Single-Wall Carbon Nanotubes (SWNTs) non-covalently fonctionalized with organic molecules have proven to be a very promising light-harvesting system. The goal is to combine the unique transport properties of nanotubes with the wide tunability of organic molecules properties. Among those molecules, porphyrins, a precursor of photosynthetic centers are already used in dye sensitized hybrid solar cells [1]. Porphyrins link to SWNTs through π-stacking interaction which preserves most of the intrinsic properties of the SWNTs, in contrast with covalent functionalization. Moreover, the coupling is still strong enough to induce an efficient excitation energy transfer (EET) [2,3]. The very high transfer yield reported in this system suggests that the EET mechanism must occur on an ultrafast time-scale [4]. In order to characterize the nature of the EET mechanism, we investigated its dynamics at a subpicosecond time scale, by means of pump-probe spectroscopy. We show that the ground state recovery time of porphyrin in the compound is reduced by several orders of magnitude compared to the case or free porphyrin (Fig. 1). Concomitantly, a strong bleaching signal is observed on the optical resonances of the nanotubes showing an ultrafast population build-up upon excitation of the porphyrin (Fig. 2). We conclude that the energy transfer occurs on a time scale shorter than 100fs and that the surrounding of SWNTs by porphyrins does not affect the relaxation dynamics. Probing excited states of the nanotubes and porphyrin further allows to track the energy transfer path in the supra molecular compound. References [1] W. M. Campbell, et al., The Journal of Physical Chemistry C, 111, 11760 (2007). [2] G. Magadur, et al., ChemPhysChem, 9, 1250 (2008).pp. 200-205. [3] J. P. Casey, et al., Journal of Materials Chemistry, 18, 1510 (2008). [4] C. Roquelet, et al., Applied Physics Letters, 97, 141918 (2010).