The Low Frequency Electrical Properties of Sea Ice

This thesis summarises an experimental and theoretical study of the low frequency electrical properties of sea ice. The aim of the research was to first demonstrate, and then gain a physical understanding of, the microstructural dependence of a sea ice impedance measurement. In particular, we sought...

Full description

Bibliographic Details
Main Author: Buchanan, Sean Thomas
Format: Thesis
Language:unknown
Published: 2010
Subjects:
Earth Sciences not elsewhere classified
Sea ice
Electrical
Microstructure
School: School of Chemical and Physical Sciences
049999 Earth Sciences not elsewhere classified
Marsden: 260203 Electromagnetism
Marsden: 249903 Instruments and Techniques
Marsden: 260403 Physical Oceanography
Marsden: 240504 Electrostatics and Electrodynamics
Degree Discipline: Physics
Degree Level: Masters
Degree Name: Master of Science
Marsden
Online Access:https://doi.org/10.26686/wgtn.16972213.v1
https://figshare.com/articles/thesis/The_Low_Frequency_Electrical_Properties_of_Sea_Ice/16972213
Description
Summary:This thesis summarises an experimental and theoretical study of the low frequency electrical properties of sea ice. The aim of the research was to first demonstrate, and then gain a physical understanding of, the microstructural dependence of a sea ice impedance measurement. In particular, we sought to realise how the effective electrical properties of the medium depended on the volume fraction, orientation, dimensions, and connectivity of the dispersed brine phase. The experimental portion of the project was performed on laboratory grown, artificial sea ice. We monitored the variation with time, and temperature, of the broadband sea ice impedance using four-electrode measurement cells embedded within the ice. The four-electrode measurement allowed us to realise and eliminate the contribution of electrode polarization to the measured impedance. By representing the electrical response of sea ice as a complex conductivity, we formulated a broadband physical model to describe the medium. The model distinguished bulk conduction, bulk polarization, and interfacial polarization. A complex non-linear least squares fitting procedure revealed the individual contribution of these physical processes and we studied their variation with temperature. We found that the bulk material underwent a dielectric relaxation with activation energy Ea = 0.20 + and - 0.04eV. We linked the bulk material properties with a two phase microstructural model, with realistic input parameters.

Similar Items