Clifford Henry Taubes scite author profile

Clifford Henry Taubes

5Publications

1,845Citation Statements Received

99Citation Statements Given

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1,479

1,794

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Affiliations

Harvard University, Harvard University Press, University of California, Berkeley

Publications

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ArbitraryN-vortex solutions to the first order Ginzburg-Landau equations

Taubes

1980

Commun.Math. Phys.

401

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We prove that a set of N not necessarily distinct points in the plane determine a unique, real analytic solution to the first order Ginzburg-Landau equations with vortex number N. This solution has the property that the Higgs field vanishes only at the points in the set and the order of vanishing at a given point is determined by the multiplicity of that point in the set. We prove further that these are the only C°° solutions to the first order Ginzburg-Landau equations.

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On the self-linking of knots

1994

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This note describes a subcomplex F of the de Rham complex of parametrized knot space, which is combinatorial over a number of universal ‘‘Anomaly Integrals.’’ The self-linking integrals of Guadaguini, Martellini, and Mintchev [‘‘Perturbative aspects of Chern–Simons field theory,’’ Phys. Lett. B 227, 111 (1989)] and Bar-Natan [‘‘Perturbative aspects of the Chern–Simons topological quantum field theory,’’ Ph.D. thesis, Princeton University, 1991; also ‘‘On the Vassiliev Knot Invariants’’ (to appear in Topology)] are seen to represent the first nontrivial element in H0(F)—occurring at level 4, and are anomaly free. However, already at the next level an anomalous term is possible.

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The Seiberg-Witten invariants and symplectic forms

Taubes

1994

389

354

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Recently, Seiberg and Witten (see [SW1], [SW2], [W]) introduced a remarkable new equation which gives differential-topological invariants for a compact, oriented 4-manifold with a distinguished integral cohomology class. A brief mathematical description of these new invariants is given in the recent preprint [KM].My purpose here is to prove the following theorem:Main Theorem. Let X be a compact, oriented, 4 dimensional manifold with b 2+ ≥ 2. Let ω be a symplectic form on X with ω ∧ ω giving the orientation. Then the first Chern class of the associated almost complex structure on X has Seiberg-Witten invariant equal to ±1.(Note: There are no symplectic forms on X unless b 2+ and the first Betti number of X have opposite parity.)In a subsequent article with joint authors, a vanishing theorem will be proved for the Seiberg-Witten invariants of a manifold X, as in the theorem, which can be split by an embedded 3-sphere as X − ∪ X + where neither X − nor X + have negative definite intersection forms. Thus, no such manifold admits a symplectic form. That is, Corollary.Connect sums of 4-manifolds with non-negative definite intersection forms do not admit symplectic forms which are compatible with the given orientation. For example, when n > 1 and m ≥ 0, then ( #n CP 2 )#( #m CP 2 ) has no symplectic form which defines the given orientation.The Main Theorem also implies that the Seiberg-Witten invariant for the canonical class of a complex surface with b 2+ ≥ 3 is equal to ±1. However, this result is easy to prove directly, as there is just one nondegenerate solution in this case.

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Compensatory cis-trans Evolution and the Dysregulation of Gene Expression in Interspecific Hybrids of Drosophila

et al. 2005

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Hybrids between species are often characterized by novel gene-expression patterns. A recent study on allele-specific gene expression in hybrids between species of Drosophila revealed cases in which cis-and transregulatory elements within species had coevolved in such a way that changes in cis-regulatory elements are compensated by changes in trans-regulatory elements. We hypothesized that such coevolution should often lead to gene misexpression in the hybrid. To test this hypothesis, we estimated allele-specific expression and overall expression levels for 31 genes in D. melanogaster, D. simulans, and their F 1 hybrid. We found that 13 genes with cis-trans compensatory evolution are in fact misexpressed in the hybrid. These represent candidate genes whose dysregulation might be the consequence of coevolution of cis-and trans-regulatory elements within species. Using a mathematical model for the regulation of gene expression, we explored the conditions under which cis-trans compensatory evolution can lead to misexpression in interspecific hybrids.

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SW ⇒ Gr: From the Seiberg-Witten equations to pseudo-holomorphic curves

Taubes

1996

J. Amer. Math. Soc.

242

350

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The purpose of this article is to explain how pseudo-holomorphic curves in a symplectic 4-manifold can be constructed from solutions to the Seiberg-Witten equations. As such, the main theorem proved here (Theorem 1.3) is an existence theorem for pseudo-holomorphic curves. This article thus provides a proof of roughly half of the main theorem in the announcement [T1]. That theorem, Theorem 4.1, asserts an equivalence between the Seiberg-Witten invariants for a symplectic manifold and a certain Gromov invariant which counts (with signs) the number of pseudoholomorphic curves in a given homology class.The Seiberg-Witten invariants were introduced to mathematicians by Witten at least 2, then these invariants define a diffeomorphism invariant map, SW, from the set of equivalence classes, Spin, of Spin C structures on X to Z. Note that the set Spin has naturally the structure of a principal H 2 (X; Z) bundle over a point. A symplectic 4-manifold is a pair (X, ω), where X is a 4-manifold and where ω is a closed 2-form with ω ∧ ω nowhere zero. Thus, a symplectic 4-manifold has a canonical orientation. A symplectic 4-manifold also has a complex line bundle, K, (called the canonical bundle) which is canonical up to isomorphism. And, as explained in [T1] or [T2], a symplectic 4-manifold has a canonical equivalence class of Spin C structure. The latter endows Spin with a base point and so gives the identification(Both the identification of Spin and the choice of orientation do not change under a continuous deformation of the symplectic form.) In the ensuing discussion, the canonical orientation for a symplectic manifold and the identification in (0.2) will be assumed implicitly. Thus, with (0.2) understood, SW defines a map SW : H 2 (X; Z) → Z. (0.3)

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