ライフサイエンスコーパス: condensed phase

1 the nandrops are comparable to those of the condensed phase.

2 r the investigation of hydrogen tunneling in condensed phase.

3 orientations of successive molecules in the condensed phase.

4 ist to perform density reconstruction in the condensed phase.

5 , familiar for high-spin d4 complexes in the condensed phase.

6 n recent claims of concerted transfer in the condensed phase.

7 ble preferences for either the disordered or condensed phase.

8 athway becomes kinetically more favorable in condensed phase.

9 of small molecule inhibitors of this type of condensed phase.

10 dominates the thermal initiation of the TATP condensed phase.

11 tion processes in both the gas phase and the condensed phase.

12 the gas phase, it is endergonic in the polar condensed phase.

13 rge method for generating O(3P) atoms in the condensed phase.

14 oclinic tilted chain lattice is found in the condensed phase.

15 ns and previous spectroscopic studies in the condensed phase.

16 istence between a liquid-expanded and liquid-condensed phase.

17 on models to study chemical reactions in the condensed phase.

18 ion reactions that proceed so readily in the condensed phase.

19 imilar systems that have been studied in the condensed phase.

20 -optical characterisation of substances in a condensed phase.

21 re on CN(-), CO, and O2 bound globins in the condensed phase.

22 ly as a short-lived transient species in the condensed phase.

23 ries of radical bimolecular reactions in the condensed phase.

24 ter-soluble organic compounds (WSOCg) to the condensed phase.

25 lecular reactions both in the gas and in the condensed phase.

26 at affect partitioning between the vapor and condensed phase.

27 imulations of Miller-like experiments in the condensed phase.

28 ample of siliconoid cluster expansion in the condensed phase.

29 e-time imaging of structural dynamics in the condensed phase.

30 dynamics occurring at interfaces and within condensed phases.

31 f organic glasses and molecular diffusion in condensed phases.

32 ning of the salt between the aqueous and the condensed phases.

33 s that have been synthesized and analyzed in condensed phases.

34 difficult to observe in symmetric dimers or condensed phases.

35 to low-temperature oxidation in gaseous and condensed phases.

36 avior of SOA species into aqueous or organic condensed phases.

37 and chemical properties of Tc(VII) oxides in condensed phases.

38 Transformation of the higher order condensed-phase 3-D PMF potential-energy surface, comput

39 gies in the gas phase (~62 kcal/mol) and the condensed phase (~35 kcal/mol) of TNT and identifies the

40 ger cross-sectional molecular areas than the condensed phases achieved by spreading at temperatures o

41 it is exceeded, the mutant protein forms the condensed phase after a nucleation time of 10-20 min.

42 ) so that the phase state (viscosity) of the condensed-phase after heating is similar to how it would

43 s is extremely high speed, exceeding that of condensed-phase alternatives by orders of magnitude.

44 In this respect, it provides a condensed-phase analogy to gas-phase ("intrinsic") acidi

45 systems, such as DPPC/water monolayer in the condensed phase and DPPC/water bilayer in the gel phase.

46 cantly impacts the coexistence of the liquid-condensed phase and liquid-expanded phase.

47 rst direct observation of metaphosphate in a condensed phase and may provide the structural basis for

48 ne adducts of gold(I) enone complexes in the condensed phase and that the existence of naked alpha-ox

49 nge with volume shows two stable phases: the condensed phase and the isolated micelle phase.

50 Because SVOCs are found in both gas and condensed phases and redistribute from their original so

51 del systems for unraveling the complexity of condensed-phase and biological structures, not to mentio

52 d to the study of molecules in gas phase, in condensed phase, and at interfaces.

53 n elementary systems to model systems in the condensed phase, and on to biological structures.

54 electrostatic solvation energy: once for the condensed phase, and once for the solution phase.

55 degree of conformational homogeneity in the condensed phase, and represents a rare example where suc

56 line tension between the fluid phase and the condensed phase as confirmed by the formation of "stripe

57 he coexistence of liquid-expanded and liquid-condensed phases as well as liquid-ordered and liquid-di

58 sts an order-to-disorder transition for this condensed phase at 480-490 K, with a sharp reduction in

59 the partitioning of selenium between gas and condensed phases at the scrubber inlet and outlet.

60 lied to explain the stability of families of condensed phase Au clusters.

61 LBID results are in excellent agreement with condensed phase behavior determined in other studies.

62 action, have been extensively studied in the condensed phase but have yielded only limited detailed i

63 parallel reactivity patterns observed in the condensed phase, but offer new insights into steric fact

64 ified industrial catalyst, ambient pressure, condensed phase, ca. 0.03 m monomer).

65 ncrease of the domain fraction of the liquid-condensed phase can be observed for the deposition of 20

66 inhibited by SOA coatings, and further that condensed phase chemical pathways and rates in organic p

67 The BQT allows for condensed phase chemical reactions to be initiated by co

68 ification approach to reduce the reliance on condensed-phase chemistries and extensive separations fo

69 g) calculations enable to directly probe the condensed phase chemistry under extreme conditions of te

70 Condensed-phase chemistry plays a significant role in th

71 Such complexes are very rare in condensed-phase chemistry.

72 lateau along the force curves), typical of a condensed phase (compaction of a long DNA into a micron-

73 e approach apportions combined gas-phase and condensed-phase concentrations of individual compounds a

74 atch closely with those observed from a TATP condensed-phase cookoff simulation, indicating that unim

75 of intermediates, some the same as in their condensed-phase counterparts.

76 Previous condensed phase data indicate a reactivity order of iodi

77 this variation, the gas-phase data parallel condensed phase data indicating that the substituent eff

78 dramatic suppression of activation energy in condensed phase decomposition of nitroaromatic explosive

79 area per molecule and compressibility of SM condensed phases depended upon the length of the saturat

80 soporous metal-organic framework NU-1000 via condensed-phase deposition where the MOF is simply subme

81 hat G(M1) and DPPC pack cooperatively in the condensed phase domain to form geometrically packed comp

82 This fluid phase forms a network, separating condensed-phase domains at coexistence.

83 We use this "optoDroplet" system to study condensed phases driven by the IDRs of various RNP body

84 uced in measurements of the molecules in the condensed phase due to polarization effects in the solid

85 ver, this assumption is commonly violated in condensed phases due to mechanical instabilities.

86 lyzed noncovalent complex dissociated in the condensed phase during the spraying process.

87 cular dynamics simulations are presented for condensed-phase electron transfer (ET) systems where the

88 products between m/z 300 and 350, the major condensed-phase end products were levulinic acid (LLA) a

89 y of this specific analyte and the analyte's condensed phase environment.

90 Incorporation of a condensed-phase environment by means of mixed quantum me

91 d building a full molecular-level picture of condensed-phase ET reactions.

92 order observed in the gas phase and in some condensed phase experiments.

93 PPL domains that were similar to the liquid condensed phase for dipalmitoyl phosphatidylcholine (DPP

94 PCM solvation calculations used to calculate condensed-phase free energies are slightly less accurate

95 Ligands from recent examples of stable condensed-phase gold(II) complexes appear to meet at lea

96 They were obtained by measuring the condensed-phase heat of reduction to the corresponding a

97 elucidate the nature of the transfer in the condensed phase, here we examine variation of solvent po

98 commonly, MOFs have been metalated from the condensed phase (i.e., from solution).

99 namic mass transport between the gaseous and condensed phases in a non-equilibrium system.

100 peptide, SP-B1-25, inhibit the formation of condensed phases in monolayers of palmitic acid, resulti

101 e and therefore partition between vapour and condensed phases in the atmosphere and both the vapour a

102 ffusion, and chemical reactions from the gas-condensed phase interface to the bulk.

103 r-scale variation in solvation forces across condensed-phase interfaces.

104 ze biological macromolecules intact from the condensed phase into the gas phase for nanospray postion

105 chrome c and lysozyme are vaporized from the condensed phase into the gas phase intact when exposed t

106 is also pointed out that all reactions in a condensed phase involve correlated motions (both in enzy

107 Complex systems in condensed phases involve a multidimensional energy lands

108 s' diffusion theory of reaction rates in the condensed phase is considered as an alternative to the t

109 age dipole moment of a water molecule in the condensed phase is enhanced by around 40 percent relativ

110 nding of the origin of volume changes in the condensed phase is needed to complement the experimental

111 t concentration of oxidation products in the condensed phase is predicted for a scenario assuming the

112 Diffusion in condensed phases is a ubiquitous but poorly understood p

113 different experimental regimes: molecules in condensed phases, isolated in supersonic jets and helium

114 s, which are the least polar and polarizable condensed phases known.

115 us media are the least polar and polarizable condensed phases known.

116 ate simulations of water from the gas to the condensed phase, leads to a definitive molecular-level p

117 Alternatively, condensed-phase magic-number cluster theories may need t

118 on experiments at 75% relative humidity, and condensed-phase mass was measured in bulk thermogravimet

119 phidynamic crystals are an emergent class of condensed phase matter designed with a combination of la

120 Condensed-phase matter with anisotropic molecular order

121 Condensed phase membrane introduction mass spectrometry

122 that could not be addressed by conventional condensed phase methods.

123 Traditional condensed-phase methods are of limited use for character

124 Condensed-phase molecular dynamics simulations are appli

125 Ultrafast electron transfer in condensed-phase molecular systems is often strongly coup

126 mulation is an appropriate condition for the condensed-phase NP(N)gammaT simulation.

127 cular dynamics (MD) simulation of the liquid condensed phase of a 1,2-dilignoceroylphosphatidylcholin

128 d lead to a chain collapse transition into a condensed phase of DNA tethered by divalent counterions.

129 Interstellar dust (ISD) is the condensed phase of the interstellar medium.

130 f specific area corresponding to an untilted condensed phase of the the pure palmitic acid monolayer.

131 charge state on the energetic proton in the condensed phase of water results in the strongly suppres

132 andard molar enthalpies of formation, in the condensed phase, of the three isomers were derived from

133 formation of chlorine oxides (ClxOy) in the condensed phase on Mars.

134 o the evolution of charge transfer states in condensed phase, one that is strongly coupled to the sur

135 ural properties, the phase state of the bulk condensed phase, or surface curvature.

136 The composition of condensed-phase organic compounds in SOA is measured usi

137 tal findings could be explained by secondary condensed-phase ozone chemistry, which competes with OH

138 In this study, condensed phase particles collected from around the deto

139 ular interactions drive the vast majority of condensed phase phenomena from molecular recognition to

140 This condensed-phase photochemical process may produce a few

141 These condensed-phase photochemical processes occur on atmosph

142 olet (lambda>300 nm) radiation, we find that condensed-phase photochemistry can induce significant ch

143 ark contrast to what is commonly observed in condensed phase photophysics.

144 We show that C4N2 ices undergo condensed-phase photopolymerization (tholin formation) a

145 ultimately led to an entirely new branch of condensed-phase physics and chemistry.

146 eatures of the packing process are rooted in condensed-phase polymer dynamics suggests that statistic

147 he morphology and chemical identity of these condensed phase postblast particles remains undetermined

148 nuders show similar results, suggesting that condensed-phase processes dominate over heterogeneous re

149 In addition, a wide array of oxygenated, condensed-phase products has been observed.

150 oducts of squalene ozonolysis are known, the condensed-phase products have not been characterized.

151 We present an analysis of condensed-phase products resulting from an extensive oxi

152 protein/nucleic acid-ligand interactions or condensed phase properties by force field-based methods

153 PC/water monolayer shows that various liquid condensed-phase properties of the monolayer have been we

154 force field parameter set developed based on condensed-phase quantum mechanical calculations and a Ge

155 Unlike the corresponding condensed-phase reaction, where catalytic proton exchang

156 the importance of accounting for the role of condensed phase reactions in altering the composition of

157 y insufficient to reveal the extent to which condensed-phase reactions occur in conjunction with the

158 and as such, they have been used to create a condensed phase reactivity profile for O((3)P).

159 lecular driving forces and the nature of the condensed phases remain poorly understood.

160 e for the measurement of infrared spectra of condensed phase samples.

161 issue) is applied to the direct analysis of condensed-phase samples.

162 ration speeds exceeding that of conventional condensed-phase separations by orders of magnitude.

163 ral orders of magnitude greater than that of condensed-phase separations.

164 ide and trifluoroacetate are reversed in the condensed phase so this reactivity pattern does reflect

165 The condensed-phase SOA photodegradation processes could the

166 provides a quantitative determination of the condensed-phase spectrum.

167 In fact, tau in the condensed phase state does not reveal any immediate chan

168 lvation is consistent with results from many condensed-phase studies, and contrasts with results for

169 ational energy redistribution in the gas and condensed phases suggest that other gas-surface reaction

170 and thermodynamic properties in the gas and condensed phases suggests that the polarizable models pr

171 ion to atmospheric aerosols by reacting with condensed phase sulfuric acid, forming low-volatility or

172 rformed at instantaneous configurations of a condensed-phase system, leading to modes with negative e

173 ng of electronically-coupled chromophores in condensed phase systems, tightening the inferred relatio

174 rafast snapshots of biological molecules and condensed-phase systems undergoing structural changes.

175 In complex condensed-phase systems, however, it is difficult to des

176 tions demonstrate that thermal initiation of condensed-phase TATP is entropy-driven (rather than enth

177 ol and more flexibility for the detection of condensed phases than with other chemical ionization met

178 association of the P23T mutant to form a new condensed phase that contains clusters of the mutant pro

179 cause syntheses are largely performed in the condensed phase, the present computational investigation

180 The average transfer free energy from the condensed phase to the solution phase was found to predi

181 alculating the transfer free energy from the condensed phase to the solution phase.

182 cular forms in which HOMs are present in the condensed phase upon gas-particle partitioning remain un

183 itions but might be expected to occur in the condensed phase upon heating or with further lowering of

184 ate and detect diazirinone (1) in either the condensed phase (using matrix isolation spectroscopy) or

185 and as mixtures in the gaseous, solution, or condensed phases, using He, Ar, N2, or ambient air as th

186 hase of condensed material and the effective condensed phase vapor pressures of the SVOCs.

187 The condensed phase was modeled as an implicit solvent, with

188 all-metal cluster-like fragments isolated in condensed phase was previously shown to be mainly ascrib

189 py (XAS) experiments on liquid water, that a condensed-phase water molecule's asymmetric electron den

190 resolved infrared (TRIR) spectroscopy in the condensed phase, we have conducted a detailed kinetic an

191 disproven claims of HAsAsH formation in the condensed phase, we report the isolation and structural

192 comparison of the IR-spectra in the gas and condensed phases, we propose putative assignments for th

193 n-carbon double bonds were identified in the condensed phase which survived ozonolysis during new par

194 lectronic effects acting on molecules in the condensed phase, which in this case are greater than the

195 ng rates are limited by diffusion within the condensed phase, which is thought to be "glassy." Here,

196 talyst deactivation have been studied in the condensed phase with both classical and quantum methods

197 the properties of water from the gas to the condensed phase with unprecedented accuracy, thus openin