Extraordinary magnetoresistance: sensing the future
journal contribution
posted on 2013-07-11, 13:07authored byThomas H. Hewett, Feodor Kusmartsev
Simulations utilising the finite element method (FEM) have been produced in order to investigate aspects
of circular extraordinary magnetoresistance (EMR) devices. The effect of three specific features on the
resultant magnetoresistance were investigated: the ratio of the metallic to semiconducting conductivities
( M/ S); the semiconductor mobility; and the introduction of an intermediate region at the semiconductormetal
interface in order to simulate a contact resistance. In order to obtain a large EMR effect the conductivity
ratio ( M/ S) is required to be larger than two orders of magnitude; below this critical value the resultant
magnetoresistance effect is dramatically reduced. Large mobility semiconductors exhibit larger EMR values
for a given field (below saturation) and reduce the magnetic field required to produce saturation of the
magnetoresistance. This is due to a larger Hall angle produced at a given magnetic field and is consistent
with the mechanism of the EMR effect. Since practical magnetic field sensors are required to operate at
low magnetic fields, high mobility semiconductors are required in the production of more sensitive EMR
sensors. The formation of a Schottky barrier at the semiconductor-metal interface has been modelled with
the introduction of a contact resistance at the semiconductor-metal interface. Increasing values of contact
resistance are found to reduce the EMR effect with it disappearing altogether for large values. This has
been shown explicitly by looking at the current flow in the system and is consistent with the mechanism
of the EMR effect. The interface resistance was used to fit the simulated model to existing experimental
data. The best fit occurred with an interface with resistivity of 1.55×10−4
m (overestimate). The EMR
effect holds great potential with regard to its future application to magnetic field sensors. The design of any
such devices should incorporate high mobility materials (such as graphene) along with the specific features
presented in this paper in order to produce effective magnetic field sensors.
History
School
Science
Department
Physics
Citation
HEWETT, T.H. and KUSMARTSEV, F.V., 2012. Extraordinary magnetoresistance: sensing the future. Central European Journal of Physics, 10 (3), pp. 1 - 7