NEXT STORY
Trying to build a strong group
RELATED STORIES
NEXT STORY
Trying to build a strong group
RELATED STORIES
Views | Duration | ||
---|---|---|---|
71. Interaction between maths and physics | 999 | 02:14 | |
72. Simon Donaldson | 1614 | 02:40 | |
73. Symplectic geometry | 870 | 01:03 | |
74. Geometry, physics and the future of mathematics | 1238 | 04:08 | |
75. Cambridge in 1990 | 662 | 01:17 | |
76. The Isaac Newton Institute | 576 | 03:17 | |
77. Opposition to the Isaac Newton Institute | 700 | 02:02 | |
78. British mathematics | 695 | 03:15 | |
79. Trying to build a strong group | 1 | 642 | 01:38 |
80. The future of mathematics | 1132 | 03:55 |
The whole world is always on an exponential growth. You know, when I was starting off the... the number of universities was... was small, there were very few jobs, you know, the number of students would be smaller; so the number of people active in the mathematical thing would have been much less, both here and internationally. So... so obviously now there's much more activity, many more people, many more universities. Probably in terms of the number of really top level people, you know, doing frontier work and really pushing the thing forward, that may not be so much different. I mean I suspect it's not, but each of the people in that position probably have larger groups working with them, and so the total body of work is greater. And again there's... there’s the… the scenes shift, you know, the… or the current activities at any given moment, where the action is, change and it's... it’s moved, you know, areas from what it was probably when I was… although Cambridge, and to some extent… strength was traditionally in number theory. On the one hand with Hardy and Littlewood and others, and Mordell and so on; and in classical algebraic geometry with the Baker school and then with Hodge, and so in some sense those two strands are still... still there.
I think there's a kind of continuity in, you know, what you might call national cultural strengths which are very long-lived, you know, because you train people in your... your own image or your own field, they go on to do… perpetuate the system and there's a tremendous built-in reservoir of expertise. And so there's a natural tendency for countries to remain strong in their fields for probably hundreds of years. It's very difficult to change, unless you're in a place like the United States where everybody's always on the move and you can create departments out of nothing. But in... in Europe I think you'll find that traditions in this country and in France and in Germany… in Germany, of course, had the terrible upheaval of the Second World War, but despite that the traditional strengths of Germany are to some extent still present and they're... they’re deeply embedded in... in the culture. So that is really quite surprising.
So I think we're still strong in the things we were strong, even though the subjects have moved on, and they no longer solve the same problems, but there're still major areas and lots of activity going on. So I think the… I would say that the strength of British mathematics… of course when I was starting it was just shortly after the war and, you know, people were picking up the pieces, so it was still the reputation of the pre-war generation that was there, so one had to get restarted again. But it's... it’s probably as good as it was in... in international comparative terms as it used to be; hard to say whether it's any better. Standards have risen, I mean there's more... more countries to compete with, but I think it's kept its... it’s kept its place, I would say, in... in the areas where it, you know, always was strong and doing... doing good work.
Eminent British mathematician Sir Michael Atiyah (1929-2019) broke new ground in geometry and topology with his proof of the Atiyah-Singer Index Theorem in the 1960s. This proof led to new branches of mathematics being developed, including those needed to understand emerging theories like supergravity and string theory.
Title: British mathematics
Listeners: Nigel Hitchin
Professor Nigel Hitchin, FRS, is the Rouse Ball Professor of Mathematics and Fellow of Gonville and Caius College, Cambridge, since 1994, and was appointed to the Savilian Professorship of Geometry in October 1997. He was made a Fellow of the Royal Society in 1991 and from 1994 until 1996 was President of the London Mathematical Society.
His research interests are in differential and algebraic geometry and its relationship with the equations of mathematical physics. He is particularly known for his work on instantons, magnetic monopoles, and integrable systems. In addition to numerous articles in academic journals, he has published "Monopoles, Minimal Surfaces and Algebraic Curves" (Presses de l'Universite de Montreal, 1987) and "The Geometry and Dynamics of Magnetic Monopoles" (Princeton University Press, 1988, with Michael Atiyah).
Tags: Cambridge, France, Germany, Godfrey Hardy, John Littlewood, Louis Mordell, William Hodge, Alan Baker
Duration: 3 minutes, 16 seconds
Date story recorded: March 1997
Date story went live: 24 January 2008