Amorphous and polycrystalline microwires cast from ferromagnetic Fe-based or Co-based alloys
in glass envelope demonstrate unique magneto-anisotropic and high frequency impedance properties that
make them very attractive for sensor applications. Magnetic anisotropies of different types result from the
inverse magnetostriction effect (positive or negative) at the interface between the glass shell and the metal
core, in the presence of the residual stresses induced during the Taylor-Ulitovski casting method. Therefore,
the glass shell is not just isolation, but also is one of most important factors that defines the physical
properties of microwires. In particular, magnetic anisotropy allows high frequency impedance to be tuned
by external stimuli such as magnetic field, tensile stress, or temperature. In the project, these effects are
explored for the creation of low density microwire inclusions that might introduce tuneable microwave
properties to polymer composite materials.
The project aims to study high frequency impedance effects in ferromagnetic wires in the presence
of tensile stress, temperature, and magnetic field. The integration of microwave equipment with mechanical
and thermal measurement facilities is a very challenging task. In the project, we develop new experimental
techniques allowing comprehensive study of composite materials with electromagnetic functionalities. The
wire surface impedance recovered from such measurements can then be used to model the microwave
response from wire-filled composites in free space. The obtained results significantly expand the horizon
of potential applications of ferromagnetic wires for structural health monitoring
Date of Award | 2017 |
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Original language | English |
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Awarding Institution | |
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Supervisor | John Summerscales (Other Supervisor) |
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- Non-Destructive Testing
- Smart Materials
- Impedance
- Magnetic Anisotropy
- Ferromagnetic Microwire
- Magnetostriction Effect
- Skin Effect
- Antenna Equation
- S-parameters
- Vector Network Analyser
- Network Calibration
COMPOSITE MATERIALS FILLED WITH FERROMAGNETIC MICROWIRE INCLUSIONS DEMONSTRATING MICROWAVE RESPONSE TO TEMPERATURE AND TENSILE STRESS
Zamorovskii, V. (Author). 2017
Student thesis: MPhil