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1 ries for a range of research problems beyond photocatalysis.
2 ortant implications in plasmonic facilitated photocatalysis.
3 r splitting by membraneless electrolysis and photocatalysis.
4 ial applications spanning photodetection and photocatalysis.
5 f chemical reactions possible with plasmonic photocatalysis.
6 ment-friendly material for photovoltaics and photocatalysis.
7 xidation reactions for energy conversion and photocatalysis.
8 h as bioimaging, light-emitting devices, and photocatalysis.
9 ations in areas as diverse as biosensing and photocatalysis.
10 hotons to be harnessed for photovoltaics and photocatalysis.
11 eptide oxidation induced by titanium dioxide photocatalysis.
12 plex to serve as a platform for two-electron photocatalysis.
13 direct relevance for their implementation in photocatalysis.
14 ir formation, thus substantially reinforcing photocatalysis.
15 anistic pathway for thiourea-mediated organo-photocatalysis.
16 idely studied model system for heterogeneous photocatalysis.
17 ible-light water splitting and CO2 reduction photocatalysis.
18 mal metal domain size for the most efficient photocatalysis.
19 can participate as a sustainable reagent in photocatalysis.
20 of catalysis, including bio-, electro-, and photocatalysis.
21 n laser sources for studying the dynamics of photocatalysis.
22 combined with other catalytic methods, e.g., photocatalysis.
23 pairs, useful for photocurrent generation or photocatalysis.
24 not compatible with in situ applications in photocatalysis.
25 rom N-(acyloxy)phthalimides by visible-light photocatalysis.
26 specific case, a clear strategic benefit of photocatalysis.
27 ee progress in the field of plasmon-mediated photocatalysis.
28 ilines with alkynes enabled by visible-light photocatalysis.
29 sustainability of Cu-EDTA treatment via TiO2 photocatalysis.
30 applications in photovoltaics, sensing, and photocatalysis.
31 in electrocatalysis, thermal catalysis, and photocatalysis.
32 gy conversion through both photovoltaics and photocatalysis.
33 d provide a novel paradigm for visible-light photocatalysis.
34 cteristic for efficient electron transfer in photocatalysis.
35 ficient catalysts especially in electro- and photocatalysis.
36 ive organic transformations by heterogeneous photocatalysis.
37 rds understanding supramolecular effects and photocatalysis.
38 e of application needs from photovoltaics to photocatalysis.
39 O2 is not an efficient electron scavenger in photocatalysis.
40 y bonded materials relevant for electro- and photocatalysis.
41 osensitizer in hydrogen-evolving homogeneous photocatalysis.
42 ers for fuel cells, and titanium dioxide for photocatalysis.
43 onic metallic nanostructures in the field of photocatalysis.
44 oxides for applications in photovoltaics and photocatalysis.
45 single photon emission, in vivo imaging, and photocatalysis.
46 nductor, and it is an important material for photocatalysis.
47 ies, fuel cells, electrochemical sensors and photocatalysis.
48 cover covalent organic frameworks (COFs) for photocatalysis.
49 nanoantennas for energy-efficient plasmonic photocatalysis.
50 n synergy to promote efficient and selective photocatalysis.
51 ng blocks have been explored for sustainable photocatalysis.
52 rganic chemicals using light irradiation and photocatalysis.
53 thermal processes, but rare in visible-light photocatalysis.
54 complexes are widely recognized and used in photocatalysis.
55 various applications, including electro- and photocatalysis.
56 quantum information and near-infrared driven photocatalysis.
57 for field effect devices, photovoltaics, and photocatalysis.
58 ore for this alternative mode of cooperative photocatalysis.
59 s of thermal catalysis, electrocatalysis, or photocatalysis.
60 omising applications in light harvesting and photocatalysis.
61 red drug delivery, photodynamic therapy, and photocatalysis.
62 t organic framework (TpTt) for heterogeneous photocatalysis.
63 offering intriguing opportunities for solar photocatalysis.
64 een proposed in other systems across dual Ni photocatalysis.
65 ed development of a more holistic science in photocatalysis.
66 ria and disrupts electron transport via NADH photocatalysis.
67 es that can be optimised for applications in photocatalysis.
68 hockley-Queisser limit for photovoltaics and photocatalysis.
69 ed into high charge extraction for efficient photocatalysis.
70 erties and hence mechanisms involved in TiO2 photocatalysis.
71 light-emitting diodes, for biosensing and in photocatalysis.
72 sed in applications such as enantioselective photocatalysis(1), circularly polarized light detection(
73 er across interfaces form the foundation for photocatalysis(1,2), energy harvesting(3) and photodetec
79 echnologies of heating, photovoltaics, water photocatalysis and artificial photosynthesis depend on t
81 hierarchical assemblies in light generation, photocatalysis and conversion of motion to electricity.
88 num, and ruthenium play an important role in photocatalysis and energy conversion applications as wel
91 properties are an ideal platform for organic photocatalysis and exploring atomic-level behaviors.
94 and or adsorbates in colloidal catalysis and photocatalysis and have important implications for the t
97 lar to the products observed earlier in TiO2 photocatalysis and in in vitro phase I metabolism assays
98 ecay, play key roles in applications such as photocatalysis and in photodetectors that circumvent ban
99 g a wide range of technologies, particularly photocatalysis and light-emitting diodes, but they rely
103 , recent strides in bridging the gap between photocatalysis and other areas of catalysis will be high
106 unate in my own research to be able to study photocatalysis and photoinduced electron transfer as uni
112 undamental principles of energy transfer and photocatalysis and provide an overview of the latest pro
114 the role of metal in semiconductor-assisted photocatalysis and size-dependent catalytic activity of
117 ept study provides a new methodology for NIR photocatalysis and would potentially guide future concep
118 properties, such as flexoelectricity, piezo-photocatalysis, and an anomalous photovoltaic effect, de
132 -atypical of the currently known homogeneous photocatalysis-and features the storage of multiple redo
133 to the BiOBr/MO system, the sulfite-assisted photocatalysis approach has been successfully demonstrat
134 strategies for enhancing the selectivity in photocatalysis are abridged to reinvigorate and stimulat
138 direct implications for understanding TiO(2) photocatalysis as well as the surface modifications invo
139 om thermal catalysis to hot-carrier-mediated photocatalysis, as reported very recently in Zhou, L.; e
140 g the fundamental principles of electro- and photocatalysis, as well as for developing highly efficie
141 alysis, heterogeneous catalysis, optical and photocatalysis, as well as magnetism and conclude the re
142 apacitors, fuel cells, photovoltaic devices, photocatalysis, as well as Raman enhancement are describ
143 d ultrafast in situ infrared spectroscopy of photocatalysis at an n-SrTiO3/aqueous interface, we reve
149 ity spectroscopies, light energy harvesting, photocatalysis, biomedical imaging and theranostics, opt
150 hose recently discovered using visible-light photocatalysis but without the use of an expensive photo
152 im of overcoming the existing limitations of photocatalysis by developing more creative synthetic met
153 m two perspectives, namely, the promotion of photocatalysis by thermal energy and the promotion of th
155 ethods such as that used in this study bring photocatalysis closer to being a viable water treatment
158 he long-standing popularity of semiconductor photocatalysis due to its great potential in a variety o
161 rsuing the stem of g-C3N4 related catalysis (photocatalysis, electrocatalysis and photoelectrocatalys
162 d to solar energy conversion (photovoltaics, photocatalysis), electrochemical energy storage, and the
163 ies and it is widely applied, for example in photocatalysis, electrochemical energy storage, in white
164 ropes in a number of applications (including photocatalysis, electrochemistry, electronics and optoel
166 Visible-light-activated transition metal photocatalysis enables the use of ammonium persulfate as
167 ategies which can improve the selectivity of photocatalysis encompassing a wide variety of photocatal
169 structural effects on obvious far red-to-NIR photocatalysis enhancement, which originates from (1) En
171 MPC-1-coated vessels enable batch and flow photocatalysis, even with opaque reaction mixtures, via
173 he role of hydrogen bonding in enhancing the photocatalysis for CO(2) reduction through supramolecula
175 the catalyst species lead to oxygen-mediated photocatalysis for the Cr-containing complex but radical
177 eactions and exhibit enhanced performance in photocatalysis, gas sensing and as Li-ion battery electr
181 Coupling a reversal of this methodology with photocatalysis has been demonstrated to allow the rapid
186 of catalytic behavior but its application in photocatalysis has inherent difficulties due to the natu
190 e intermediates accessible via visible light photocatalysis, has accelerated the development of this
191 acid based organocatalysis and visible-light photocatalysis have both emerged as promising technologi
193 ed chemical transformations.Plasmon-enhanced photocatalysis holds promise for the control of chemical
196 an advanced oxidation process (heterogeneous photocatalysis (HPC)) were used to disinfect urban WW to
197 water-stability has been applied to promote photocatalysis in aqueous medium, in particular by devis
198 force analysis, unveiled the crucial role of photocatalysis in both initiating and sustaining a Ni(I)
201 photogenerated carriers for high efficiency photocatalysis in the hydrogen evolution half-reaction,
202 the transferred electrons in the Pt tip and photocatalysis in the presence of sacrificial hole accep
204 ation and focus on understanding the role of photocatalysis in the product generation and authenticat
205 2 complexes that participate in HX-splitting photocatalysis in which metal-metal cooperation is credi
207 anoparticles show promising applications for photocatalysis, including light-driven H(2) production.
213 In recent years, the field of selective photocatalysis is developing rapidly and now extended to
214 cal studies revealed that the enhancement in photocatalysis is due not to differences in intrinsic pr
215 ydrogen production from water by electro- or photocatalysis is of current scientific and technologica
216 f the benefits of compounds showing TADF for photocatalysis is presented, which paints a picture of a
217 to DNA or to tubulin, and red light (660 nm) photocatalysis is used to initiate a cascade of DHTz oxi
219 been performed to understand the underlying photocatalysis mechanism of the nitrogen-doped titania n
220 ent uncovers a hot plasmonic electron-driven photocatalysis mechanism with an identified electron tra
221 applications such as contaminant adsorption, photocatalysis, membrane-based separation, sensing, and
222 w of their special role in special selective photocatalysis, namely epoxidation reactions, among othe
224 Under dry, anaerobic conditions, TiO(2) photocatalysis of carboxylic acid precursors resulted in
225 ihot to study the adsorption, desorption and photocatalysis of carminic acid on these materials.
226 These results expand the current view on the photocatalysis of CH3OH on TiO2(110) by highlighting the
228 describe the synthesis through visible-light photocatalysis of novel functionalized tetracyclic scaff
229 mbination of adsorption, biodegradation, and photocatalysis of triclosan by algae and P25, triclosan
230 t band gap of around 2.0 eV, the optimum for photocatalysis of water splitting, is readily accessible
231 visible-light organic photoredox catalysis (photocatalysis) of methylene blue chromophore with a sac
233 s and observations of crystal-face-dependent photocatalysis on anatase, and support the idea that opt
235 Photo-thermo catalysis, which integrates photocatalysis on semiconductors with thermocatalysis on
237 ovides a desirable platform for eco-friendly photocatalysis, optoelectronic devices, biolabeling, and
238 tracted tremendous attention in the field of photocatalysis, owing to their superior optoelectronic p
239 find in the emerging fields of electro- and photocatalysis, particularly in the context of the susta
242 n generation is beneficial, such as in solar photocatalysis, photodetectors and nonlinear devices.
243 ith wide applications to photosensitization, photocatalysis, photodynamic therapy, photovoltaic conve
244 catalysis including heterogeneous catalysis, photocatalysis, photoelectrocatalysis and electrocatalys
248 The study also shows that titanium dioxide photocatalysis provides a fast and easy method to study
249 ntenna-reactor heterostructures in plasmonic photocatalysis provides a sustainable route to high-valu
250 heterogeneous catalytic systems (thermal and photocatalysis) require noble metals or harsh reaction c
252 main applications in thermo-, electro-, and photocatalysis, revealing trends in element-specific evo
253 iconductor sensitisers, to promote reductive photocatalysis, RP, especially of dyes, is significant a
254 catalysts in bimolecular and supramolecular photocatalysis schemes for proton reduction is briefly r
255 prove its performance in the applications of photocatalysis, solar cells, Li batteries, and transpare
256 operties of COFs for applications related to photocatalysis, solid-state light emitters, and chemical
259 ient way to overcome important challenges in photocatalysis, such as controlling catalytic activity a
260 gradation by visible light (lambda > 400 nm) photocatalysis suggested that adsorbed OFX-ClO(4)(-) ion
261 size their applications in electrocatalysis, photocatalysis, supercapacitors, batteries, and photovol
263 ls and in sensitizer-catalyst assemblies for photocatalysis that operate with irradiation from the ul
264 sively as stoichiometric electron donors for photocatalysis, the controlled modification of amine sub
266 The sensitizer is regenerated during the photocatalysis; therefore, 4-CP effectively reduces the
267 cross-cut energy conversion (photovoltaics, photocatalysis, thermoelectrics), energy storage (lithiu
268 oduction of pharmaceutics and food, bio- and photocatalysis, thin-film solar cells and antibacterial
269 ely detailing RP's roles and implications in photocatalysis, this review article will first include i
271 to the application of visible light-mediated photocatalysis to a challenging bond construction in a c
273 t a comprehensive, mechanistic evaluation of photocatalysis to better understand how composition rela
274 nanosystems into synthetic applications from photocatalysis to optical devices need to demonstrate in
275 ess in the application of nanogold plasmonic photocatalysis to organic transformations and energy con
277 selectively converted to CO with almost same photocatalysis to that under a pure CO2 atmosphere (TONC
280 ompared to the conventional cooperative/dual photocatalysis (type B), this new class of unconventiona
281 able solution that relies upon decatungstate photocatalysis under acidic conditions using either H2 O
285 ucleobases were synthesized by visible light photocatalysis using rhodamine 6G as photoredox catalyst
286 e state-of-the art of plasmon-based nanogold photocatalysis using visible light including fundamental
290 ytic reactions, such as reforming processes, photocatalysis, water-gas shift reaction, thermochemical
291 Using electrochemical CO(2) reduction and photocatalysis, we demonstrate that the structural pecul
292 mocatalysis and Pd-TiO(2) for H(2) evolution photocatalysis) were used to showcase the universal impo
294 l to the fields of organic photovoltaics and photocatalysis, where it is necessary to funnel energy o
295 inal ring was achieved through visible light photocatalysis, wherein carbon-carbon bond formation was
296 o enhance the absorption of light and afford photocatalysis with MOFs under visible-light irradiation
298 antages of both homogenous and heterogeneous photocatalysis, with the molecular components providing
299 rding plasmon-driven chemistry and nanoscale photocatalysis within optically confined near-field plas
300 ct reaction of arenes and alkyl amines using photocatalysis, without the need for pre-functionalizati