Developing
highly efficient and stable photoelectrochemical (PEC)
water-splitting electrodes via inexpensive, liquid phase processing
is one of the key challenges for the conversion of solar energy into
hydrogen for sustainable energy production. ZnO represents one the
most suitable semiconductor metal oxide alternatives because of its
high electron mobility, abundance, and low cost, although its performance
is limited by its lack of absorption in the visible spectrum and reduced
charge separation and charge transfer efficiency. Here, we present
a solution-processed water-splitting photoanode based on Co-doped
ZnO nanorods (NRs) coated with a transparent functionalizing metal–organic
framework (MOF). The light absorption of the ZnO NRs is engineered
toward the visible region by Co-doping, while the MOF significantly
improves the stability and charge separation and transfer properties
of the NRs. This synergetic combination of doping and nanoscale surface
functionalization boosts the current density and functional lifetime
of the photoanodes while achieving an unprecedented incident photon
to current efficiency (IPCE) of 75% at 350 nm, which is over 2 times
that of pristine ZnO. A theoretical model and band structure for the
core–shell nanostructure is provided, highlighting how this
nanomaterial combination provides an attractive pathway for the design
of robust and highly efficient semiconductor-based photoanodes that
can be translated to other semiconducting oxide systems.
We present femtosecond transient transmission (or absorbance) measurements in silicon nanowires in the energy range 1.1-3.5 eV, from below the indirect band-gap to above the direct band-gap. Our pumpprobe measurements allow us to give a complete picture of the carrier dynamics in silicon. In this way we perform an experimental study with a spectral completeness that lacks in the whole literature on carrier dynamics in silicon. A particular emphasis is given to the dynamics of the transient absorbance at the energies relative to the direct band gap at 3.3 eV. Indeed, the use of pump energies below and above 3.3 eV allowed us to disentangle the dynamics of electrons and holes in their respective bands. The band gap renormalization of the direct band gap is also investigated for different pump energies. A critical discussion is given on the results below 3.3 eV where phonon-assisted processes are required in the optical transitions.
The knowledge of the carrier dynamics in nanostructures is of fundamental importance for the development of (opto)electronic devices. This is true for semiconducting nanostructures as well as for plasmonic nanoparticles (NPs). Indeed, improvement of photocatalytic efficiencies by combining semiconductor and plasmonic nanostructures is one of the reasons why their ultrafast dynamics are intensively studied. In this work, we will review our activity on ultrafast spectroscopy in nanostructures carried out in the recently established EuroFEL Support Laboratory. We have investigated the dynamical plasmonic responses of metal NPs both in solution and in 2D and 3D arrays on surfaces, with particular attention being paid to the effects of the NP shape and to the conversion of absorbed light into heat on a nano-localized scale. We will summarize the results obtained on the carrier dynamics in nanostructured perovskites with emphasis on the hot-carrier dynamics and in semiconductor nanosystems such as ZnSe and Si nanowires, with particular attention to the band-gap bleaching dynamics. Subsequently, the study of semiconductor-metal NP hybrids, such as CeO2-Ag NPs, ZnSe-Ag NPs and ZnSe-Au NPs, allows the discussion of interaction mechanisms such as charge carrier transfer and Förster interaction. Finally, we assess an alternative method for the sensitization of wide band gap semiconductors to visible light by discussing the relationship between the carrier dynamics of TiO2 NPs and V-doped TiO2 NPs and their catalytic properties.
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