ライフサイエンスコーパス: photophysical

1 mical fluorophores offer tremendous size and photophysical advantages over fluorescent proteins but a

2 Photophysical analysis of (th) G reveals the existence o

3 Photophysical and DFT studies indicate a light-initiated

4 alculations accurately modelled the observed photophysical and electrochemical behavior of the comple

5 The proposed process is supported by photophysical and electrochemical data.

6 phenes to the TAPP core on their structural, photophysical and electrochemical properties has been st

7 their conducting properties as well as their photophysical and electrochemical properties in solution

8 The photophysical and electrochemical properties of the prod

9 Their photophysical and electrochemical properties were invest

10 The complex was found to exhibit rich photophysical and electrochemical properties.

11 Photophysical and electrochemical studies established th

12 (+) and [Ru(2+), 2Br(-)], each with distinct photophysical and electron-transfer properties.

13 Investigation of the photophysical and electronic properties together with th

14 ations in the five-member heterocycle affect photophysical and electronic properties.

15 Experiments reveal a dependence of photophysical and electronic structure on the nature of

16 and structure were employed to elucidate the photophysical and ET processes in the prepared fullereti

17 This survey provides an overview of the photophysical and imaging properties of a range of SNAP-

18 Photophysical and interface sensitive measurements revea

19 The synthesis and electrochemical, photophysical and intrinsic properties of fused D-A syst

20 A mechanistic model based on detailed photophysical and isomerization kinetic studies is provi

21 diation in nucleotides initiates a number of photophysical and photochemical processes, which may fin

22 exploration of the pathway and mechanism of photophysical and photochemical processes.

23 of a unified mechanistic framework where the photophysical and photochemical properties of the cataly

24 benzene moiety can lead to marked changes in photophysical and photochemical properties, providing an

25 ing realized that possess exciting chemical, photophysical and thermal properties that are not possib

26 blies that could find use in a wide range of photophysical applications.

27 ansfer characterization by means of advanced photophysical assays.

28 r design possibilities have enabled exciting photophysical attributes including narrower emission spe

29 The isomers are similar in their photophysical behavior but very different in their photo

30 Photochemical and photophysical behavior of molecules in supramolecular as

31 The photophysical behavior of the cyanines was investigated

32 rted to N(tz)ADH, reflecting a complementary photophysical behavior to that of the native NAD(+)/NADH

33 The photophysical behavior, high quantum yield, and stabilit

34 s elucidate the electronic structure and the photophysical behavior.

35 These unique photophysical behaviors are rationalized by electronic c

36 In particular, heterogeneous photophysical behaviors of these proteins, which cannot

37 ing of the quantum-mechanical origin of this photophysical behaviour is limited.

38 cond factor contributing to the spectral and photophysical changes is cluster transformation.

39 ng into account solvent-induced spectral and photophysical changes of the labels, leads to deviations

40 Next, photophysical characteristics are presented, setting the

41 Together, these photophysical characteristics determine imaging performa

42 monstrate the ability to resolve the diverse photophysical characteristics of different library types

43 need for a review dedicated to the redox and photophysical characteristics of easily accessible boran

44 The molecular design strategies, photophysical characteristics, and device performance re

45 We performed detailed photophysical characterization and kinetic modeling of f

46 As expected, photophysical characterization clearly shows increasing

47 The synthesis and photophysical characterization of a chromophore-bridged

48 les as emitters and transporters, a detailed photophysical characterization of molecules 4-6 was carr

49 The synthesis, electrochemical, and photophysical characterization of N,N'-dialkylated and N

50 We report the synthesis and basic photophysical characterization of strongly conjugated hy

51 For the latter systems, the photophysical characterization of their ground- and exci

52 thracene-2,3-dicarboximide) (6-DMA), and the photophysical characterization of this fluorophore are d

53 Photophysical characterization revealed that the 1- and

54 ed at a greater rate than their quantitative photophysical characterization; a quantitative identific

55 here has been little characterization of the photophysical consequences of using chemical tags with o

56 Bulk and single molecule photophysical data for FDN probes are compared to single

57 ctures, cyclic voltammetry, and spectral and photophysical data of the compounds are presented.

58 We also present photophysical data pertaining to the efficiency of elect

59 Based on photophysical data, their excited-state properties have

60 e N-aryl component proved to be an effective photophysical device as it allows the placement of a PET

61 This study underscores the photophysical diversity of the M-(PM')n-M platform and p

62 Their photophysical, electrochemical, and computational proper

63 no-based acceptor TCNE and TCNQ units on the photophysical, electrochemical, and computational studie

64 Current understanding of the photophysical electron transfer processes present in CD

65 ar rearrangement during a photoreaction or a photophysical event is one of the most important challen

66 On the basis of photochemical and photophysical experiments and computational studies, we

67 Pc-TCBD-aniline conjugates presents a unique photophysical feature never observed before in SubPc che

68 We have exploited this unique photophysical feature to establish a sensitive competiti

69 etail chemical structures and their relevant photophysical features for various groups of materials,

70 hybrid electrode architecture, combining the photophysical features of PSI with the biocatalytic prop

71 rolyte (COE), ZCOE, was synthesized, and its photophysical features were characterized.

72 s of reduced flavins/flavoproteins on a firm photophysical footing.

73 NA-induced twist, is crucial for the desired photophysical interactions.

74 A detailed photophysical investigation of the TPE-naphthyridine sca

75 Photophysical investigations in the solution phase provi

76 Consequently, photophysical investigations show that, compared to pare

77 Detailed photophysical investigations showed that as the doping d

78 We use a combination of conventional photophysical investigations, nuclear magnetic resonance

79 Photophysical investigations, supported by TD-DFT calcul

80 Based on photophysical investigations, the nature of excited stat

81 resonators are described quantitatively by a photophysical kinetic model and simulations.

82 critical need for high-speed multiparameter photophysical measurements of large libraries of fluores

83 Photophysical measurements on dye-grafted TiO2 films rev

84 EPR/ENDOR/photophysical measurements on wild type (WT) MoFe protei

85 Taken together, these photophysical measurements strongly suggest that 2,4-dit

86 Based on electrochemical and photophysical measurements, when a polarizable 2,5-thien

87 osal that suppression of Kasha's rule is the photophysical mechanism responsible for emission in both

88 mented, some doubts remain about the precise photophysical mechanism that underlies their peculiar sp

89 Elucidating the photophysical mechanisms in sulfur-substituted nucleobas

90 edure to determine appropriate transport and photophysical models for fluorescent proteins when appro

91 A detailed investigation of the photophysical parameters and photochemical reactivity of

92 the context of 14 new X-ray structures, and photophysical parameters of all new BODIPY compounds are

93 Although the small size and superb photophysical parameters of fluorescent-dyes offer uniqu

94 troscopy is a relevant method to investigate photophysical parameters of single fluorescent molecules

95 ion microscopy as a function of the measured photophysical parameters of the probe such as photobleac

96 one hand, approach (a) allows the control of photophysical parameters such as Stokes shift, emission

97 We have also quantified other key photophysical parameters that characterize this sensitiz

98 ins, is strongly entangled with spectral and photophysical parameters.

99 Interpretation of the photophysical pathways underlying these isomerization re

100 he spatial distribution of SMs with improved photophysical performance was obtained with 40 nm precis

101 spectroscopy is commonly used to investigate photophysical phenomena such as light harvesting in phot

102 Spectral, photophysical, photodynamic, and biological properties o

103 In this review, we describe the underlying photophysical principles by which this energy is absorbe

104 competitive reactions especially for using a photophysical process owing to its tunable properties.

105 various technologies that take advantage of photophysical processes amplified by this light-matter i

106 These fundamental insights into the photophysical processes in heavily doped nanocrystals wi

107 approaches for understanding the underlying photophysical processes in hot electron generation and d

108 f dark carriers in deconvoluting the complex photophysical processes in these materials.

109 A fundamental knowledge of these photophysical processes is crucial for the development o

110 Photochemical and photophysical processes occurring within these systems a

111 wever, little is known about the fundamental photophysical processes of g-C3N4, which are key to expl

112 is review, we focus on the photochemical and photophysical processes of organic fluorophores that aff

113 r dynamics and transport, and other relevant photophysical processes that have propelled these materi

114 ently, it has been shown that in addition to photophysical processes, optically excited plasmonic nan

115 sotope fractionation points to rate-limiting photophysical processes.

116 y from bond cleavage reactions but also from photophysical processes.

117 fts of the excitation laser power, and/or by photophysical processes.

118 Photophysical properties (2PA brightness and phosphoresc

119 These compounds were examined for their photophysical properties (absorption, fluorescence, and

120 were synthesized and investigated for their photophysical properties (PhiDelta value up to 0.91, lam

121 Here, we characterized the photophysical properties (steady-state and time-resolved

122 emissive materials were synthesized and the photophysical properties analyzed.

123 sembles into a columnar host, influences its photophysical properties and affects the reactivity of b

124 Photophysical properties and cell permeability of a pyre

125 The photophysical properties and electronic structure were a

126 The photophysical properties and photochemistry of [Ru(cyTPA

127 nyl]pyridines 2-4 were synthesized and their photophysical properties and reactivity in phototautomer

128 ynthesized and studied with respect to their photophysical properties and response toward ionizing ne

129 The favourable photophysical properties and solvent-dependent aggregati

130 The photophysical properties and subsequent reactivity of me

131 Changes in the photophysical properties and the nature of the excited s

132 The zinc(II)-sensitive photophysical properties and zinc(II) affinities of both

133 frared (NIR) fluorescent dyes with favorable photophysical properties are highly useful for bioimagin

134 ionic species (i.e. radical ions), and their photophysical properties are markedly sensitive to the m

135 toring protein aggregation with a variety of photophysical properties are of importance for the funda

136 The photophysical properties are relatively insensitive to t

137 ally available starting materials, and their photophysical properties are shown to be dependent on th

138 luorophores with excellent photochemical and photophysical properties as well as provides access to a

139 bulk fluorescence properties, but also their photophysical properties at the single molecule level.

140 , 3a-3c, and have systematically tuned their photophysical properties by changing the peripheral subs

141 Their photophysical properties can be easily tuned in a wide r

142 esults demonstrate that fine-tuning of their photophysical properties can be obtained by acting on th

143 synthesized in a one-pot reaction and their photophysical properties characterized by fluorescence,

144 cines, bridged azobenzenes, exhibit superior photophysical properties compared to parent azobenzenes

145 lies are described as Frenkel excitons whose photophysical properties depend crucially on the mutual

146 Their fascinating photophysical properties enable spectral discrimination

147 The four synthesized structures had their photophysical properties evaluated and their potential a

148 bostyril antennae were synthesized and their photophysical properties evaluated using steady-state an

149 The relationship between the structure and photophysical properties for all compounds were directly

150 or versatile bioconjugation, their adaptable photophysical properties for multiplexed detection, and

151 The photophysical properties for selected compounds have bee

152 hracene moiety has been synthesized, and its photophysical properties have been characterized.

153 However, to date, their photophysical properties have not been studied extensive

154 ucts were investigated with respect to their photophysical properties in order to quantify their "swi

155 Key photophysical properties in these systems were evaluated

156 laser dye, PM567, were synthesized and their photophysical properties in various organic solvents, la

157 Here, we describe the photophysical properties involved in photoacoustic (PA)

158 Facile tuning of photophysical properties is highly desirable for boostin

159 nship between their electronic structure and photophysical properties is outlined.

160 e arylazopyrazoles (AAPs) featuring superior photophysical properties is reported.

161 Accessibility and photophysical properties make them ideal candidates for

162 lymers contributes to the improvement of the photophysical properties necessary for highly efficient

163 ion spectroscopy and was used to probe basic photophysical properties of (3)CDOM*.

164 insight into the resonance stabilization and photophysical properties of 1,4-azaborines.

165 Photophysical properties of 2-7 were determined by stead

166 The photophysical properties of 3 are compared to those of D

167 tic-dimer excited states may account for the photophysical properties of a previously reported lumino

168 port on the synthesis, characterization, and photophysical properties of a rationally designed multic

169 oundary in real time by employing the unique photophysical properties of aggregation-induced emission

170 The excellent photophysical properties of C60 fullerenes have spurred

171 Furthermore, we characterize the photophysical properties of commonly used photoactivatab

172 The photophysical properties of dye-conjugated FDNs (Cy5-FDN

173 nces in planarity between the molecules, the photophysical properties of each trimer are derived from

174 ndergo singlet exciton fission to reveal the photophysical properties of entangled triplet-pair state

175 ty coupling is quasi-deterministic since the photophysical properties of every SWCNT are enhanced by

176 In all cases, the photophysical properties of FDNs resulted in enhanced fl

177 We find that the photophysical properties of individual chlorosomes from

178 gned a single-molecule approach to probe the photophysical properties of individual pigment sites as

179 Here, the underlying physical and photophysical properties of inorganic (A = inorganic) an

180 The photophysical properties of isoquinoline derivatives dif

181 report the preparation and new insight into photophysical properties of luminescent hydroxypyridonat

182 The photophysical properties of MediaChrom dyes have been ev

183 nt of the linkers can play a key role in the photophysical properties of MOFs.

184 c strategies currently in use to enhance the photophysical properties of mononuclear Ru(II) complexes

185 report the synthesis, crystal structure and photophysical properties of one-dimensional organic lead

186 this review, we discuss the biochemical and photophysical properties of photocontrollable fluorescen

187 In this review, we discuss the photophysical properties of porphyrins, and overview the

188 applications, but little is known about the photophysical properties of pyridine-based BODIPY analog

189 The ability to cooperatively merge the photophysical properties of semiconductor quantum dots w

190 he structural basis for the fluorescence and photophysical properties of Spinach, and we describe fut

191 ural modifications of the switching unit the photophysical properties of the AAPs could be tuned to o

192 belled carbon nanomaterials or the intrinsic photophysical properties of the carbon nanomaterial.

193 3-polypseudorotaxane results in far superior photophysical properties of the central PDI unit relativ

194 ments to the stability, electrochemical, and photophysical properties of the complexes.

195 The photophysical properties of the compounds are described.

196 In addition, the photophysical properties of the cycloadducts are present

197 The photophysical properties of the dendrimers have been stu

198 he demonstration that photobleaching and the photophysical properties of the dye did not influence di

199 The photophysical properties of the dye exhibit change in fl

200 for tuning of the electron accumulation and photophysical properties of the extended tetracationic c

201 In practice, the photophysical properties of the fluorophores used as tag

202 es for potential applications related to the photophysical properties of the grafted chromophore.

203 s photoswitchable behavior and to direct the photophysical properties of the host.

204 The photophysical properties of the internal charge transfer

205 conformational, structural, chiroptical, and photophysical properties of the molecule are reported.

206 The photophysical properties of the novel compounds are also

207 sent review, the attention is focused on the photophysical properties of the probe drugs (rather than

208 Interestingly, the photophysical properties of the resulting partially amor

209 gate the tunability of the photochemical and photophysical properties of the retinal-protonated Schif

210 Due to the photophysical properties of the studied compounds and th

211 by a theoretical model that incorporated the photophysical properties of the Tb(III) probe and the in

212 thin film morphology and the electronic and photophysical properties of the three materials are exam

213 The photophysical properties of these cages and their fuller

214 g to compounds 4 can be utilized to tune the photophysical properties of these compounds.

215 The photophysical properties of these emitters therefore inv

216 res, Atto655 and Alexa647, by evaluating the photophysical properties of these fluorophores and their

217 The photophysical properties of these molecules in deoxygena

218 s offer versatile strategies to modulate the photophysical properties of these nanoassemblies in resp

219 nal analysis, we describe the structural and photophysical properties of these unique compounds.

220 Moreover, the solution-phase photophysical properties of this cyclophane have been in

221 The unique photophysical properties of this hybrid material are att

222 The photophysical properties of three of the fluorescent unn

223 d area of chemical space and investigate the photophysical properties of three simple DIPYR dyes: bor

224 Photophysical properties of two highly emissive three-co

225 he presence of the N-ligand also affects the photophysical properties of Yb and Eu by decreasing thei

226 ramework (NMOF), DBC-UiO, with much improved photophysical properties over the previously reported po

227 It was found that the photophysical properties remain basically unchanged with

228 Finally, the photophysical properties revealed that the subphthalocya

229 he NDIs not containing Br, only 12 exhibited photophysical properties similar to those of Br-NDIs, by

230 tinum complexes have attractive chemical and photophysical properties such as high stability, emissio

231 cs, atomically precise thickness, and unique photophysical properties such as narrow-band fluorescenc

232 ts of a broad range of properties, including photophysical properties such as spectral spread and bio

233 he heterobimetallic complexes herein exhibit photophysical properties that are favorable to those for

234 l perovskite nanostructures provide improved photophysical properties that are important for fundamen

235 at NAO is promiscuous in its binding and has photophysical properties that are largely insensitive to

236 iew highlights new insights into many of the photophysical properties that are of interest in semicon

237 er pure T10 and T12 silsesquioxanes and show photophysical properties that differ as a function of si

238 y of such hybrid materials, reports on their photophysical properties that is anticipated to have sig

239 ations, suggest a rationale for the observed photophysical properties that is dependent on duplex int

240 By tuning the photophysical properties through the judicious functiona

241 However, much of the fundamental photophysical properties underlying this performance has

242 ns are organic heterocyclic macrocycles with photophysical properties well-suited for clinical photot

243 difluoroborates were synthesized, and their photophysical properties were determined.

244 tigated by scanning electron microscopy, and photophysical properties were evaluated using UV-Vis and

245 stitution and double benzannulation on their photophysical properties were examined with experimental

246 ding arylacetonitrile derivatives, and their photophysical properties were fine-tuned through the inc

247 lization were fully characterized, and their photophysical properties were investigated.

248 eir photochemical reactivity, acid-base, and photophysical properties were investigated.

249 fects of said substitution on the compounds' photophysical properties were rationalized by density fu

250 In addition, the change in photophysical properties with extension of conjugation o

251 edia to manipulate the structural change and photophysical properties, a broad white emission can be

252 is paper describes the synthesis, structure, photophysical properties, and bioimaging application of

253 They have interesting photophysical properties, are readily functionalized, an

254 The materials exhibit unique photophysical properties, arising from both, this phase

255 uorescent SOFs exhibit intriguing and varied photophysical properties, including large red-shifts (up

256 large polaron responsible for the remarkable photophysical properties, irrespective of the cation typ

257 Despite their numerous outstanding photophysical properties, QDs at the single particle lev

258 , carbopyronines and cyanines with excellent photophysical properties, that is, high photostability a

259 though they present a wealth of interesting photophysical properties, these optically dark states si

260 nically orthogonal with respect to the dye's photophysical properties, which are only determined by t

261 PECN exhibited excellent photophysical properties, which makes it to be a good ca

262 clotetramerization, no aggregation, and good photophysical properties, which makes them potentially s

263 ation energies and for interpretation of the photophysical properties.

264 nd class with highly desirable near infrared photophysical properties.

265 ties analysis, and characterization of their photophysical properties.

266 the surface composition of the QDs to their photophysical properties.

267 homogeneous morphological, hydrodynamic, and photophysical properties.

268 approaches were used to explain the observed photophysical properties.

269 cer mouse models as a result of its improved photophysical properties.

270 bonding properties, reactivity, thermal and photophysical properties.

271 age size and/or symmetry can strongly affect photophysical properties.

272 kites and its connection with structural and photophysical properties.

273 alized nanohoop, show unique solid-state and photophysical properties.

274 with all of the investigated scaffolds, the photophysical response to each scaffold was significantl

275 PFBT-MI showed excellent photophysical responses toward SDS and SDBS with a detec

276 nescent probes with unique photochemical and photophysical signatures have already emerged from these

277 ituent at the sensitive meso position in the photophysical signatures of these compounds.

278 f the structural rigidity/flexibility on the photophysical signatures.

279 substrate/product combination with discrete photophysical signatures.

280 rge optical cross-sections and extraordinary photophysical stability.

281 twork model accurately predicts the observed photophysical states of C-PC and suggests highly variabl

282 real time, we directly monitor the changing photophysical states of individual C-PC monomers from Sp

283 The number of photophysical states, the kinetics of interconversion, a

284 used to develop experimental electronic and photophysical structure-property trends.

285 of their native nucleoside counterparts, and photophysical studies demonstrate that the nucleodyes ar

286 Via photophysical studies Ni et al. observe 'quantum cutting

287 Photophysical studies of the resulting compounds show th

288 The synthesis and photophysical studies of two cationic Troger's base (TB)

289 parison with model systems and from detailed photophysical studies on 2 and 3, we conclude that the p

290 elevant designs, synthetic methodologies and photophysical studies related to materials that incorpor

291 Photophysical studies reveal extended pi-effects that in

292 Photophysical studies reveal the effects of mixed phase

293 Photophysical studies revealed that 5-hydroxy-naphtho[2,

294 Photophysical studies such as fluorescence, phosphoresce

295 ished to be 2:1 (TPEN:Ag(+)) on the basis of photophysical studies, mass analysis, and high-resolutio

296 On the basis of detailed photophysical studies, the triplet energies of the malei

297 r with their synthesis and photochemical and photophysical studies.

298 These findings provide the first detailed photophysical study of chromophore-functionalized T10 an

299 We offer here the first detailed photophysical study of the larger pure T10 and T12 silse

300 A series of photophysical titrations show this Eu(III) chelate behav

301 ials that would also benefit from a detailed photophysical understanding afforded by single nanocryst

302 ied with respect to their microstructures by photophysical, X-ray crystallographic, and computational