# Paul S. Aspinwall

## Professor

## Details

** Topological D-Branes and Commutative Algebra
**

Communications in Number Theory and Physics
(2009)

** D-Branes on Toric Calabi-Yau Varieties
**

(2008)

** The Landau-Ginzburg to Calabi-Yau Dictionary for D-Branes
**

J.Math.Phys.
(2007)

** Black Hole Entropy, Marginal Stability and Mirror Symmetry
**

J. High Energy Phys.
(2007)

** The Landau-Ginzburg to Calabi-Yau Dictionary for D-Branes
**

J. Math. Phys.
(2007)

** Computation of Superpotentials for D-Branes
**

Commun. Math. Phys.
(2006)

** Superpotentials for Quiver Gauge Theories
**

J. High Energy Phys.
(2006)

** An Analysis of Fluxes by Duality
**

(2005)

** Massless D-Branes on Calabi-Yau Threefolds and Monodromy
**

Commun. Math. Phys.
(2005)

** Fixing all Moduli for M-Theory on K3xK3.
**

J. High Energy Phys.
(2005)

String theory is hoped to provide a theory of all fundamental physics encompassing both

quantum mechanics and general relativity. String theories naturally live in a large number of

dimensions and so to make contact with the real world it is necessary to ``compactify'' the

extra dimensions on some small compact space. Understanding the physics of the real

world then becomes a problem very closely tied to understanding the geometry of the space

on which one has compactified. In particular, when one restricts one's attention to

``supersymmetric'' physics the subject of algebraic geometry becomes particularly important.

Of current interest is the notion of ``duality''. Here one obtains the same physics by

compactifying two different string theories in two different ways. Now one may use our limited understanding of one

picture to fill in the gaps in our limited knowledge of the second picture. This appears to be an extremely powerful

method of understanding a great deal of string theory.

Both mathematics and physics appear to benefit greatly from duality. In mathematics one finds hitherto unexpected

connections between the geometry of different spaces. ``Mirror symmetry'' was an example of this but many more

remain to be explored. On the physics side one hopes to obtain a better understanding of nonperturbative aspects

of the way string theory describes the real world.

**Education:**

Ph.D. - University of Oxford (UK)

B.A. - University of Oxford (UK)

**2001**Langford Lecture, Duke

**1999**Alfred P. Sloan Fellowship, Alfred P. Sloan Foundadtion

**1999**Sloan Research Fellowship-Physics, Alfred P. Sloan Foundation

**1998**Invited Talk at ICM, ICM