ライフサイエンスコーパス: photochemical reaction

1 hotoexcitation can be effective in driving a photochemical reaction.

2 ao as a product in an electron-transfer (ET) photochemical reaction.

3 nd then covalently modify the receptor via a photochemical reaction.

4 the most important and most frequently used photochemical reaction.

5 thereby indicating the feasibility of [2+2] photochemical reaction.

6 ess is (eta(5)-C(5)H(5))Mo(CO)(3)CH(3) via a photochemical reaction.

7 -radiative energy dissipation and exothermic photochemical reactions.

8 acity to channel that energy into productive photochemical reactions.

9 d by both exports of plumes upwind and local photochemical reactions.

10 potentially unique locations for chemical or photochemical reactions.

11 rol, are one of the unique abilities of such photochemical reactions.

12 -efficient and sustainable energy source for photochemical reactions.

13 sic principle, Kasha's rule, when applied to photochemical reactions.

14 rting catalyst to carry out energy-demanding photochemical reactions.

15 single-walled carbon nanotube hosts through photochemical reactions.

16 sue penetration but also causing detrimental photochemical reactions.

17 oparticles (Ag, Au and Cu) can induce direct photochemical reactions.

18 lf-terminating aromatizing enyne cascades to photochemical reactions.

19 l in carrying out useful electrochemical and photochemical reactions.

20 d to the "meta effect" well-known in organic photochemical reactions.

21 ues (~ -2 per mil) indicative of atmospheric photochemical reactions.

22 ce of pesticides in prairie wetlands through photochemical reactions.

23 he same oxidizing transient is formed in the photochemical reaction and in the hydrogen peroxide shun

24 to-destruction, photo-physical modification, photochemical reaction and photo-oxidation.

25 duce electrophoretic transport by a confined photochemical reaction and use it to infer the binding s

26 discovery of catalysts that can both promote photochemical reactions and control their stereochemistr

27 olecules has been a basic way to investigate photochemical reactions and dynamics.

28 emission spectroscopy were used to rule out photochemical reactions and elucidate the supramolecular

29 emitted into the atmosphere, PCDD/Fs undergo photochemical reactions and enter other environmental co

30 g particles in the boundary layer accelerate photochemical reactions and smog production, but UV-abso

31 e we compare BPR and GPR absorption spectra, photochemical reactions, and proton transport activity.

32 the need for any external reducing agent or photochemical reactions, and the resulting Ag@BIF-20 (or

33 rmation in which the arrangements needed for photochemical reaction are attained during the electroni

34 Photochemical reactions are essential to a large number

35 The majority of photochemical reactions are likely to be dissociative, b

36 These photochemical reactions are mediated by the alpha-hydrox

37 Photochemical reactions are remarkable for their ability

38 .(2,7)0(5,9)]decane structures formed in the photochemical reactions are thermally stable.

39 We designed an autocatalytic photochemical reaction based on the photoinduced cleavag

40 ns were synthesized by a one-step metal-free photochemical reaction between 2-chlorophenol derivative

41 We demonstrate a photochemical reaction between graphene and benzoyl pero

42 surfaces to direct geometrically unfavorable photochemical reactions between individual organic molec

43 The possible catalysis of photochemical reactions by water molecules is considered

44 Our photochemical reaction can be successfully adapted into

45 The photochemical reactions can be run neat in standard boro

46 the substrates recognized (protein or DNA), photochemical reactions catalysed and involvement of an

47 Here we describe a novel photochemical reaction cell which allows for the simulta

48 The synthesis takes place in a photochemical reaction cell which positions the microarr

49 electron carriers which operate between the photochemical reaction center (RC) and the cyt bc1 compl

50 lexes, the light-harvesting antenna (LH) and photochemical reaction center (RC).

51 as an efficient electron carrier between the photochemical reaction center and the cyt bc1 complex du

52 ently with distinct redox partners, like the photochemical reaction center and the Cyt c oxidase, and

53 from the cytochrome (cyt) bc1 complex to the photochemical reaction center by either the periplasmic

54 ding light-harvesting complexes 1 and 2, the photochemical reaction center, and the cytochrome bc(1)

55 s on the intramolecular distance between two photochemical reaction centers in the molecule.

56 The use of photochemical reaction centers to convert light energy i

57 lutant mixtures, or ozone (O3) for 4 hr in a photochemical reaction chamber.

58 ests persistence throughout Earth history of photochemical reactions characteristic of the present-da

59 rm a pink pigment (lambda max 543 nm) with a photochemical reaction cycle of 110 ms half-life (pH 6.8

60 by time-resolved flash spectroscopy that the photochemical reaction cycle of a functional purified AC

61 The photochemical reaction cycle of Hawaiian deep ocean BPR

62 The photochemical reaction cycle of one Escherichia-coli-exp

63 We studied the photochemical reaction cycle of sensory rhodopsin II (SR

64 he retinal-reconstituted pigment undergoes a photochemical reaction cycle with a near-UV-absorbing in

65 The new rhodopsin exhibited a photochemical reaction cycle with intermediates and kine

66 l necessary for proton uptake during the SRI photochemical reaction cycle.

67 Their photochemical reaction cycles in H. salinarum and E. col

68 This paper illustrates a new photochemical reaction detection scheme for CEC that tak

69 Not only are these photochemical reactions different from the known thermal

70 (3) MIF-S in rocks was mostly created by non-photochemical reactions during sediment diagenesis, and

71 are typically required to monitor ultrafast photochemical reaction dynamics, sample depletion and pr

72 lectronic states, reveal a rich diversity of photochemical reaction dynamics.

73 precedented detail that 2D-EV will afford to photochemical reaction dynamics.

74 Photochemical reactions employing TiO2 and carboxylic ac

75 og, which is produced in the stratosphere by photochemical reactions following the dissociation of me

76 The initial photochemical reaction follows a single quantum mechanis

77 The inclusion of photochemical reactions for higher iodine oxides leads t

78 Environmental photochemical reactions generating .OH lead to distinct

79 r photoelectrochemical applications, a novel photochemical reaction has been discovered.

80 influence of the substituent pattern on the photochemical reaction has been examined.

81 Photochemical reactions have become an important tool fo

82 on, involving Pchlide binding and an initial photochemical reaction, have been studied in vitro by us

83 ement of Tyr21 with Leu or Phe abolished the photochemical reaction implicating involvement of Tyr21

84 ields and short reaction times by means of a photochemical reaction in methanol with a catalytic amou

85 lambda = 254 nm) of our assemblies induces a photochemical reaction in the redox-inactive spacer incr

86 cipation of DOM have direct implications for photochemical reactions in extracellular proteins as wel

87 hese topics in relation to ultrafast organic photochemical reactions in homogeneous liquids.

88 Ultrafast photochemical reactions in liquids occur on similar or s

89 ed with the ability to achieve multielectron photochemical reactions in preference to single-electron

90 Photochemical reactions in snow can have an important im

91 ew of supramolecular and template effects on photochemical reactions in solution is presented.

92 te estimates of iox formation, emission, and photochemical reactions in the atmosphere.

93 are ruled out as causes of the anomaly, but photochemical reactions in the early solar nebula could

94 brated excited states that undergo different photochemical reactions, including proton transfer or hy

95 (no nitrile byproduct is formed unlike other photochemical reactions involving aldoxime ethers) as we

96 Here we report observations of photochemical reactions involving Fe(III) bound to sider

97 Our work suggests that photochemical reactions involving ionic Ag and NOM can b

98 tion of sulfur isotopes (S-MIF) results from photochemical reactions involving short-wavelength UV li

99 vals, a weak hydrological cycle coupled with photochemical reactions involving water vapor would give

100 owever, where application of light elicits a photochemical reaction irrespective of the environment.

101 ansient absorption experiments show that the photochemical reaction is complete in less than 10 ns.

102 This photochemical reaction is impeded by molecular oxygen an

103 The quantum yield of a photochemical reaction is one of the most fundamental qu

104 A method for monitoring photochemical reaction kinetics and the dynamics of mole

105 cells and transducer-modulation of receptor photochemical reaction kinetics in membranes.

106 Photochemical reactions (lambda irr = 254 nm) of substit

107 Our work suggests that photochemical reactions may be a significant transformat

108 s, the excess electrons that are not used in photochemical reactions may form reactive oxygen species

109 We show that the photochemical reaction mechanisms for alpha-keto acids i

110 ygen concentration that inhibited subsequent photochemical reactions necessary for efficient photodes

111 arbon dioxide (P(CO2)) in the past through a photochemical reaction network linking stratospheric ozo

112 e investigated SOA particle formation due to photochemical reactions occurring at an air-water interf

113 The photochemical reaction of 9,10-dinitroanthracene (DNO(2)

114 The photochemical reaction of [Rh(eta5-C5H5)(R,R-phospholane

115 A related photochemical reaction of an iminium ether substrate unc

116 The photochemical reaction of CpRh(eta(6)-C(6)Me(6)) with pi

117 But the initial photochemical reaction of cryptochrome is still unclear.

118 s39 with alanine abolishes the light-induced photochemical reaction of LOV1 and LOV2.

119 ental and computational investigation of the photochemical reaction of terminal alkenes with hydrogen

120 nce is initiated by a previously unexploited photochemical reaction of the cyanine fluorophore scaffo

121 The photochemical reaction of Tp'Rh(L)(eta2-PhN=L) [Tp' = tr

122 expansion of cyclobutanones, produced by the photochemical reaction of vinyl oxazolidinones with chro

123 in the second part of the article we review photochemical reactions of a series of benzene derivativ

124 The photochemical reactions of a series of cyclic N-alkenyl-

125 ve been proposed for the beta-lactam-forming photochemical reactions of alpha-ketoamides.

126 chromophore during light-dark adaptation and photochemical reactions of Anabaena (Nostoc) sp. PCC7120

127 The photochemical reactions of crystal violet leuconitrile (

128 proximately 15% whereas simulations with the photochemical reactions of higher iodine oxides indicate

129 Halogen chemistry without the photochemical reactions of higher iodine oxides reduces

130 with the halogen chemistry: without and with photochemical reactions of higher iodine oxides.

131 Photochemical reactions of minerals are underappreciated

132 t states constitute a crucial gateway in the photochemical reactions of organic molecules by serving

133 Photochemical reactions of organic molecules in the soli

134 Photochemical reactions of ozone with all three organic

135 roaches based on the photothermal effect and photochemical reactions of photoswitching groups incorpo

136 es to delineate mechanisms of basic types of photochemical reactions of small organic molecules to st

137 This approach complements the photochemical reactions of the same systems previously u

138 lation pathway is preferentially followed in photochemical reactions of the tributylstannylmethyl-sub

139 The photochemical reactions of Tp'Rh(PMe3)H2 (1) and thermal

140 Photochemical reactions of triphenylcyclopropenium tetra

141 a batch reactor for performing a problematic photochemical reaction on a larger scale.

142 e exploited as an increased driving force in photochemical reactions on surfaces.

143 This type of photochemical reactions opens the possibility to control

144 processes including hydrothermal reduction, photochemical reactions, or lightning discharge could ha

145 Photochemical reactions, particularly those involving ph

146 ula-Twist mechanism, postulated in 1985 as a photochemical reaction pathway for a polyene chromophore

147 echanism of the photolysis follows the known photochemical reaction pathway of the 2-nitrobenzyl grou

148 iated and previously unsuspected thermal and photochemical reaction pathways in the chemistry of both

149 between two distinct but nearly isoenergetic photochemical reaction pathways is resolved by a topogra

150 y a zwitteronic-type intermediate, while the photochemical reactions proceed via an excited-state ele

151 s the signal from SRI but also optimizes the photochemical reaction process for SRI signaling.

152 let light illumination of JF-NP-26 induces a photochemical reaction prompting the active-drug's relea

153 However, the putative photochemical reactions remain elusive, and predicted ac

154 dures/platforms to expedite the discovery of photochemical reactions remains challenging.

155 Using non-bonding interactions to control photochemical reactions requires an understanding of not

156 ADP.Vi complex, and also the potential, in a photochemical reaction resulting in peptide bond cleavag

157 ces requires understanding such processes as photochemical reactions, spatial dynamics of photoexcita

158 ition to the lowest energy excited state and photochemical reaction starting therein, in some cases,

159 The photochemical reaction step involves the selective forma

160 or barcoding, and driving multiple important photochemical reactions, such as photoswitching.

161 ceptibility to oxidative stress generated by photochemical reaction, suggesting that the antioxidant

162 rgy is transferred to reaction centers where photochemical reactions take place.

163 nic structure of 2 led to the discovery of a photochemical reaction that forms NMo(N[t-Bu]Ar)3 and Mo

164 en migration to yield pent-1-en-3-yne (4), a photochemical reaction that is typical of carbenes beari

165 into the ice-free Arctic Ocean and to cause photochemical reactions that result in bleaching and min

166 The photochemical reactions that take place in RNA and affec

167 These results shed light on the photochemical reactions that take place in RNA and sugge

168 In single-quantum photochemical reactions, the conformer with the Schiff b

169 y and using TDDFT calculations, the simplest photochemical reaction: the binding and release of exoge

170 lly unstable and undergoes a DNA-accelerated photochemical reaction to afford a highly fluorescent ph

171 Proton pumps utilize a chemical or photochemical reaction to create pH and electrical gradi

172 seven-transmembrane helix design and similar photochemical reactions to carry out distinctly differen

173 This review will focus on the use of photochemical reactions to create dynamic hydrogel envir

174 using cytocompatible and wavelength-specific photochemical reactions to create hydrogels that allow o

175 Traces of water were required for the photochemical reactions to proceed.

176 n the BR retinal-binding pocket, enables its photochemical reactions to transmit signals to HtrII and

177 singlet excited S2 and S3 states drives the photochemical reaction toward a barrierless ultrafast re

178 re generated exclusively through atmospheric photochemical reactions until about 2.45 billion years a

179 s the first case in which true turnover of a photochemical reaction using a catalytic antibody could

180 A light-induced photochemical reaction was able to reactivate the intein

181 To explain the complex photochemical reactions, we propose a symmetrical two-cy

182 e demonstrate that the product of an initial photochemical reaction, which can occur below 200 K, is

183 sufficient to infer water catalysis in some photochemical reactions, which instead require dynamical

184 le of organic molecules and metal species in photochemical reactions with Mn oxide phases.

185 other rationale, the inability to influence photochemical reactions with temperature, solvent, addit

186 bly viscosity, on the rate of an atmospheric photochemical reaction within SOM.

187 cent examples of plasmon-driven hot electron photochemical reactions within the context of both cases

188 situ exchange of solutions allows successive photochemical reactions without moving the substrate and