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Phyllis Nicolson

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21 Sept 1917

Macclesfield, England

6 Oct 1968

Sheffield, England

Presentation Wikipedia
Phyllis Nicolson's maiden name was Lockett. She was educated at Stockport High School and received the degrees of B.Sc. (1938) and M.Sc. (1939) and Ph.D. in Physics (1946) from Manchester University and was a research student (1945-46) and research fellow (1946-49) at Girton College, Cambridge. In 1942 she married Malcolm Nicolson. She had a strong wish to have her first child before reaching thirty, and she achieved this ambition with a day to spare. After her husband's untimely death in a train crash in 1952, she was appointed to fill his lectureship in Physics at Leeds University. In 1956 she married Malcolm McCaig, who was also a physicist.

During the period 1940-45 she was a member of a research group in Manchester University directed by Douglas Hartree , working on wartime problems for the Ministry of Supply, one being concerned with magnetron theory and performance. Phyllis Nicolson is best known for her joint work with John Crank on the heat equation, where a continuous solution u(x, t) is required which satisfies the second order partial differential equation

ut - uxx = 0

for t > 0, subject to an initial condition of the form u(x, 0) = f(x) for all real x. They considered numerical methods which find an approximate solution on a grid of values of x and t, replacing ut(x, t) and uxx(x, t) by finite difference approximations. One of the simplest such replacements was proposed by L F Richardson in 1910. Richardson 's method yielded a numerical solution which was very easy to compute, but alas was numerically unstable and thus useless. The instability was not recognised until lengthy numerical computations were carried out by Crank , Nicolson and others. Crank and Nicolson's method, which is numerically stable, requires the solution of a very simple system of linear equations (a tridiagonal system) at each time level.

Source:School of Mathematics and Statistics University of St Andrews, Scotland