Nanostructured Semiconductors for Electrochemical and Photoelectrochemical Water Splitting
Date
2017
Authors
Liu, Guanyu
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Abstract
Chemical energy storage by water splitting is a promising
solution for the utilization of solar energy in numerous
applications. Both efficient electrocatalysts and photocatalysts
with a facile and scalable synthesis method are indispensable to
achieve economic feasibility for water splitting. In the
introductory chapter, a comprehensive review of electrochemical
and photoelectrochemical (PEC) water splitting is provided and
the fundamental concept of the PEC device design is described.
Three different systems for water splitting were then explored in
the following experimental chapters. In the second chapter,
Manganese oxides (Mn3O4, Mn5O8 and Mn2O3) nanoparticles, with a
range of specific surface area and crystal structures, were
synthesized and compared. The nearly identical morphology of
synthesized manganese oxide nanocrystals allows a systematic
investigation on the relation between oxidation states and
catalytic activities of different manganese oxide nanocrystals.
Interesting discoveries regarding surface-specific turnover
frequency, mole-specific turnover frequency and catalytic
stability were demonstrated.
Highly transparent and robust sub-monolayers of Co3O4
nano-islands were subsequently developed, which efficiently
catalyse water oxidation with a comparable performance to noble
metal-based catalysts. The potential of the Co3O4 nano-islands
for photoelectrochemical water splitting has been demonstrated by
incorporation of co-catalysts in GaN nanowire photoanodes. The
Co3O4-GaN photoanodes reveal significantly reduced onset
overpotentials, improved photoresponse and photostability
compared to the bare GaN ones.
In the last experimental chapter, we developed both physically-
and chemically-induced morphology/structure tuning procedures,
viz. capillary force-induced self-assembly and corrosion followed
by regrowth, drastically increasing the water oxidation
photocurrent density of nanostructured hematite photoanode. In
addition to morphological changes, structural transformations
were obtained by capillary force-induced self-assembly resulting
in improved crystallinity of hematite with preferential
orientation in the [110] direction. High conductivity of the
hematite (001) basal planes contributes to the significantly
enhanced photo-electrocatalytic activity. Subsequent dissolution
and regrowth of hematite nanostructures further improved the
performance, resulting in improved light absorption, more
efficient charge separation and surface charge transfer
processes.
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Keywords
semiconductors, water splitting, energy conversion, artificial photosynthesis, nanomaterials
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