One of the most detrimental loss mechanisms in Luminescent Solar Concentrators (LSCs) is reabsorption of emitted light from the luminophore. Silicon Nanocrystals (SiNCs) offer a solution due to the high apparent Stokes shift, but the poor absorption properties limit their performance as LSC luminophores. Coupling an organic dye to SiNCs represents a smart approach to obtain sensitization of SiNC luminescence by the organic dyes, thus, resulting in tunable and improved optical properties of LSCs. In particular, 9,10-diphenylanthracene was employed as a UV sensitizer for SiNCs in order to produce LSCs with an aesthetic appearance suitable to smart window application and optical efficiency as high as 4.25%. In addition, the role of the energy transfer process on LSC performance was elucidated by a thorough optical and photovoltaic characterization.
Water splitting is
considered one of the most promising approaches
to power the globe without the risk of environmental pollution. The
oxygen evolution reaction (OER) is even more challenging because the
generation of only one oxygen molecule involves the transfer of four
e– and removal of four H+ ions from water.
Thus, developing highly efficient catalysts to meet industrial requirements
remains a focus of attention. Herein, the prominent role of Sn in
accelerating the electron transfer kinetics of Ni5P4 nanosheets in OER is reported. The post catalytic survey
elucidates that the electrochemically induced Ni–Sn oxides
at the vicinity of phosphides are responsible for the observed catalytic
activity, delivering current densities of 10, 30, and 100 mA cm–2 at overpotentials of only 173 ± 5.2, 200 ±7.4,
and 310 ± 5.5 mV, respectively. The density functional theory
calculation also supports the experimental findings from the basis
of the difference observed in density of states at the Fermi level
in the presence/absence of Sn. This work underscores the role of Sn
in OER and opens a promising avenue toward practical implementation
of hydrogen production through water splitting and other catalytic
reactions.
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