Sea ice plays a key role in the global climate system. Indeed, through the albedo
effect it reflects significant solar radiation away from the oceans, while it also plays a
key role in the momentum and heat transfer between the atmosphere and ocean by
acting as an insulating layer between the two. Furthermore, as more sea ice melts due
to climate change, additional fresh water is released into the upper oceans, affecting
the global circulation of the ocean as a whole. While there has been significant effort
in recent decades, the ability to simulate sea ice has lagged behind other components
of the climate system and most Earth System Models fail to capture the observed
losses of Arctic sea ice, which is largely attributed to our inability to resolve sea
ice dynamics. The most widely accepted model for sea ice dynamics is the Viscous-
Plastic (VP) rheology, which leads to a very non-linear set of partial differential
equations that are known to be intrinsically difficult to solve numerically. This work
builds on recent advances in solving these equations with a Jacobian-Free Newton-
Krylov (JFNK) solver. We present an improved JFNK solver, where a fully second
order discretization is achieved via the Crank Nicolson scheme and consistency is
improved via a novel approach to the rheology term. More importantly, we present a
significant improvement to the Jacobian approximation used in the Newton iterations,
and partially form the action of the matrix by expressing the linear and nearly linear
terms in closed form and approximating the remaining highly non-linear term with
a second order approximation of its Gateaux derivative. This is in contrast with the
previous approach which used a first order approximation for the Gateaux derivative
of the whole functional. Numerical tests on synthetic equations confirm the theoretical
convergence rate and demonstrate the drastic improvements seen by using a second
order approximation in the Gateaux derivative. To produce a fast and efficient solver
for VP sea ice dynamics, the improved JFNK solver is then coupled with a non-
oscillatory, central differencing scheme for transporting sea ice as well as a novel
method for tracking the ice domain using a level set method. Two idealized test
cases are then presented and simulation results discussed, demonstrating the solver’s
ability to efficiently produce Viscous-Plastic, physically motivated solutions. / Graduate
Identifer | oai:union.ndltd.org:uvic.ca/oai:dspace.library.uvic.ca:1828/8630 |
Date | 04 October 2017 |
Creators | Seinen, Clint |
Contributors | Khouider, Boualem |
Source Sets | University of Victoria |
Language | English, English |
Detected Language | English |
Type | Thesis |
Format | application/pdf |
Rights | Available to the World Wide Web |
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