Laser processing of neat and gold-nanoparticle-functionalized ZnO and TiO2 nanoparticles by nanosecond-355-nm or picosecond-532-nm light enabled control of photocurrent generation under simulated sunlight irradiation in neutral aqueous electrolytes. We obtained more than twofold enhanced photoelectrochemical performance of TiO2 nanoparticles upon irradiation by picosecond-532-nm pulses that healed defects. Laser processing and gold nanoparticle functionalization of ZnO and TiO2 nanomaterials resulted in color changes that did not originate from optical bandgaps or crystal structures. Two-dimensional photoluminescence data allowed us to differentiate and quantify surface and bulk defects that play a critical yet oft-underappreciated role for photoelectrochemical performance as sites for detrimental carrier recombination. We developed a detailed mechanistic model of how surface and bulk defects were generated as a function of laser processing parameters and obtained key insights on how these defects affected photocurrent production. The controlled healing of defects by pulsed-laser processing may be useful in the design of solar fuels materials. Pulsed lasers are powerful tools for the time-efficient preparation and/or modification of functional materials. 14-21 Recent investigations have shown that laser-modified TiO2 particles can be used to improve the light-driven water splitting to form hydrogen 22 or
Laser fragmentation
in liquids (LFL) allows the synthesis of fully
inorganic, ultrasmall gold nanoparticles, usAu NPs (<3 nm). Although
the general method is well established, there is a lack of understanding
the chemical processes that are triggered by the laser pulses, which
may dictate the surface properties that are highly important in heterogeneous
oxidation catalytic reactions. We observed the formation of radical
oxygen species during LFL, which suggested that LFL is a physicochemical
process that leads to particle size reductions and initiates oxidative
processes. When the ionic strength in the nanoenvironment was increased,
the oxidation of the first atomic layer saturated at 50%, whereby
the surface charge density increases continuously. We found a correlation
between the surface charge density after synthesis of colloidal nanoparticles
and its behavior in catalysis. The properties of the laser-generated
nanoparticles in the colloidal state appear to have predetermined
the catalytic performance. We found that a smaller surface charge
density of the usAu NPs was beneficial for the catalytic activity
in CO and ethanol oxidation, while their peroxidase-like activity
was affected less. The catalytic activity was 2 times higher for samples
prepared by chloride-free LFL after ozone pretreatment compared to
samples prepared in pure water.
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