PDMS-based nature of the sensor ensures its perfect bonding with PDMS chips, and the standard photolithographic process of the sensor allows one-time fabrication of three dimensional structures or even microsensor arrays. The theoretical calculations are in good agreement with experimental observations.

1.
S. K.
Sia
and
G. M.
Whitesides
,
Electrophoresis
24
,
3563
(
2003
).
2.
E.
Leclerc
,
Y.
Sakai
, and
T.
Fujii
,
Biomed. Microdevices
5
,
109
(
2003
).
3.
A. J.
DeMello
,
Nature (London)
442
,
394
(
2006
).
4.
J. W.
Hong
and
S. R.
Quake
,
Nat. Biotechnol.
21
,
1179
(
2003
).
5.
Y.
Luo
,
Q.
Zhang
,
J.
Qin
, and
B.
Lin
,
Electrophoresis
28
,
4769
(
2007
).
6.
X.
Niu
,
M.
Zhang
,
S.
Peng
,
W.
Wen
, and
P.
Sheng
,
Biomicrofluidics
1
,
044101
(
2007
).
7.
B.
Li
,
L.
Jiang
,
Q.
Wang
,
J.
Qin
, and
B.
Lin
,
Electrophoresis
29
,
4906
(
2008
).
8.
M.
Akiyama
,
Y.
Morofuji
,
T.
Kamohara
,
K.
Nishikubo
,
M.
Tsubai
,
O.
Fukuda
, and
N.
Ueno
,
J. Appl. Phys.
100
,
114318
(
2006
).
9.
K.
Arshak
,
D.
Morris
,
A.
Arshak
,
O.
Korostynska
, and
K.
Kaneswaran
,
Conference Proceedings of the ISSE 2006 - 29th International Spring Seminar on Electronics Technology: Nano Technologies for Electronics Packaging
,
2006
(unpublished), Vol.
334
.
10.
K. I.
Arshak
,
D.
Morris
,
A.
Arshak
,
O.
Korostynska
, and
E.
Jafer
,
IEEE Sens. J.
7
,
122
(
2007
).
11.
G.
Schweeger
,
C.
Lang
,
K.
Fricke
,
H. L.
Hartnagel
,
R.
Dolt
, and
G.
Hohenberg
,
Electron. Lett.
30
,
1355
(
1994
).
12.
Y. -H.
Wang
,
C. -P.
Chen
,
C. -M.
Chang
,
C. -P.
Lin
,
C. -H.
Lin
,
L. -M.
Fu
, and
C. -Y.
Lee
,
Microfluid. Nanofluid.
6
,
333
(
2009
).
13.
O. J. A.
Schueller
,
D. C.
Duffy
,
J. A.
Rogers
,
S. T.
Brittain
, and
G. M.
Whitesides
,
Sens. Actuators, A
78
,
149
(
1999
).
14.
J. A.
Rogers
,
D.
Qin
,
O. J. A.
Schueller
, and
G. M.
Whitesides
,
Rev. Sci. Instrum.
67
,
3310
(
1996
).
15.
K.
Hosokawa
,
K.
Hanada
, and
R.
Maeda
,
J. Micromech. Microeng.
12
,
1
(
2002
).
16.
X.
Niu
,
S.
Peng
,
L.
Liu
,
W.
Wen
, and
P.
Sheng
,
Adv. Mater.
19
,
2682
(
2007
).
17.
X.
Gong
and
W.
Wen
,
Biomicrofluidics
3
,
012007
(
2009
).
18.
L.
Liu
,
W.
Cao
,
J.
Wu
,
W.
Wen
,
D. C.
Chang
, and
P.
Sheng
,
Biomicrofluidics
2
,
034103
(
2008
).
19.
N.
Bao
,
J.
Wang
, and
C.
Lu
,
Anal. Bioanal. Chem.
391
,
933
(
2008
).
20.
Z.
Long
,
Z.
Shen
,
D.
Wu
,
J.
Qin
, and
B.
Lin
,
Lab Chip
7
,
1819
(
2007
).
21.
M. A.
Eddings
,
M. A.
Johnson
, and
B. K.
Gale
,
J. Micromech. Microeng.
18
,
067001
(
2008
).
22.
L.
Flandin
,
A.
Chang
,
S.
Nazarenko
,
A.
Hiltner
, and
E.
Baer
,
J. Appl. Polym. Sci.
76
,
894
(
2000
).
23.
J.
Lu
,
W.
Weng
,
X.
Chen
,
D.
Wu
,
C.
Wu
, and
G.
Chen
,
Adv. Funct. Mater.
15
,
1358
(
2005
).
24.
W.
Hu
,
L.
Zhao
,
L.
Wu
,
L.
Wang
,
B.
Zhang
, and
H.
Guan
,
J. Appl. Phys.
79
,
866
(
1996
).
25.
S. A.
Mansour
,
Express Polymer Letters
2
,
836
(
2008
).
26.
P.
Guha
and
P.
Shipman
,
Chaos, Solitons Fractals
,
41
,
2828
(
2008
).
You do not currently have access to this content.