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Slideshow

11th Annual Cantrell Lectures

Roger Penrose
Physics, Room 202
Roger Penrose
Oxford University

Monday, May 2, 2005

4:00p.m., Physics Bldg., Room 202

Basic Twistor Geometry; Physical Motivations

Twistor theory is motivated by the idea that the union between space-time structure and quantum-mechanical principles may well involve non-standard quantization procedures. Two guiding principles underlying the twistor approach are holomorphicity (complex analyticity) and non-locality, these seeming to be features that an appropriate "quantized space-time" ought to have. In this lecture, I shall concentrate on the basic twistor geometry, in which space-time ideas are translated into a very

different-looking geometrical picture, this having close connections to some well-known classical geometry.

Tuesday, May 3, 2005

4:00p.m., Boyd Graduate Studies, Room 328

Twistor Cohomology and linear Physical Fields

Abstract: Massless physical field equations (such as the wave equation, Maxwell's equations, the linearized Einstein gravitational field, and the massless neutrino equation) find a remarkable translation into twistor terms; they are represented as elements of holomorphic sheaf cohomology. Such cohomology groups have for many years had important roles to play in complex-manifold

theory; now we see that they play an important role, also, in the description of basic physical fields.

Wednesday, May 4, 2004

4:00p.m., Boyd Graduate Studies, Room 328

Non-Linear Fields and Googlies; a New Input from String Theory?

Abstract: Some of these constructions have non-linear versions, and these lead to twistor solutions to the problem of finding anti-self-dual solutions of the Einstein vacuum equations (Ricci-flatness) and the Yang-Mills equations, relevant to strong and weak interactions. But we also need to see how to solve the self-dual versions of these equations, which has been termed the "googly problem", and this has proved remarkably resistant to any coherent mathematical treatment. Some recent new input has come from an unexpected source, starting with a 100-page paper by Edward Witten, in December 2003. I shall try to address the role of these new ideas.

Refreshments will be served at 3:30p.m. preceding each lecture.

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