Ultrafast charge transfer through p-oligo(phenylene) bridges: Effect of nonequilibrium vibrations
Current Science 99:3 (2010) 343-352
Abstract:
Electron transfers (ET) between a donor (D) and an acceptor (A) through a molecular bridge (B) are of great importance in biological systems, molecular electronics and molecular based light-energy conversion systems. Here, the back and the forward electron transfer rates have been measured by femtosecond and nanosecond spectroscopy in a heterogeneous donor- bridge-acceptor (D-B-A) system, where D = ruthenium terpyridine complex, B = p-oligo(phenylene) and A = TiO2. The forward ET rate (from 0.85 to 3.7 ps-1) is faster than the nonequilibrium vibrations relaxation rate of the hot 3MLCT (metal-to-ligand charge transfer) state of the donor (12 ps-1 in solution). The back ET occurs on the microsecond time scale. Regarding the distance dependence behaviour, damping factors 0.16 and 0.47 Å-1 of the forward and the back ET respectively are obtained. These results confirm that the damping factor is not only linked to the nature of the molecular bridge but to the full D-B-A system. This unusual low damping factor observed for the forward ET is attributed to a decrease of the tunnelling energy gap ΔE, which is induced by the nonequilibrium vibrations at the donor-bridge interface. This enhanced electron transmission is briefly discussed within the concept of a nonequilibrium polaron relaxation towards the dissipative acceptor. In this case, the dissipation of the excess vibrational energy and the electron transfer occur in a synchronized cooperative way.Inexpensive and fast wafer-scale fabrication of nanohole arrays in thin gold films for plasmonics.
Nanotechnology 21:20 (2010) 205301
Abstract:
In this paper, a fast and inexpensive wafer-scale process for the fabrication of arrays of nanoscale holes in thin gold films for plasmonics is shown. The process combines nanosphere lithography using spin-coated polystyrene beads with a sputter-etching process. This allows the batch fabrication of several 1000 microm(2) large hole arrays in 200 nm thick gold films without the use of an adhesion layer for the gold film. The hole size and lattice period can be tuned independently with this method. This allows tuning of the optical properties of the hole arrays for the desired application. An example application, refractive index sensing, is demonstrated.Nanostructured waveguides for evanescent wave biosensors
Applied Surface Science Elsevier 256:3 (2009) s12-s17
Monitoring of cellular immune responses with an optical biosensor: a new tool to assess nanoparticle toxicity
Procedia Chemistry Elsevier 1:1 (2009) 738-741
Optically‐Pumped Lasing in Hybrid Organic–Inorganic Light‐Emitting Diodes
Advanced Functional Materials Wiley 19:13 (2009) 2130-2136