Construction of invariant curves for singular holomorphic vector fields

Camacho and Sad proved the existence of invariant analytic curves for germs of singular holomorphic foliations over a two dimensional complex analytic variety . Their proof is only of existential nature. Here we provide a simple constructive proof by giving criteria to choose a singular point at each blowing-up that follows an analytic invariant curve.

     

A resolution theorem for absolutely isolated singularities of holomorphic vector fields

In this paper, the desingularization problem for an absolutely isolated singularity of an-dimensional holomorphic vector field is solved. Also, we exhibit final forms under blowing-up for this type of singularities.     

On complete holomorphic vector fields

We show that, on holomorphic manifolds that have a plurisubharmonic exhaustion function and that do not carry nonconstant bounded plurisubharmonic functions (e.g. ), holomorphic vector fields that are complete in positive time are complete in complex time.

     

Residues of higher order and holomorphic vector fields

LetX ₁ andX ₂ be two holomorphic vector fields on a manifoldV with complex dimensionp. Assume that they have the same singular set . For all , it is known (after Chern-Bott) that each of the vector fields defines a residual characteristic classC ₁(V,X ₁)(resp.C ₁(V,X ₂)) inH ^2p (V, V-), which is a lift of the usual characteristic classC ₁ (V) of the tangent bundle. The differenceC ₁ (V,X ₂)-C ₁ (V,X ₁) belongs then to the image of in the exact sequence. In fact, there exists a canonical liftC ₁ (V,X ₁,X ₂) of this difference inH ^2p–1(V-): we will call itthe residual class of order 2 (associated toI, X ₁ andX ₂). This class is localized near the points whereX ₁ andX ₂ are colinear: we will explain this precisely in terms of Grothendieck residues. The formula that we obtain can be interpreted as a generalization of the purely algebraic identity, obtained from the general one as a byproduct: where ( ₁, , _p) and ( ₁,, _p ) denote two families of non-zero complex numbers, such that all denominators in this formula do not vanish. (This identity corresponds in fact to the case whereX ₁ andX ₂ are non-degenerate at the same isolated singular point.)If the _i 's (1ip) depend now differentiably (resp. holomorphically) on a real (resp. complex) parametert then, denoting by the derivative with respect tot, and assuming all numbers lying in a denominator not to be 0, we can deduce from the above identity the following derivation formula:     

Examples of non-conjugated holomorphic vector fields and foliations

We consider germs of holomorphic vector fields near the origin of with a saddle-node singularity, and the induced singular foliations. In a previous article we described the invariants addressing the analytical classification of these vector fields. They split into three parts: a formal, an orbital and a tangential component. For a fixed formal class, the orbital invariant (associated to the foliation) was obtained by Martinet and Ramis; we give it an integral representation. We then derive examples of non-orbitally conjugated foliations by the use of a “first-step” normal form, whose first-significative jet is an invariant. The tangential invariant also admits an integral representation, hence we derive explicit examples of vector fields, inducing the same foliation, that are not mutually conjugated. In addition, we provide a family of normal forms for vector fields orbitally equivalent to the model of Poincaré-Dulac.     

A singular approach to discontinuous vector fields on the plane

In this paper we deal with discontinuous vector fields on R² and we prove that the analysis of their local behavior around a typical singularity can be treated via singular perturbation. The regularization process developed by Sotomayor and Teixeira is crucial for the development of this work.     

Analyticity for singular sums of squares of degenerate vector fields

Recently J. J. Kohn (2005) proved hypoellipticity for

(the negative of) a singular sum of squares of complex vector fields on the complex Heisenberg group, an operator which exhibits a loss of derivatives. Subsequently, M. Derridj and D. S. Tartakoff proved analytic hypoellipticity for this operator using rather different methods going back to earlier methods of Tartakoff. Those methods also provide an alternate proof of the hypoellipticity given by Kohn.

In this paper, we consider the equation

for which the underlying manifold is only of finite type, and prove analytic hypoellipticity using methods of Derridj and Tartakoff. This operator is also subelliptic with large loss of derivatives, but the exact loss plays no role for analytic hypoellipticity. Nonetheless, these methods give a proof of hypoellipticity with precise loss as well, which is to appear in a forthcoming paper by A. Bove, M. Derridj, J. J. Kohn and the author.

     

Characterization of the complex projective space by holomorphic vector fields

Received 22 June 1994; in final form 16 August 1994     

A free convenient vector space for holomorphic spaces

In this paper we show that there exists a free convenient vector space for the case of holomorphic spaces and holomorphic maps. This means that for every spaceX with a holomorphic structure, there exists an appropriately complete locally convex vector space X and a holomorphic mapl _X:XX, such that for any vector space of the same kind the map (l _X )^*:L(X,E)(X,E) is a bijection. Analogously to the smooth case treated in [2, 5.1.1] the free convenient vector space X can be obtained as the Mackey closure of the linear subspace spanned by the image of the canonical mapX(X).In the second part of the paper we prove that in the case whereX is a Riemann surface, one hasX=(X,).     

Germs of holomorphic vector fields in without a separatrix

We prove the existence of families of germs of holomorphic vector fields in without a separatrix, in every complex dimension bigger than or equal to 4.