Let be an almost complex manifold with almost complex structure. Let be a smooth Riemann surface with complex structure. A pseudoholomorphic curve in is a map that satisfies the Cauchy–Riemann equation Since, this condition is equivalent to which simply means that the differential is complex-linear, that is, maps each tangent space to itself. For technical reasons, it is often preferable to introduce some sort of inhomogeneous term and to study maps satisfying the perturbed Cauchy–Riemann equation A pseudoholomorphic curve satisfying this equation can be called, more specifically, a -holomorphic curve. The perturbation is sometimes assumed to be generated by a Hamiltonian, but in general it need not be. A pseudoholomorphic curve is, by its definition, always parametrized. In applications one is often truly interested in unparametrized curves, meaning embedded two-submanifolds of, so one mods out by reparametrizations of the domain that preserve the relevant structure. In the case of Gromov–Witten invariants, for example, we consider only closed domains of fixed genus and we introduce marked points on. As soon as the punctured Euler characteristic is negative, there are only finitely many holomorphic reparametrizations of that preserve the marked points. The domain curve is an element of the Deligne–Mumford moduli space of curves.
The classical case occurs when and are both simply the complex number plane. In real coordinates and where. After multiplying these matrices in two different orders, one sees immediately that the equation written above is equivalent to the classical Cauchy–Riemann equations
Although they can be defined for any almost complex manifold, pseudoholomorphic curves are especially interesting when interacts with a symplectic form. An almost complex structure is said to be -tame if and only if for all nonzero tangent vectors. Tameness implies that the formula defines a Riemannian metric on. Gromov showed that, for a given, the space of -tame is nonempty and contractible. He used this theory to prove a non-squeezing theorem concerning symplectic embeddings of spheres into cylinders. Gromov showed that certain moduli spaces of pseudoholomorphic curves are compact, and described the way in which pseudoholomorphic curves can degenerate when only finite energy is assumed. . This Gromov compactness theorem, now greatly generalized using stable maps, makes possible the definition of Gromov–Witten invariants, which count pseudoholomorphic curves in symplectic manifolds. Compact moduli spaces of pseudoholomorphic curves are also used to construct Floer homology, which Andreas Floer used to prove the famous conjecture of Vladimir Arnol'd concerning the number of fixed points of Hamiltonian flows.
Applications in physics
In type II string theory, one considers surfaces traced out by strings as they travel along paths in a Calabi–Yau 3-fold. Following the path integral formulation of quantum mechanics, one wishes to compute certain integrals over the space of all such surfaces. Because such a space is infinite-dimensional, these path integrals are not mathematically well-defined in general. However, under the A-twist one can deduce that the surfaces are parametrized by pseudoholomorphic curves, and so the path integrals reduce to integrals over moduli spaces of pseudoholomorphic curves, which are finite-dimensional. In closed type IIA string theory, for example, these integrals are precisely the Gromov–Witten invariants.
