Sensitization processes resulting from the photoexcitation of chromophores (sensitizers) bound to semiconductor nanoparticles are of great importance for solar energy conversion. 1 Examples are TiO 2 solar cells, where the sensitizer is usually a Ru II -polypyridyl complex substituted with COOR binding groups, such as Ru(bpy) 2 -(dme) 2+ (1). 2 To study the dynamics of long-range interfacial charge-transfer processes in sensitizer/semiconductor nanoparticle systems, 3 we prepared a series of rigid sensitizers made of a tripod-shaped base terminated with a Ru II complex and attached them to the surface of mesoporous nanocrystalline (anatase) TiO 2 thin films through three COOR groups. 4 The three-point attachment and the rigidity of these molecules allow the control of the distance and orientation of the sensitizer with respect to the nanoparticle surface. Earlier nanosecond experiments with the tripod/TiO 2 systems demonstrated that the excited-state electron injection is quantitative and occurs well within the duration of the laser pulse. 4a,b In this communication, we report the observation of ultrafast charge injection from the longest tripods prepared in these laboratories, 2 and 3 shown in Figure 1, 5 in which the Ru-to-footprint distance is 24 Å. 6 To our knowledge, this is the first example of subpicosecond photoinduced ET in sensitized TiO 2 occurring over such extended distances.Interfacial charge injection was investigated in 2 and 3 ( Figure 1) bound to TiO 2 mesoporous films, with 1 serving as the reference. The structures of 2 and 3 are identical except for the ligand connecting the Ru II center to the tripod (phenanthroline in 2 and bipyridine in 3). The thin films were cast on microscope cover glasses and treated with solutions of 1, 2, or 3, following previously described procedures. 4a The resulting 1/TiO 2 , 2/TiO 2 , and 3/TiO 2 systems were excited at 405 nm (SH) and probed with the white light continuum generated by the fundamental output of a homebuilt 1 kHz multipass Ti:sapphire amplifier. 7 The typical pulse length was 110 fs, and the beams were mildly focused to ∼0.5-1.0 mm diameter at the sample. The injection dynamics was probed over a broad range of wavelengths. The analysis focused on the 750-1100 nm spectral region, where only the MLCT excited state of the Ru II chromophore and the electron injected into the conduction band of TiO 2 , e -TiO2 , exhibit appreciable absorption 8,9 and no stimulated emission is observed.For the reference system 1/TiO 2 the electron injection occurred within the response time of our instrument, k inj > 1 × 10 13 s -1 , and only the long-lived absorption of e -TiO2 was detected ( Figure 2a, lowest trace). This is fully consistent with the reports of other groups, which place the injection rate of directly bound Ru II -polypyridyl sensitizers in the sub-100 fs range. 10 Recent stateof-the-art measurements on related sensitizers show that this rate is ∼20-30 fs, 11 i.e., much faster than the duration of our excitation and probe pulses. Upon excitation...
