Inorganic Metal Oxide Nanocrystal Photocatalysts for Solar Fuel Generation from Water PDF Download
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Author: Troy K. Townsend
Publisher: Springer Science & Business Media
ISBN: 331905242X
Category : Science
Languages : en
Pages : 80
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Book Description
Troy Townsend's thesis explores the structure, energetics and activity of three inorganic nanocrystal photocatalysts. The goal of this work is to investigate the potential of metal oxide nanocrystals for application in photocatalytic water splitting, which could one day provide us with clean hydrogen fuel derived from water and solar energy. Specifically, Townsend's work addresses the effects of co-catalyst addition to niobium oxide nanotubes for photocatalytic water reduction to hydrogen, and the first use of iron oxide 'rust' in nanocrystal suspensions for oxygen production. In addition, Townsend studies a nickel/oxide-strontium titanate nanocomposite which can be described as one of only four nanoscale water splitting photocatalysts. He also examines the charge transport for this system. Overall, this collection of studies brings relevance to the design of inorganic nanomaterials for photocatalytic water splitting while introducing new directions for solar energy conversion.
Author: Troy K. Townsend
Publisher: Springer Science & Business Media
ISBN: 331905242X
Category : Science
Languages : en
Pages : 80
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Book Description
Troy Townsend's thesis explores the structure, energetics and activity of three inorganic nanocrystal photocatalysts. The goal of this work is to investigate the potential of metal oxide nanocrystals for application in photocatalytic water splitting, which could one day provide us with clean hydrogen fuel derived from water and solar energy. Specifically, Townsend's work addresses the effects of co-catalyst addition to niobium oxide nanotubes for photocatalytic water reduction to hydrogen, and the first use of iron oxide 'rust' in nanocrystal suspensions for oxygen production. In addition, Townsend studies a nickel/oxide-strontium titanate nanocomposite which can be described as one of only four nanoscale water splitting photocatalysts. He also examines the charge transport for this system. Overall, this collection of studies brings relevance to the design of inorganic nanomaterials for photocatalytic water splitting while introducing new directions for solar energy conversion.
Author: Jing Zhao
Publisher:
ISBN: 9781321610314
Category :
Languages : en
Pages :
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Book Description
Solar energy conversion is considered one of the most promising renewable energy solutions for replacing fossil fuels and easing global climate change. Developing a cost-effective technology for solar energy utilization to compete with market grid price is among the top priorities of our scientific society. Photocatalytic water splitting, which utilizes solar energy to produce carbon-zero hydrogen fuels from water, holds great potential towards achieving this challenging mission. Photovoltaic (PV) devices, for converting solar energy to electricity, continue to witness technological advances in the 21st century. This dissertation is dedicated to the advancement of photocatalytic water splitting and photovoltaic technologies, including the search for inexpensive photocatalysts with high efficiency, the fundamental understanding of photo-induced charge separation processes and the advanced instrumentation for probing photovoltage generation on the nanoscale. Chapter 2 starts off with the effect of quantum size confinement on the photocatalytic hydrogen production by CdSe nanocrystals. The particle size of a well-defined CdSe nanocrystal series is systematically varied, and their size-dependent conduction/valence band energetics as well as their photocatalytic hydrogen evolution rates are characterized in details. This allows the construction of a quantitative correlation between particle size, energy level and photocatalytic activity for CdSe nanocrystals, following Butler-Volmer electron-transfer theory. Chapter 3 transitions into the study on WO3 photoanodes for photocatalytic oxygen evolution. The activity of WO3 photoanodes is greatly enhanced via an in-situ doping by electrochemical reduction. Investigations show that the moderate reduction boosts carrier concentration and conductivity in WO3, consequently an improved charge collection and an increased photocurrent response. This activation strategy is also proven to be applicable to other WO3 systems with a wide range of particle sizes. Chapter 4 introduces surface photovoltage spectroscopy (SPS) as a powerful sensitive technique for probing photon-induced charge separation processes in photocatalysts and PV systems. Calcium niobium oxide, a wide bandgap hydrogen evolution photocatalyst with a well-defined surface morphology, is selected as a model material for understanding the photovoltage generation and charge separation in photocatalyst system via SPS. Systematic studies reveal the dependence of photovoltage on photon wavelength, light intensity, defect density, film thickness, ambient environment, substrate property, and the relative Fermi-level difference at the interface. Chapter 5 continues the application of SPS technique for understanding charge separation in CdSe nanocrystalline films for inorganic-/organic- hybrid solar cells. Surface ligands on CdSe nanocrystals are found to have a dramatic impact on the photovoltage responses from CdSe films. The replacement of native ligands by halides and amines leads to electron traps at the particle surface. Chloride, among all halide ligands, is indicated as a promising short surface ligand for good photovoltage response, whereas bromide and iodide are found as detrimental hole traps.
Author: W. David Wei
Publisher: Elsevier Inc. Chapters
ISBN: 0128081430
Category : Science
Languages : en
Pages : 48
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Book Description
Author: Jiaguo Yu
Publisher: John Wiley & Sons
ISBN: 3527349596
Category : Technology & Engineering
Languages : en
Pages : 514
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Book Description
Provides a timely overview of basic principles and significant advances of semiconductor-based photocatalysts for solar energy conversion Semiconductor Solar Photocatalysts: Fundamentals and Applications presents a systematic, in-depth summary of both fundamental and cutting-edge research in novel photocatalytic systems. Focusing on photocatalysts with vast potential for efficient utilization of solar energy, this up-to-date volume covers heterojunction systems, graphene-based photocatalysts, organic semiconductor photocatalysts, metal sulfide semiconductor photocatalysts, and graphitic carbon nitride-based photocatalysts. Organized into six chapters, the text opens with a detailed introduction to the history, design principles, modification strategies, and performance evaluation methods of solar energy photocatalysis. The remaining chapters provide detailed discussion of various novel photocatalytic systems such as direct Z-scheme and S-scheme photocatalysts, organic polymers, and covalent organic frameworks. This authoritative resource: Explains the essential concepts of solar energy photocatalysis and heterojunction systems for photocatalysis Reviews interesting structures and new applications of semiconductor photocatalysts Features contributions from an international panel of leading researchers in the field Includes extensive references and numerous tables, figures, and color illustrations Semiconductor Solar Photocatalysts: Fundamentals and Applications is valuable resource for all catalytic chemists, materials scientists, inorganic and physical chemists, chemical engineers, and physicists working in the semiconductor industry.
Author: Timothy L. Shelton
Publisher:
ISBN: 9781369310580
Category :
Languages : en
Pages :
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Book Description
As our world’s population is constantly growing, so also is the need to power the growth and spread of technology. The conversion of abundant solar energy into useable sources of fuel is an area of significant and vital research. Photocatalytic water splitting via suspended nanomaterials or photoelectrochemical cells has great promise for this purpose. This research focuses on the preparation and analysis of nanomaterials utilizing simple methods and earth abundant chemicals that will lead to cost-competitive methods to convert solar energy into an easily stored and transported fuel source. Specifically, our research seeks to better understand the methods of charge generation and separation in nanomaterial films and to quantify the limits of activity in suspended photocatalysts. Chapter 2 introduces a study on the nature of photovoltage generation in well-ordered hematite films under zero applied bias. The thickness of Fe2O3 nanorod films is varied by a simple hydrothermal synthesis and confirmed with TEM and profilometry measurements. Surface photovoltage spectroscopy (SPS) in the presence of air, water, nitrogen, oxygen, and under vacuum confirms photovoltages are associated with oxidation of surface water and hydroxyl groups and with reversible surface hole trapping on the 1 minute time scale and de-trapping on the 1 hour time scale with a maximum photovoltage of -130 mW under 2.0 eV – 4.5 eV illumination. Sacrificial donors (KI, H2O2, KOH) increase the voltage to -240 and -400 mW, due to improved hole transfer. The photovoltage is quenched with the addition of co-catalysts CoO[subscript x] and Co-Pi, possibly due to the removal of surface states and enhanced e/h recombination. Chapter 3 outlines a methodical exploration of the limits of water oxidation from illuminated ß-FeO(OH) suspensions. Well-defined akaganéite nanocrystals are able to produce oxygen gas from aqueous solutions in the presence of an appropriate electron acceptor. Optimal conditions were achieved by systematically varying the amount of catalyst, concentration of the electron acceptor, pH of the solution, and light intensity. A decrease in activity is shown to be the result of particle agglomeration after roughly 5 hours of illumination. A maximum O2 evolution rate of 35.2 μmol O2 h−1 is observed from an optimized system, with a QE of 0.19%, and TON of 2.58 based on total ß-FeO(OH). Chapter 4 continues to understand charge separation and transport in CdS nanorods. These nanomaterials are capable of catalytic proton reduction under visible illumination, but suffer from photo-corrosion resulting in decreased H2 production. SPS measurements show a maximum photovoltage of -230 mV at 2.75 eV and the charge separation is largely reversible. Coating the rods with graphitic carbon nitride (g-C3N4) creates a hole accepting protective layer than prevents oxidative loss of photo-activity. By adding platinum salts, additional photovoltage could be extracted through field induced charge migration from excited sub gap defect states and trap sites. The addition of a sacrificial reagent would either decrease or increase the photovoltage (depending on the reagent used) by creating additional bias in the films or charge recombination pathways. Finally, it was shown that varying the substrate has an effect on the platinum/substrate polarized charge injection. Chapter 5 Surface photovoltage is used to show for the first time the charge separation properties of Sn2TiO4, an n-type photocatalyst, a series of cuprous niobium oxides doped with tantalum (CuNb[subscript 1-y]Ta[subscript y]O[subscript x]), and a Cu (I) tantalum oxide Cu5Ta11O3.
Author: Srabanti Ghosh
Publisher: Elsevier
ISBN: 0128200731
Category : Technology & Engineering
Languages : en
Pages : 386
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Book Description
Heterostructured Photocatalysts for Solar Energy Conversion provides a comprehensive description of novel z-scheme hybrid materials based on metal oxide or chalcogenides-based semiconductor, or carbon-based nanomaterials (conducting polymers, graphene, and other carbon materials). The book explores energy conversion applications, such as hydrogen generation, water splitting, CO2 reduction or degradation of organic pollutants, and their associated new material and technology development. The book addresses a variety of topics, such as photochemical processes, materials and fabrication, degradation mechanisms, as well as challenges and strategies. The book includes in-depth discussions ranging from comprehensive understanding, to engineering of materials and applied devices. The concept of visible light active catalysis emerged in recent decades and continues to attract the scientific community. Driven primarily by an opportunity to develop novel multifunctional materials on one hand, and sustainable technologies on the other, several successful approaches have been explored. However, preparation, characterization, and application of visible light active Z-scheme heterojunction-based catalytic nanostructures are still at the foreground of research activity. - Provides an overview on recently developed Z-scheme photocatalysts to stress their performance as catalysts - Covers most of the important topics in photocatalysis - Explores the most recent advances in synthesis to enable deeper understanding of the principles underlying electronic behavior of catalytic nanostructures, mechanistic details, and the evaluation of their effectiveness, as well as perspectives in solar light harvesting - Serves as a valuable resource for better understanding of the current state of photocatalysis research and its possible applications in energy domain
Author: Benjamin Nail
Publisher:
ISBN: 9780355969412
Category :
Languages : en
Pages :
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Book Description
Solar energy conversion has the potential to reduce society’s dependence on fossil fuels and to diminish the harmful effects of climate change by generating clean power from the sun. The process of solar hydrogen production by photocatalytic water splitting uses solar energy to generate hydrogen fuels from water and has been explored extensively in recent years as hydrogen is considered a very promising candidate for a clean and renewable solar fuel. However, only a limited number of earth-abundant photocatalysts have been shown to be active for visible-light driven H2 evolution. New advances also continue in photovoltaic (PV) technologies such as hybrid solar cells, devices composed of inorganic semiconductor quantum dots (QDs) mixed with organic conducting polymers. This dissertation will focus on the application of Surface Photovoltage Spectroscopy (SPS) to study photochemical charge transfer processes in nanoscale photocatalysts and on the characterization of charge transfer dynamics occurring in inorganic-organic hybrid solar cell films. Chapter 2 explores a photocatalytic nickel oxide nanoparticle system modified with platinum co-catalyst for photochemical hydrogen generation. Nanocrystals of NiO have increased p-type character and improved photocatalytic activity for hydrogen evolution from water in the presence of methanol as sacrificial electron donor. Surface photovoltage spectroscopy of NiO and NiO–Pt films on Au substrates indicate a metal Pt-NiO junction with 30 mV photovoltage that promotes carrier separation. The increased photocatalytic and photoelectrochemical performance of nano-NiO is due to improved minority carrier extraction and increased p-type character, as deduced from Mott–Schottky plots, optical absorbance, and X-ray photoelectron spectroscopy data. These results are relevant to the understanding of NiO-containing photocatalysts and to the electronic properties of nanoscale metal oxides and junctions. In Chapter 3, surface photovoltage spectroscopy (SPS) was used to study the intrinsic charge transfer properties and surface states of thin films of thiol, amine, carboxylic acid supported CdSe QDs on indium tin oxide (ITO) in the absence of an external bias or electrolyte. On ITO, the QD films give positive or negative photovoltage signals (-120 to +350 mV) under sub band gap and super band gap excitation (0.1 - 0.3 mW cm−2), depending on the ligand type present at the QD surface. Experimental photovoltage values are found to correlate with the LUMO energies of the CdSe QDs, obtained from the electrochemical reduction potential in tetra-n-butylammonium hexafluorophosphate electrolyte at unadjusted pH. This suggests the possibility that the built-in potential of the ITO-QD Schottky contacts is controlled by the electronic properties of the ligands. The findings shed new light on factors controlling photochemical charge separation in films of ligand-stabilized CdSe QDs. Chapter 4 presents a study of a nanoscale doped perovskite photocatalyst, chromium-doped strontium titanate (Cr:SrTiO3). The Cr:SrTiO3 nanoparticles form as well defined cubic-shaped nanocrystals with a mean diameter of 43.5 nm (±18.8 nm) and have homogeneous composition. X-ray photoelectron spectroscopy (XPS) and X-ray absorption near edge structure (XANES) analysis shows that Cr:SrTiO3 particles synthesized at high temperature contain high concentrations of Cr6+ trap sites while hydrothermally synthesized particles contain only Cr3+. SPS data shows that photogenerated charge carriers from Cr3+ donor states can drive photochemical reactions (e.g methanol oxidation) at the particle surface and that those reaction rates are increased by previous light excitation of the film. SPS also shows a dependence of photovoltage magnitude on substrate work function that is explained by the built-in potential (V[subscript bi]) at the film-substrate interface. Photochemical hydrogen evolution experiments show rates of up to 85 [mu]mol/hr (1.56% AQE at 435 nm). Rates are strongly dependent on solution pH, Cr doping %, and particle synthesis method. A mild NaBH4 reduction treatment was shown to increase photocatalytic activity in Cr:SrTiO3 and decrease its Cr6+ concentration. Surface photovoltage spectroscopy (SPS) also reveals an anomalously increasing photovoltage with magnitude greater than the band gap of SrTiO3. A model is proposed to show that the unusually large photovoltage, as well as charge separation in Cr:SrTiO3 in general, can be explained by a light-activated ferroelectric effect that causes ordering of electric dipoles in the non-centrosymmetric Cr:SrTiO3 unit cells.
Author: Fredrick Andrew Frame
Publisher:
ISBN: 9781124508597
Category :
Languages : en
Pages :
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Book Description
The photochemical water splitting reaction is of great interest for converting solar energy into usable fuels. This dissertation focuses on the development of inorganic nanoparticle catalysts for solar energy driven conversion of water into hydrogen and oxygen. The results from these selected studies have allowed greater insight into nanoparticle chemistry and the role of nanoparticles in photochemical conversion of water in to hydrogen and oxygen. Chapter 2 shows that CdSe nanoribbons have photocatalytic activity for hydrogen production from water in the presence of Na2S/Na2SO3 as sacrificial electron donors in both UV and visible light. Quantum confinement of this material leads to an extended bandgap of 2.7 eV and enables the photocatalytic activity of this material. We report on the photocatalytic H2 evolution, and its dependence on platinum co-catalysts, the concentration of the electron donor, and the wavelength of incident radiation. Transient absorption measurements reveal decay of the excited state on multiple timescales, and an increase of lifetimes of trapped electrons due to the sacrificial electron donors. In chapter 3, we explore the catalytic activity of citrate-capped CdSe quantum dots. We show that the process is indeed catalytic for these dots in aqueous 0.1 M Na2S:Na2SO3, but not in pure water. Furthermore, optical spectroscopy was used to report electronic transitions in the dots and electron microscopy was used to obtain morphology of the catalyst. Interestingly, an increasing catalytic rate is noted for undialyzed catalyst. Dynamic light scattering experiments show an increased hydrodynamic radius in the case of undialyzed CdSe dots in donor solution. In chapter 4 we show that CdSe:MoS2 nanoparticle composites with improved catalytic activity can be assembled from CdSe and MoS2 nanoparticle building units. We report on the photocatalytic H2 evolution, quantum efficiency using LED irriadiation, and its dependence on the co-catalyst loading. Furthermore, optical spectroscopy, cyclic voltammetry, and electron microscopy were used to obtain morphology, optical properties, and electronic structure of the catalysts. In chapter 5, illumination with visible light ([lambda]> 400 nm) photoconverts a red V2O5 gel in aqueous methanol solution into a green VO2 gel. The presence of V(4+) in the green VO2 gel is supported by Electron Energy Loss Spectra. High-resolution electron micrographs, powder X-ray diffraction, and selective area electron diffraction (SAED) data show that the crystalline structure of the V2O5 gel is retained upon reduction. After attachment of colloidal Pt nanoparticles, H2 evolution proceeds catalytically on the VO2 gel. The Pt nanoparticles reduce the H2 evolution overpotential. However, the activity of the new photocatalyst remains limited by the VO2 conduction band edge just below the proton reduction potential. Chapter 6 studies the ability of IrO2 to evolve oxygen from aqueous solutions under UV irradiation. We show that visible illumination ([lambda]> 400 nm) of iridium dioxide (IrO2) nanocrystals capped in succinic acid in aqueous sodium persulfate solution leads to catalytic oxygen evolution. While the majority of catalytic hydrogen evolution comes from UV light, the process can still be driven with visible light. Morphology, optical properties, surface photovoltage measurements, and oxygen evolution rates are discussed.
Author: Rachel Lee Chamousis
Publisher:
ISBN: 9781303537905
Category :
Languages : en
Pages :
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Book Description
New, inexpensive and non-polluting energy technologies are of great importance for civilization. A promising source is solar energy, which can be photocatalytically converted into gaseous fuel or electricity. It has been hypothesized that nanomaterials may lead to improved photoelectrochemical (PEC), suspended photocatalytic, and photovoltaic cells. This particular field of study is vast considering the various ways nanomaterials can be synthesized, manipulated, and employed. Here, several different nanomaterials are studied as photocatalysts and as components in photoelectrochemical and photovoltaic cells. The purpose is to better understand charge transfer properties and energetics of these materials, and eventually, to help find a cheap, active, and sustainable photocatalyst for our ever-increasing energy demands. Chapter 1 gives a brief introduction to the field of nanomaterials for solar energy conversion. The motivation for this research is given, water-splitting photocatalysis is explained, and the various ways nanomaterials can be employed are reviewed. Chapter 2 explains how nanomaterials such as titanium dioxide and tungsten oxide can be used to photocatalytically decompose organic contaminants in wastewater while simultaneously producing electricity. Efficiency and power output analysis of derived photoelectrochemical cells revealed the highest published values for titanium dioxide electrodes under 395 nm illumination. Chapter 3 discusses calcium niobate (TBACa2Nb3O10, TBA = tetrabutylammonium) nanosheets as a photocatalyst for hydrogen evolution from aqueous methanol solution under UV illumination. Photoelectrochemical techniques were used to study the effects of ion modification of TBACa2Nb3O10 on the energetics, specifically the position of the Fermi energy. The data shows a direct relationship between the position of the Fermi energy and the relative rate of hydrogen production. Chapter 4 explains the fabrication and function of the first fractal electrode-based organic photovoltaic cells. Although the fractal electrode enhances the interfacial area between the light absorber and electrode, enhanced charge recombination results in reduced photocurrent for fractal silver. Chapter 5 gives a selection of the photoelectrochemical properties of iridium dioxide nanoparticles and single-crystal tungsten oxide nanosheets. The data can be used to calculate the photo-onset values for each material. Chapter 6 gives supporting information on calculating the power conversion efficiency of a PEC cell.
Author: Jiarui Wang
Publisher:
ISBN: 9781339543994
Category :
Languages : en
Pages :
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Book Description
Solar energy is a promising sustainable energy source to reduce greenhouse gas emission from combustion of fossil fuels and slow down the global climate change. Solar hydrogen generation via photocatalytic water splitting is potentially the most cost-effective way to produce solar fuels, so the development of efficient photocatalysts is one of the most important targets for scientific research. However, the application of inorganic materials for solar water splitting is currently limited by our understanding of photochemical charge transfer on the nanoscale, where space charge layers are less effective for carrier separation. Therefore, this dissertation focuses on the preparation of well-defined photocatalysts for the water splitting reaction and on the characterization of photochemical charge transfer on their interfaces. This will be accomplished through the application of surface photovoltage and photoelectrochemical measurements, and with photocatalytic reactivity tests. Results from this study can guide the design of inorganic photocatalysts with improved efficiency for solar energy conversion into fuel. Chapter 2 describes surface photovoltage spectroscopy studies to measure the internal photovoltages in a hydrogen evolution photocatalyst, single crystalline platinum/ruthenium-modified Rh-doped SrTiO3 nanocrystals. Voltages of -0.88 V and -1.13 V are found between the light absorber and the Ru and Pt cocatalysts, respectively, and a voltage of -1.48 V for a Rh-doped SrTiO3 film on an Au substrate. The voltages shows that the Pt and Ru cocatalysts not only improve the redox kinetics but also aid charge separation in the absorber. The voltages with redox agents correlate well with the photocatalytic performance of the catalyst and are influenced by the built-in potentials of the donor-acceptor configurations, the physical separation of donors and acceptors, and the reversibility of the redox reaction. The photovoltage data also allow the identification of a photosynthetic system for hydrogen evolution (80 [mu]mol·g−11h−1) under visible light illumination (>400 nm) from 0.05 M aqueous K4[Fe(CN)6]. Chapter 3 shows that suspended p-Si nanowires obtained by etching of an Al-doped silicon wafer facilitate photochemical hydrogen evolution under visible light. The activity varies greatly between sacrificial donors and can be increased by attachment of MoS2 cocatalysts, which promote proton reduction and charge transfer at the silicon-MoS2 interface. Overall, the activity of suspended p-Si nanorods is limited by the stability of the material in neutral solutions. A basic or neutral environment with photo-excitation can lead to silicon corrosion. In 0.05 M ferrocyanide at pH 6.5, the hydrogen evolution rate for SiNW/MoS2 was as high as 106 [mu]mol (10mg)−1 h−1 accompanied by silicon corrosion. The rate without corrosion decreased to 0.64 [mu]mol (10mg)−1 h−1 at a lower pH of 4.7. With silicon corrosion, the rate also reached 117 [mu]mol (10mg)−1 h−1 in pH 6.5 0.05 M Na2SO3 solution and 678 [mu]mol (10mg)−1 h−1 in 0.1 M NaSH without pH control. Silicon corrosion was not found in formaldehyde and methanol solutions, but the rates of SiNW/MoS2 and SiNW were as low as 0.40 and 0.18 [mu]mol (10mg)−1 h−1 for methanol solution, and 0.71 and 0.27 [mu]mol (10mg)−1 h−1 for formaldehyde solution. The increased hydrogen evolution with silicon corrosion can be attributed to both electron donating of silicon and reduced charge transfer resistivity with the dissolution of surface oxide layer on silicon nanowires. These findings can improve the understanding of photochemistry of Si-MoS2 catalyst, and help avoiding silicon corrosion in photocatalysis.
