Until now, the planar Hall effect has been studied in samples with cross-shaped Hall geometry. We demonstrate theoretically and experimentally that the planar Hall effect can be observed for an exchange-biased ferromagnetic material in a Wheatstone bridge topology and that the sensor signal can be significantly enhanced by a geometric factor. For the samples in the present study, we demonstrate an enhancement of the sensor output by a factor of about 100 compared to cross-shaped sensors. The presented construction opens a new design and application area of the planar Hall effect, which we term planar Hall effect bridge sensors.

1.
F.
Montaigne
,
A.
Schuhl
,
F.
Nguyen Van Dau
, and
A.
Encinas
,
Sens. Actuators A
81
,
324
(
2000
).
2.
L.
Ejsing
,
M. F.
Hansen
,
A. K.
Menon
,
H. A.
Ferreira
,
D. L.
Graham
, and
P. P.
Freitas
,
Appl. Phys. Lett.
84
,
4729
(
2004
).
3.
C. D.
Damsgaard
,
S. C.
Freitas
,
P. P.
Freitas
, and
M. F.
Hansen
,
J. Appl. Phys.
103
,
07A302
(
2008
).
4.
C. D.
Damsgaard
,
B. T.
Dalslet
,
S. C.
Freitas
,
P. P.
Freitas
, and
M. F.
Hansen
,
Sens. Actuators A
156
,
103
(
2009
).
5.
T. Q.
Hung
,
S.
Oh
,
S.
Anandakumar
,
J. -R.
Jeong
,
D. -Y.
Kim
, and
C.
Kim
,
IEEE Trans. Magn.
45
,
4518
(
2009
).
6.
T. Q.
Hung
,
S.
Oh
,
J. -R.
Jeong
, and
C.
Kim
,
Sens. Actuators A
157
,
42
(
2010
).
You do not currently have access to this content.