ライフサイエンスコーパス: photochemistry

1 oduction to these aspects of 'Supramolecular Photochemistry'.

2 ified while applying them to 'Supramolecular Photochemistry'.

3 eld that is emerging as a distinct branch of photochemistry.

4 s") and is accelerated by light through NADH photochemistry.

5 me range, to propose a new mechanism for the photochemistry.

6 on migration is a key process in hydrocarbon photochemistry.

7 standing and theoretical description of RPSB photochemistry.

8 otope exchange with water, and stratospheric photochemistry.

9 degradation of organic compounds via aquatic photochemistry.

10 tive damage--currently not considered in DNA photochemistry.

11 o 750 nm for absorbance of light that drives photochemistry.

12 which is in accord with the results from the photochemistry.

13 show by mutagenesis to be critical for BphP photochemistry.

14 maximum quantum efficiency of photosystem II photochemistry.

15 is ALW on reactive gas budgets and gas-phase photochemistry.

16 o the red region than was reported for PS II photochemistry.

17 enhancing daytime HONO formation from NO3(-) photochemistry.

18 ment for the efficient design of tailor-made photochemistry.

19 ne of the oldest and best known reactions in photochemistry.

20 ucture may have a functional role in initial photochemistry.

21 chnique in probing molecular excitations and photochemistry.

22 e Na(+), this does not compromise their leaf photochemistry.

23 eaction efficiencies in hot-electron-induced photochemistry.

24 dge with regard to both emission factors and photochemistry.

25 noplasmonic device engineering and nanoscale photochemistry.

26 e light-activated signaling based on similar photochemistry.

27 involvement of the I675* intermediate in POR photochemistry.

28 voidable damage that results from its normal photochemistry.

29 ically incompetent to readily perform useful photochemistry.

30 ensitized triplet-triplet annihilation (TTA) photochemistry.

31 ium and photoredox behavior in anthraquinone photochemistry.

32 nt for these distinct classes of red/far-red photochemistry.

33 onstrate the influence of DOM composition on photochemistry.

34 mpounds, with potential implications for DOM photochemistry.

35 es that offer a unique opportunity for solar photochemistry.

36 cal cascade reaction through the use of flow photochemistry.

37 cids in aqueous buffer led to a pH-dependent photochemistry.

38 ite, a model for clay minerals, to prebiotic photochemistry.

39 Herein, we extend this tactic to organic photochemistry.

40 rategies that have been applied to synthetic photochemistry.

41 interesting amino acids can form through ice photochemistry.

42 rtant trace gas and regulator of atmospheric photochemistry.

43 trol of light propagation, light capture and photochemistry.

44 ns regarding the use of PCs in environmental photochemistry.

45 yll excited states through electron transfer photochemistry.

46 cations for urban climate, ecohydrology, and photochemistry.

47 o both coenzyme B12 enzymology and its known photochemistry.

48 o ongoing and possible future changes in the photochemistry active over the Amazon rainforest.

49 30% of the total natural transformation, (2) photochemistry also contributed 30%, such that its contr

50 hat the AzoAMP-1 and -2 retain excited state photochemistry analogous to azobenzene was provided by u

51 e rational redesign of plant Phys with novel photochemistries and signaling properties potentially be

52 Compounds VI and VII are formed by photochemistry and are not reported as human metabolites

53 ate matter aid understanding of tropospheric photochemistry and are required for estimates of the dir

54 ffy, fractal aggregate particles produced by photochemistry and auroral chemistry dominates the strat

55 riverine DOM and, thus, estuarine optics and photochemistry and bioavailability.

56 ant but sometimes opposing influences on the photochemistry and biological activity of pHP phototrigg

57 multaneously measuring the quantum yields of photochemistry and chlorophyll fluorescence in situ, we

58 crucial for understanding their fundamental photochemistry and controlling their photoreactivity.

59 acellular loops is also required for optimal photochemistry and efficient G protein activation.

60 g and maximum efficiencies of photosystem II photochemistry and lower leaf and whole-plant water use

61 e motion results from a complex interplay of photochemistry and mechanics.

62 proteins, highlighting the interplay between photochemistry and other channels (fluorescence, radiati

63 stry are likely to have wider application in photochemistry and other reactions.

64 teractions could be exploited for tuning the photochemistry and photophysics of organic chromophores.

65 suffer from limitations associated with dye photochemistry and photophysics, or the requirement for

66 The photochemistry and photosensitizing properties of the ki

67 structural and dynamic origins of efficient photochemistry and provides critical experimental inform

68 found to have a lower quantum yield of PSII photochemistry and reduced PSII electron transport rate

69 The use of photonic crystal fibre in photochemistry and sensing is discussed and recent resul

70 al and practical importance, particularly in photochemistry and solar energy applications.

71 Based on the analysis of the photochemistry and structure of BphPs we suggest a varie

72 e of application-driven research, azobenzene photochemistry and the isomerization mechanism remain to

73 that copper species are engaged in both the photochemistry and the key bond-forming step, which occu

74 r a 7-day period and examined for changes in photochemistry and transcript abundance.

75 e Precambrian atmosphere and to document the photochemistry and transport properties of the modern at

76 us affect atmospheric radiative transfer and photochemistry and with that climate and air quality.

77 We describe the synthesis, structure, photochemistry, and activity against multidrug-resistant

78 n dioxide assimilation rates, photosystem II photochemistry, and linear electron flow.

79 include catalysis, new energy technologies, photochemistry, and medicine, among others.

80 s including industrial wastewater treatment, photochemistry, and photodynamic therapy.

81 embled monolayers, plasma-polymerized films, photochemistry, and sensing ionic liquids-used to functi

82 ks (MOFs) are attractive compounds for solar photochemistry applications.

83 The major products of this photochemistry are covalently bonded dimers and trimers

84 h this process deviates from typical quinone photochemistry are discussed.

85 addition, the advantages of continuous-flow photochemistry are pointed out and a thorough comparison

86 ents are discussed within the context of the photochemistry, arrestin binding and turnover of the vis

87 These data provide insight into DOM photochemistry as well as provide parameters useful for

88 is one of the most fundamental quantities in photochemistry, as it measures the efficiency of the tra

89 cts of atmospheric particles on tropospheric photochemistry, as well as possible inaccuracies in some

90 The effect of sea salt on NO(3)(-) photochemistry at 311 nm was investigated at 298 K using

91 Anthraquinones undergo photochemistry at a wavelength where the endoperoxide is

92 be electrophoresis of colloids generated by photochemistry at an indium tin oxide-coated substrate.

93 t oxygen dependencies imply that oxalic acid photochemistry at the authentic surfaces under study was

94 nt protein complex, couples the one-electron photochemistry at the reaction centre with the four-elec

95 sent study, we have investigated oxalic acid photochemistry at the surface of Fe(2)O(3), TiO(2), Maur

96 the far-red light absorption leading to PS I photochemistry at wavelengths up to 840 nm.

97 Photodynamic therapy (PDT), a photochemistry-based cytotoxic modality, sensitizes ovar

98 Photochemistry, bearing significant applications in natu

99 s are of interest for fundamental studies in photochemistry because of their strong absorption in the

100 ical tissues is thought to reflect marine Hg photochemistry before biouptake and bioaccumulation.

101 nd accomplishments of performing research in photochemistry between 1960 and the present time are emp

102 These studies demonstrate that photochemistry can be a powerful tool for inducing redox

103 ating how conserved protein architecture and photochemistry can be elaborated into a range of light-d

104 ates that this unusual example of rare-earth photochemistry can be rationalized by absorptions involv

105 nm) radiation, we find that condensed-phase photochemistry can induce significant changes in SOA par

106 opment of electronic spin and supramolecular photochemistry chemistry.

107 ensitized triplet-triplet annihilation (TTA) photochemistry, confirmed by the quadratic dependence of

108 is not currently accounted for by known bulk photochemistry, consistent with recent laboratory observ

109 Challenging photochemistry demands high-potential visible-light-abso

110 Proteins involved in light harvesting, photochemistry, electron transport and ATP synthesis are

111 During the Program for Research on Oxidants: Photochemistry, Emissions and Transport (PROPHET) summer

112 mate models, will likely lead to more active photochemistry, enhanced biogenic isoprene and fire emis

113 h are both required to initiate conventional photochemistry essential for ozone production, are at a

114 an water, we believe that the supramolecular photochemistry expounded here has a momentous role as a

115 ve greatly advanced the understanding of its photochemistry, extrapolation of the conclusions to the

116 ations in the kinetics and efficiency of LOV photochemistry fine-tune various aspects of the photic r

117 action of absorbed photons that are used for photochemistry for a light-adapted measurement from a pu

118 he author in the area of mechanistic organic photochemistry from the primitive state of this field in

119 conductance mechanisms and their underlying photochemistry, further confirming that these proteins f

120 maximum quantum efficiency of photosystem II photochemistry (Fv /Fm ), carotenoids, and reactive oxyg

121 nce transition formerly ignored in classical photochemistry has been found for maleimides.

122 Visible-light-driven photochemistry has continued to attract heightened inter

123 scales and at low temperature, metal-hydride photochemistry has enabled determination of the molecula

124 Merging with polymerization techniques, photochemistry has opened up new intriguing and powerful

125 ing-opening polymerization and thiol-ene/yne photochemistry in aqueous solution, allowing the mild in

126 of iodine chemistry and the role of snowpack photochemistry in Arctic atmospheric composition, and im

127 Here we describe the photochemistry in CarH that ultimately triggers tetramer

128 , indicating the ubiquity of DOM in indirect photochemistry in environmental ices.

129 raging the advantages of utilizing gases and photochemistry in flow, a commercially available organic

130 Continuous-flow photochemistry in microreactors receives a lot of attent

131 High-resolution mapping of cofactor-specific photochemistry in photosynthetic reaction centers (RCs)

132 o the trends observed when comparing retinal photochemistry in protein and solution environments.

133 Rapid assessment of laser-induced photochemistry in single microdroplets is afforded by on

134 Extending on this, to probe laser-initiated photochemistry in single picoliter volumes, a UV laser p

135 llows for rapid detection of laser-initiated photochemistry in single picoliter volumes.

136 unlight absorption in snowpack; however, DOM photochemistry in snow/ice has received little attention

137 The results further suggest that photochemistry in SOM may play a key role in transformat

138 would be a novel potential nanomodulator of photochemistry in the agricultural sector.

139 e re-evaluated the mechanism for early stage photochemistry in the light-driven reduction of Pchlide

140 tion of the OH free radical from nitrite ion photochemistry in the presence of water and its addition

141 Photochemistry in the solar nebula has been attributed a

142 to chondrites, which have been attributed to photochemistry in the solar nebula.

143 aspects of the nitrogen fixation process by photochemistry in the Titan atmosphere are not fully und

144 ing photoproducts and metabolites, pesticide photochemistry (including the use of structural optimiza

145 sulfur dioxide and carbonyl sulfide) via SOx photochemistry, including photoexcitation and photodisso

146 cies (ROS) are known to be produced from DOM photochemistry, including singlet oxygen, 1O2.

147 inetics of NH3 uptake and NOx formation from photochemistry initiated on irradiated (lambda > 290 nm)

148 Photochemistry is a key environmental process directly l

149 Photochemistry is a largely unconsidered potential sourc

150 ield and laboratory studies suggest that NO3 photochemistry is a more important source of HONO than o

151 ics is plausible, provided that catalysis or photochemistry is available to sufficiently lower reacti

152 The photochemistry is described by the superposition of two

153 The small part of energy that is not used in photochemistry is dissipated as heat or re-emitted as fl

154 by the A215T mutation and to assess what new photochemistry is likely to be introduced into the BR ph

155 Furthermore, we validate that photochemistry is one of the main processes that shapes

156 Among these, photochemistry is particularly well suited because these

157 amounts of unlabeled thymidine before the SP photochemistry is performed.

158 detailed mechanistic proposal for isoxazole photochemistry is presented.

159 The photochemistry is promoted with either standard UV irrad

160 ing on the task at hand, fluorescent protein photochemistry is regarded either as an asset facilitati

161 istic understanding on how NPF is related to photochemistry is still rather limited.

162 own as a powerful activation mode in organic photochemistry, it is surprising to recognize that photo

163 The photochemistry itself provides a rare example of one ele

164 ction of recent laboratory work on gas phase photochemistry, kinetics and reaction dynamics of radica

165 and volatile organic compounds (VOCs), whose photochemistry leads to production of ozone, a secondary

166 ts provide evidence that solid-phase aerosol photochemistry may influence the atmospheric lifetime of

167 A zero-dimensional photochemistry model was constrained to Cl2 observations

168 cluding use in catalysis, enzyme inhibition, photochemistry, molecular logic and materials, e.g. poly

169 It was found that at 295 K PS I photochemistry, observed as P700 (+) formation, was func

170 atalytic cycle that couples the one-electron photochemistry occurring at the PS II reaction center wi

171 It is shown that the photochemistries of the two isomers, 1-methyl-(1H)-tetra

172 The photochemistry of 1-methyl-4-phenyl-1H-tetrazole-5(4H)-t

173 ned by the results of cursory studies of the photochemistry of 1-phenyl-1,3-butadiene and 4-phenyl-1-

174 The photochemistry of 2-naphthylsulfonyl azide (2-NpSO(2)N(3

175 The aqueous photochemistry of 2-oxooctanoic acid (a single-tailed su

176 The unimolecular photochemistry of 3,5-dimethylisoxazole (1) induced by a

177 The molecular structure and photochemistry of 5-thiosaccharyl-1-methyltetrazole (TSM

178 The photophysical properties and photochemistry of [Ru(cyTPA)(CH3CN)2](2+) (1), [Ru(1-iso

179 The photochemistry of a molecular pentad composed of a centr

180 The photochemistry of a new photoaffinity labeling (PAL) age

181 The photochemistry of a p-biphenylyl diazo ester (BpCN2CO2CH

182 The photochemistry of a series of 9,10-anthraquinones with m

183 The aqueous phase photochemistry of a series of amphiphilic alpha-keto aci

184 The investigation of the photochemistry of a two-stage photobase generator (PBG)

185 vis/IR spectroscopies were used to study the photochemistry of a vinyl diazo ester PhCH=CHCN2CO2CH3 (

186 This tutorial review will introduce the photochemistry of activation, reactive intermediates, me

187 synthesis, crystallization, and solid state photochemistry of acyclic, homochiral, hexasubstituted (

188 role of solvation by coadsorbed water in the photochemistry of adsorbates at solid interfaces and the

189 The photochemistry of an aqueous suspension of goethite in t

190 his mechanistic study fully rationalized the photochemistry of aniline photocages which is important

191 diagnostic tools to investigate the aquatic photochemistry of aromatic amines.

192 ompared to results from a prior study of the photochemistry of As(III) in the presence of another iro

193 The photochemistry of azidopyridine 1-oxides was studied usi

194 The photochemistry of benzylallene was studied in a pump-pro

195 The solution photochemistry of bis(phenylpyrrolidinonyl)ketones (R,R)

196 ith O2(-) and their likely importance in the photochemistry of CDOM, we suggest that coproduced pheno

197 has important implications for the oxidation photochemistry of CdS nanocrystals.

198 ractionation associated with the mesospheric photochemistry of CO(2) or temperature-dependent isotopi

199 The Type-A photochemistry of cyclohexadienones is well-studied and

200 t to UV irradiation throughout life, and the photochemistry of damage proceeds through the excited st

201 The photochemistry of diazocyclohexadienone (1), o-phenylene

202 The photophysics and photochemistry of DNA is of great importance due to the

203 pairs, with possible implications for the UV photochemistry of DNA.

204 We propose that the photochemistry of Earth-abundant minerals with wide band

205 importance of different spin channels in the photochemistry of Fe(CO)5, was made possible by the abil

206 knowledge-based rational design based on the photochemistry of fluorescent proteins and the position

207 resent study, we investigated the uptake and photochemistry of FTOHs at the surface of TiO2, Fe2O3, M

208 d aerosol generated by far ultraviolet (FUV) photochemistry of gas mixtures containing 0.1% of either

209 ward a detailed investigation of the aqueous photochemistry of larger cage fullerene species, by focu

210 nimal unit capable of performing the primary photochemistry of light-driven charge separation and wat

211 The photochemistry of matrix-isolated isoxazole, induced by

212 dination with Zn(2+), demonstrating that the photochemistry of metal-bound His is different from that

213 stable metal-nitrosyl linkage isomers in the photochemistry of metal-nitrosyl compounds in chemistry

214 We present insight into the photochemistry of miniSOG and ascertain the reasons for

215 Photochemistry of mycolactone A/B and related unsaturate

216 orbed nitrate, yet little is known about the photochemistry of nitrate on the surface of these partic

217 ntal insights into the surface chemistry and photochemistry of numerous probe molecules on various su

218 Here, we review the photophysics and photochemistry of organic fluorophores as they pertain t

219 e derivatives, yet few have investigated the photochemistry of other larger cage fullerene species (e

220 gement with ring contraction paralleling the photochemistry of p-hydroxyphenacyl esters.

221 te (T1, (3)pipi*) in the ultraviolet-induced photochemistry of pentane-2,4-dione (acetylacetone, AcAc

222 The photochemistry of phosphonium salts is controlled by the

223 Although the photochemistry of plant CRYs has been studied in some de

224 The benzazirine was generated in situ by the photochemistry of protium and deuterated triplet 2-formy

225 and demonstrate that it results in improved photochemistry of PSII.

226 Here we report the crystallization and solid photochemistry of six quaternary ammonium salts of 2,4-d

227 f bacterial spores is a result of the unique photochemistry of spore DNA, which results in accumulati

228 better understanding of the photophysics and photochemistry of sunscreen molecules selected by nature

229 4 represents a novel reaction pathway in the photochemistry of tetrazoles and seems to be characteris

230 r can be assembled combining the established photochemistry of the 2-nitrobenzyl photocage with the o

231 sformations of LMCT photochemistry, the LMCT photochemistry of the Au(III) centers allows for the unp

232 described, the initial events that underpin photochemistry of the coupled bilin chromophore and the

233 years, Ciamician's prophetic vision of "the photochemistry of the future" as a clean and green manuf

234 The photochemistry of the hydroxybenzocycloalkanonyl derivat

235 esting C5H6 isomers, in contrast to the rich photochemistry of the parent C3H2 system.

236 onstitutes a framework for understanding the photochemistry of the photosensitizer KillerRed.

237 The photochemistry of the sterically congested complex 4 was

238 urrently grown beyond fundamental studies on photochemistry of the switches and DNA duplex stability,

239 we have been able to study the dissociative photochemistry of the triiodide anion (I3(-)) in single-

240 The photochemistry of the widely used photoaffinity labeling

241 The photophysics and photochemistry of these hairpins were investigated using

242 ofound consequences for the photophysics and photochemistry of these materials.

243 -methyl-substituted 5-aminotetrazoles on the photochemistry of these molecules is evaluated.

244 We describe the photochemistry of these systems and explore applications

245 The mechanism provides insight into the photochemistry of TiO(2) and suggests general synthetic

246 The photochemistry of Trp and the participation of DOM have

247 The photochemistry of two isomeric aryl diazo ketones was in

248 Our research on the triplet photochemistry of vinylcyclopropenes has dealt with a di

249 ructure (XANES) was used to characterize the photochemistry of vitamin B12, cyanocobalamin (CNCbl), i

250 This work has implications for the photochemistry of waters undergoing natural or engineere

251 are found to be quite unlike the well-known photochemistry on lower electronic surfaces.

252 ns from the rTCA cycle were accomplished via photochemistry on semiconductor minerals, the synthesis

253 ut questions remain regarding the effects of photochemistry on SOA growth.

254 ults will provide insight into the impact of photochemistry on the fate of oil in environmental syste

255 e, which points toward a strong influence of photochemistry on these species.

256 nge of fields, including catalysis, sensing, photochemistry, optoelectronics, energy conversion and m

257 e oxidation; whether these are the result of photochemistry or an instrumental artifact from ion-mole

258 ds) and a survey of transition metal hydride photochemistry organized by transition metal group compl

259 ted enol form does not lead to any ultrafast photochemistry other than proton transfer followed by ro

260 that Synechococcus spp. are able to regulate photochemistry over a range of temperatures by using sta

261 lays an important role in middle atmospheric photochemistry, particularly in ozone (O(3)) chemistry.

262 By utilizing a powerful flow photochemistry platform developed in our laboratory, we

263 presence of oxygen, suggest that Ti-mediated photochemistry played an important role.

264 widespread application in molecular biology, photochemistry, polymer chemistry, quantum optics and su

265 However, compared to the gas phase, the photochemistry proceeds completely differently by virtue

266 bene species while diazocyclohexadienone (1) photochemistry proceeds mainly by a concerted process.

267 anding and uncertainties of the main halogen photochemistry processes, including the current knowledg

268 Indeed, aromatic rings show a rich photochemistry, ranging from isomerizations, substitutio

269 of their signal transduction mechanisms and photochemistry remain poorly understood.

270 of the Martian surface, activated by surface photochemistry, render the present-day surface more unin

271 DOM* are crucial transients in environmental photochemistry responsible for contaminant transformatio

272 ltaneously connecting them to the underlying photochemistry responsible for graphene oxide's reductio

273 To quantify the effects of an advanced iron photochemistry scheme, the chemical aqueous-phase radica

274 The simulations showed that Fe(III) photochemistry should not be neglected when considering

275 The concepts of 'Molecular Photochemistry' should be modified while applying them t

276 s for the facile production of reagents with photochemistry that can be engineered for specific appli

277 ns, we observed an undescribed phenomenon in photochemistry that dictates reactivity of maleimide gro

278 uest interactions; (iv) the photophysics and photochemistry that lead to photochromism; and (v) appli

279 we provide a quantitative assessment of the photochemistry that leads to these extreme winter ozone

280 l one-electron redox transformations of LMCT photochemistry, the LMCT photochemistry of the Au(III) c

281 ecting the bilin-binding pocket that altered photochemistry, thermal stability, and/or nuclear locali

282 , e.g., in anion recognition, catalysis, and photochemistry, thus going far beyond the original purpo

283 tic strategy that exploits two bioorthogonal photochemistries to achieve reversible immobilization of

284 nt; 2), an average reduction in the yield of photochemistry to 0.2; and 3), an increased nonphotochem

285 placement exists to link the reaction center photochemistry to cyclic electron transfer as well as re

286 Here we analyze phytochrome structure and photochemistry to describe the molecular mechanisms by w

287 The coupling of photochemistry to protein chemical and structural change

288 aboratory measurements of the kinetics of IC photochemistry, to analyze IC-photosensitized SOA format

289 e the roles of fire aerosols in ozone (O(3)) photochemistry using an online coupled meteorology-chemi

290 ollagen cross-linking through UVA-riboflavin photochemistry (UVAR) has been shown to be an effective

291 ed in low-temperature argon matrices and its photochemistry was characterized by means of infrared sp

292 rn the absorption cross section serving PSII photochemistry was down-regulated in T. pseudonana throu

293 s of 2-phenylphenol were prepared, and their photochemistry was investigated.

294 The far-red limit of photosystem I (PS I) photochemistry was studied by EPR spectroscopy using las

295 Via organic synthesis and DNA photochemistry, we selectively labeled the 6-H(proS) or

296 Understanding the differences in photochemistry, which originate from substitution, is im

297 anet could have been facilitated by sunlight photochemistry, which played a significant role in the c

298 early work in the field of physical organic photochemistry, which, in turn, guided me to my current

299 cetonitrile solution resulted in ligand loss photochemistry with a quantum yield of 5 x 10(-5).

300 rforming high-throughput nano- to macroscale photochemistry with relevance to biology and medicine.