This article explores to which extent the algebro-geometric theory of rational descendant Gromov-Witten invariants can be carried over to the tropical world. Despite the fact that the tropical moduli-spaces we work with are non-compact, the answer is surprisingly positive. We discuss the string, divisor and dilaton equations, we prove a splitting lemma describing the intersection with a "boundary" divisor and we prove general tropical versions of the WDVV resp. topological recursion equations (under some assumptions). As a direct application, we prove that the toric varieties P 1 , P 2 , P 1 × P 1 and with Psiconditions only in combination with point conditions, the tropical and classical descendant Gromov-Witten invariants coincide (which extends the result for P 2 in [MR08]). Our approach uses tropical intersection theory and can unify and simplify some parts of the existing tropical enumerative geometry (for rational curves).2010 Mathematics Subject Classification. Primary 14T05; Secondary 14N35, 52B20.To be more precise, let Γ ϕ be the graph of ϕ in X × R. It is a polyhedral complex whose polyhedra are in one-to-one correspondence with those of X, but in general Γ ϕ is not balanced. However, it can be completed to a cycle by adding facets in (0, −1)-direction at each ridge of Γ ϕ , equipped with the above weights. Now, if we (imaginary) intersect this tropically completed graph of ϕ with X × {−∞} (i.e. compute the tropical zero locus of ϕ), we obtain the cycle div(ϕ) = ϕ · X of our definition. If ϕ is globally affine (resp. linear), all weights are zero, which we denote by ϕ · X = 0. Let the support of ϕ, denoted by |ϕ|, be the subcomplex of X containing the points x ∈ |X| where ϕ is not locally affine. Then we have |ϕ · X| ⊆ |ϕ|. Furthermore, the intersection product is bilinear (see [AR07, 3.6]). As the restriction of a rational function to a subcycle is again a rational function, we can also form multiple intersection products ϕ 1 · . . . · ϕ l · X. In this case we will sometimes omit "·X" to keep formulas shorter. Note that multiple intersection products are commutative (see [AR07, 3.7]).A morphism of cycles X ⊆ V = Λ ⊗ R and Y ⊆ V ′ = Λ ′ ⊗ R is a map f : |X| → |Y | that is induced by a linear map b Λ to Λ ′ and that maps each polyhedron of X into a polyhedron of Y . We call f an isomorphism and write X ∼ = Y , if there exists an inverse morphism and if for all facets σ ∈ X we have ω X (σ) = ω Y (f (σ)). Such a morphism pulls back rational functions ϕ on Y to rational functions f * (ϕ) = ϕ • f on X. Note that the second condition of a morphism makes sure that we do not have to refine X further. f * (ϕ) is already affine on each cone. The inclusion |f * (ϕ)| ⊆ f −1 (|ϕ|) holds, as the composition of an affine and a linear function is again affine. Furthermore, we can push forward subcycles Z of X to subcycles f * (Z) of Y of same dimension. This is due [GKM07, 2.24 and 2.25] in the case of fans and can be generalized to complexes (see [AR07, 7.3]). We can omit further refinements here if we assume that f...
