The temperature dependence of d-wave superconducting order for two dimensional fermions with d-wave attraction is investigated by means of the functional renormalization group with partial bosonization. Below the critical temperature T c we find superconductivity, a gap in the electron propagator and a temperature dependent anomalous dimension. At T c the renormalized "superfluid density" jumps and the approach to T c from above is characterized by essential scaling. These features are characteristic for a phase transition of the KosterlitzThouless (KT) type.The two-dimensional Hubbard model [1] is often associated with high temperature superconductivity [2]. Its ground state is assumed to be a d-wave superconductor for an appropriate range of doping [3,4]. Under the hypothesis of d-wave superconductivity we study within a simplified effective model the phase transition from the high temperature "symmetric phase" to the low temperature superconducting phase by means of the functional renormalization group. As characteristic features we find (i) essential scaling as the critical temperature T c is approached from above, (ii) a massless Goldstone mode for T < T c leading to superfluidity, (iii) a temperature dependent anomalous dimension η for T < T c , (iv) a jump in the renormalized superfluid density at T c and (v) a gap in the electron propagator for T < T c which vanishes non-analytically as T → T c .The features (i)-(iv) are characteristic for a KT phase transition [5] which is a natural candidate for a universality class with a global U(1) symmetry. Actually, while in the infinite volume limit the "bare" order parameter vanishes in accordance with the Mermin-Wagner theorem, a renormalized order parameter [6] spontaneously breaks the U(1) symmetry for T < T c , leading to an infinite correlation length for the Goldstone mode. Vortices arise as topological defects for T < T c . In the Hubbard model the fermionic excitations (single electrons or holes) are an important ingredient for driving the transition. Finally, coupling our model to electromagnetic fields the photon acquires a mass through the Higgs mechanism while the Goldstone mode disappears from the spectrum, being a gauge degree of freedom. Superfluidity is replaced by superconductivity. Recently, various experimental data have been interpreted as signatures of KT phase fluctuations [7,8,9,10]. The direct relation between real high temperature superconductors and the two-dimensional Hubbard model is difficult, however.The problem of d-wave superconductivity in the Hubbard model can be separated into two qualitative steps in the renormalization flow. In the first step the fluctuations with momenta |p 2 − p 2 F | > Λ 2 (with p F on the Fermi-surface) have to generate a strong effective interaction in the d-wave channel. This phenomenon has indeed been found in renormalization group studies [11,12,13,14,15,16,17,18,19], the d-wave coupling being triggered by spin wave fluctuations. It also has been found in various other approaches, see e.g. [20,21,22]....
