Ultrafast laser spectroscopy enables real time observations of photo-induced processes and the exploration of their dynamics and reaction pathways on attosecond time-scales. By shaping the spectral amplitude and phase of ultrashort laser pulses the contributing electronically and vibronically excited states can even be controlled coherently. Optimum control is achieved by adaptive pulse shaping using learning-loop techniques fine-tuning branching ratios and reaction yields. Near-field optics, on the other hand, aims at surpassing the resolution limit of conventional microscopy imposed by diffraction reaching about 10 nm at present. We propose to develop a novel technique by combining ultrafast adaptive control and tip-enhanced near-field optical microscopy (UAC-TENOM) using carbon nanotubes as model nanostructures. Specifically, we will achieve the adaptive control of near-field interference and pulse compression in tunable metal-particle configurations using polarization shaped laser pulses. Merging ultrafast adaptive control and tip-enhanced techniques offers substantial added value by further increasing spatial resolution and signal enhancement of TENOM. Our results will form important steps towards full spatio-temporal and coherent control of excited states in single nanostructures and will have a major impact on other nanoscale spectroscopies.

DFG Programme Priority Programmes

Subproject of SPP 1391:  Ultrafast Nanooptics