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  • Broschiertes Buch

In order to observe phenomena on the molecular level, it is necessary to develop a technique that is sensitive to all the microscopic spatial degrees of freedom on the time scale of the molecular processes. For the case of surface physics, the standard tool for structure determination is Low-Energy-Electron-Diffraction (LEED). This technique, endowed in a so-called 'pump-probe experiment' framework has the potential to follow in real time the excitation and the relaxation dynamics at surfaces on the picosecond time scale (1 ps=10^(-15) s). This book describes the realization of the first…mehr

Produktbeschreibung
In order to observe phenomena on the molecular level,
it is necessary to develop a technique that is
sensitive to all the microscopic spatial degrees of
freedom on the time scale of the molecular processes.
For the case of surface physics, the standard tool
for structure determination is
Low-Energy-Electron-Diffraction (LEED). This
technique, endowed in a so-called 'pump-probe
experiment' framework has the potential to follow in
real time the excitation and the relaxation dynamics
at surfaces on the picosecond time scale (1
ps=10^(-15) s). This book describes the realization
of the first proof-of-principle experiment for
time-resolved LEED
(t-LEED). The design, realization and
characterization of a home-built electron gun is
presented: with such a tool, a temporal resolution of
few picosecond was achieved. First experiments were
performed to track in real time phase transitions
occuring on surfaces and dynamics of the so-called
space-charge effect: the emission of electrons on a
metal surface by an intense pump pulse via
multi-photon absorption processes.
Autorenporträt
Claudio Cirelli received his diploma degree in Physics from the
University of Milan, Italy, in 2002. in January 2003, he joined
the Surface Physics group at the University of Zurich,
Switzerland. His research focuses on the investigation of
dynamics of molecules and atoms on surfaces by means of
time-resolved measurements.