ライフサイエンスコーパス: ultrafast

1 We report the use of an Ultrafast 2D NMR approach applied on a benchtop NMR syst

2 Ultrafast 2D spectroscopy uses correlated multiple light

3 We report a demonstration of ultrafast 2D terahertz spectroscopy of gas-phase molecul

4 Here we report our discovery of a universal, ultrafast (60 seconds), energy-efficient, and facile tec

5 Using a combination of ultrafast absorption and stimulated Raman spectroscopies

6 Herein we describe UClncR, an Ultrafast and Comprehensive lncRNA detection pipeline to

7 findings thereby enable a versatile tool for ultrafast and efficient control of light using light.Met

8 nsfer pathways, and ii) to perform directed, ultrafast and efficient electron transfer.

9 ent coherent light diffraction is due to the ultrafast and large third-order optical nonlinearity of

10 Ultrafast and nanosecond transient absorption and time-r

11 , which points to exciting opportunities for ultrafast and novel skyrmionic applications in the futur

12 We demonstrate a facile and ultrafast approach for the synthesis of multifunctional

13 on depletion microscopy into a time-resolved ultrafast approach, we measure a 16-nm migration length

14 ptical excitation of tF2356, one observes an ultrafast ( approximately 0.06 ps) evolution that reflec

15 titutes a first step towards measurements of ultrafast atomic dynamics using femtosecond HEX-ray puls

16 Ultrafast betatron x-ray emission from electron oscillat

17 has been investigated using a combination of ultrafast broadband mid-IR and visible transient absorpt

18 Refolding was confirmed by ultrafast broadband transient absorption and two-dimensi

19 otoemission spectroscopy, we investigate the ultrafast carrier dynamics in the series of (Sb1-x Bi x

20 aser a promising multimodal, super-contrast, ultrafast cellular probe with a single-pulse nanosecond

21 RP that can be differentially recruited upon ultrafast changes in the stimulation frequency.

22 This ultrafast charge motion may be key to separating electro

23 Ultrafast charge separation was monitored by transient a

24 This enhancement is driven by ultrafast charge transfer within the molecule, which ref

25 wing demands for faster signal processing is ultrafast charge transport and control by electromagneti

26 rein report an investigation into the use of ultrafast chiral chromatography as a second dimension fo

27 esolution sampling, and comprehensive) using ultrafast chiral chromatography in the second dimension

28 r optical spectroscopy, is used to probe the ultrafast coherent decay of photoexcitations into charge

29 ime stretch imaging, which has been used for ultrafast continuous imaging for a diverse range of appl

30 selective electron-lattice interplay for the ultrafast control of material parameters, and are releva

31 ov emission, giving a versatile, tunable and ultrafast conversion mechanism from electrical signal to

32 tion on time scales competitive with that of ultrafast cooling.

33 tive structural-ordering processes, by which ultrafast crystal growth becomes possible.

34 This ultrafast crystallization stems from the reduced stochas

35 This results in a very strong, ultrafast current that drives the nanoantennas to produc

36 In this work a new ultrafast data collection strategy for electron diffract

37 y both a low generation efficiency and their ultrafast decay.

38 laser pulse, the film exhibits the classical ultrafast demagnetization phenomenon although only a neg

39 amental phenomena and the development of new ultrafast diagnosis tools using either photonic or elect

40 ion shell structure, have been measured with ultrafast diffuse X-ray scattering and simulated with Bo

41 ded protein engineering approach that imbues ultrafast DnaE split inteins with minimal extein depende

42 We conclude that the development of TSL with ultrafast drug release capabilities needs to progress in

43 rbital-specific electronic structure and its ultrafast dynamics accessed with resonant inelastic X-ra

44 , are depicted.Real-time characterization of ultrafast dynamics comes with a tradeoff between tempora

45 e for studying the structure, properties and ultrafast dynamics of atoms, molecules, semiconductor ma

46 Understanding the ultrafast dynamics of electronically excited BODIPY chro

47 n this work, we characterize and compare the ultrafast dynamics of halogenated BODIPY chromophores th

48 The ultrafast dynamics of hot carriers in graphene are key t

49 ling to capture the electronic structure and ultrafast dynamics of molecular systems using phase-reso

50 EM) has enabled not only observations of the ultrafast dynamics of photon-matter interactions at the

51 We studied the ultrafast dynamics of the photoisomerization of azobenze

52 However, experimental observation of the ultrafast dynamics of this chiral magnetic texture in re

53 Using ultrafast electro-optical pump-push-photocurrent spectro

54 Here, ultrafast electron and hole dynamics in germanium nanocr

55 Dynamically, ultrafast electron diffraction (UED) with atomic-scale s

56 ase transition of VO2 are elucidated through ultrafast electron diffraction and diffusive scattering

57 The temporal resolution of ultrafast electron diffraction and microscopy experiment

58 Here, we use ultrafast electron diffraction to directly probe the sub

59 m of catalyst photoreduction is initiated by ultrafast electron injection into TiO2, followed by rapi

60 The development of four-dimensional ultrafast electron microscopy (4D UEM) has enabled not o

61 nated amorphous silicon (a-Si:H) by scanning ultrafast electron microscopy (SUEM).

62 Here we use scanning ultrafast electron microscopy to image the dynamics of e

63 Here, we report, using 4D ultrafast electron microscopy, the spatiotemporal behavi

64 n electron microscope (TEM) and too slow for ultrafast electron microscopy.

65 This high efficiency originates in ultrafast electron transfer between the QD and FeTPP, en

66 Ultrafast electron transfer in condensed-phase molecular

67 th the interaction strength characterized by ultrafast electron transfer measurements.

68 hat the simple outer-sphere pathway mediates ultrafast electron transfer of the Fc(2+/+) couple with

69 toexcitation of D within D-A-R(*) results in ultrafast electron transfer to form the D(+*)-A(-*)-R(*)

70 Subsequent ultrafast electron transfer within the triradical forms

71 ortant implications for our understanding of ultrafast electron-photon interactions in strong fields.

72 ible with future laser-wakefield-accelerator ultrafast-electron-diffraction schemes.

73 After photoexcitation, an ultrafast electronic energy relaxation to the lowest exc

74 mobility, can lead to applications based on ultrafast electronic response and low dissipation.

75 polariton condensate formation, resulting in ultrafast emission pulses of coherent polariton field.

76 g that the recent revolution in the field of ultrafast enantioselective chromatography could now prov

77 e actin depolymerization and impair bulk and ultrafast endocytosis, has a stronger effect on steady-s

78 pump-probe-type SMS technique to observe the ultrafast energy relaxation in single light-harvesting c

79 otosynthetic antenna to reaction centers via ultrafast energy transfer.

80 o femtosecond temporal resolution as well as ultrafast energy-filtered transmission electron microsco

81 , we present SPME-TM as a novel tool for the ultrafast enrichment of pesticides present in food and e

82 Here, we review the recent theoretical and ultrafast experimental studies of their photodynamics an

83 In such circumstances, ultrafast experiments can provide new insights by tracki

84 Here, the authors predict that an ultrafast (femtosecond) radiative cooling regime takes p

85 Ultrafast fiber lasers with broad bandwidth and short pu

86 Our versatile ultrafast fibre laser will be attractive for application

87 e of control over the dynamics and output of ultrafast fibre lasers, in contrast to the traditional m

88 diate states and the underlying mechanism of ultrafast fission have not been elucidated experimentall

89 Here we report a simple, robust and ultrafast fluid-phase immunocapture method for clinical

90 e TrmFO as a suitable model system and using ultrafast fluorescence and absorption spectroscopy, we c

91 Ultrafast formation of air-processable and high-quality

92 The ultrafast Franck-Condon bright state relaxes to a dark e

93 of multiple absorption lines from an extreme ultrafast gas flow in the X-ray spectrum of the active g

94 ns(-1) and 1.03+/-0.09 ns(-1) respectively), ultrafast hole transfer occurs only from PbS QDs to 5-CT

95 of cages loaded with C60 or C70 fullerenes, ultrafast host-to-guest electron transfer was observed t

96 combination of computational techniques and ultrafast imaging have enabled sensing through unconvent

97 Conventional ultrafast imaging techniques often rely on long data col

98 Here, using theoretical calculations and ultrafast in situ infrared spectroscopy of photocatalysi

99 the tens of nanoseconds range, whereas it is ultrafast in the oxygen-rich chloroplasts of oxygen-evol

100 dynamics simulations reproduce the observed ultrafast increase in lattice temperature and the corres

101 ilicon photonics could access new regimes of ultrafast information processing for radio, control, and

102 Ultrafast interfacial electron transfer in sensitized so

103 d state of (1*)DAPP(2+) which then undergoes ultrafast intramolecular electron transfer from (1*)DAPP

104 n, and improved stability in the presence of ultrafast irradiation.

105 This polymer undergoes ultrafast iSF in solution, generating high-energy triple

106 However, the mechanism for ultrafast isomerization of acetylene [HCCH](2+) to vinyl

107 s in the foldamer, starting from the initial ultrafast isomerization of the azobenzene unit(s) and en

108 bsorption data are employed to elucidate the ultrafast kinetics and efficiencies of charge separation

109 The ultrafast kinetics of CO rebinding to carbon monoxide ox

110 itated electrode arrays (IDE-arrays) towards ultrafast, label-free screening of heart type-FABP and M

111 aging, broadband optical communications, and ultrafast laser display and printing.

112 method by which the spectral intensity of an ultrafast laser pulse can be accumulated at selected fre

113 switching (AOS) of magnetization induced by ultrafast laser pulses is fundamentally interesting and

114 atom's motion in a harmonic oscillator using ultrafast laser pulses.

115 rpositions into spatial superpositions using ultrafast laser pulses.

116 tions are now amenable to direct study using ultrafast laser spectroscopy techniques and advances in

117 ited for mode-locking device applications in ultrafast laser technology, whereas nonlinearities in th

118 The directional asymmetry in the ultrafast laser writing is qualitatively described in te

119 ves rise to the directional asymmetry of the ultrafast laser writing.

120 ulation for many novel applications based on ultrafast laser-induced electron emission.

121 le black phosphorus ink suitable for printed ultrafast lasers and photodetectors.

122 ted black phosphorus as a passive switch for ultrafast lasers, stable against intense irradiation, an

123 The ultrafast light-activated electrocyclic ring-opening rea

124 The promise of ultrafast light-field-driven electronic nanocircuits has

125 faces capable of high faradaic efficiency at ultrafast limits.

126 Using MD simulations, we conclude that ultrafast local field fluctuations exist whether or not

127 rrelations is vital for our understanding of ultrafast magnetic dynamics.

128 Does the excitation of ultrafast magnetization require direct interaction betwe

129 is mode of stress propagation as a potential ultrafast mechanism of signaling that may quickly couple

130 cale of isomerization in molecules involving ultrafast migration of constituent atoms is difficult to

131 hybrid metamaterials are capable of offering ultrafast modulation of THz radiation.

132 r harmonic generation, optical limiting, and ultrafast modulation.

133 used here to demonstrate the feasibility of ultrafast multislice (13)C MRI after tail vein injection

134 This is particularly problematic in ultrafast nanophotonics, including optical sensing, nonl

135 mplications in optical energy conversion and ultrafast nanophotonics.

136 pplications in optical energy conversion and ultrafast nanophotonics.

137 he relaxed (d,d) state has been obtained via ultrafast Ni K-edge XANES (X-ray absorption near edge st

138 The description of ultrafast nonadiabatic chemical dynamics during molecula

139 s imply novel potential application of BP in ultrafast nonlinear phase modulation devices based on th

140 was experimentally explored in the field of ultrafast nonlinear photonics.

141 Transparent conductive oxides exhibit large ultrafast nonlinearities under both interband and intrab

142 Pumping at 530 nm leads to ultrafast nonradiative relaxation from the singlet metal

143 nd materials is crucial for producing strong ultrafast nonthermal electron components.The creation of

144 ueezed automatic behaviours characterised by ultrafast oligomeric action chunks that correlated with

145 ution is essential for investigating various ultrafast optical dynamics.

146 We find that, at early time after the ultrafast optical excitation, graphene undergoes a latti

147 extremely fast response of this material to ultrafast optical excitation.

148 We have applied far-infrared and ultrafast optical Kerr effect spectroscopies on carefull

149 such as photoconductivity time-of-flight and ultrafast optical measurements, many aspects of the dyna

150 Here, exploiting advances in ultrafast optical metrology, we perform real-time measur

151 mprehensive understanding of many intriguing ultrafast optical phenomena that evolve over a timescale

152 The approach exploits ultrafast optical sources with slow group velocity propa

153 delocalized excitons has been challenged by ultrafast optical spectroscopy experiments with the Fenn

154 We have utilized ultrafast optical spectroscopy to study carrier dynamics

155 their intriguing physics and applications in ultrafast optics and supercontinuum generation.

156 ning dynamic phases that may be exploited in ultrafast optoelectronic and optospintronic devices.

157 magnetic field duration originates from the ultrafast optothermal and optomagnetic coupling.

158 Here we discuss these topics in relation to ultrafast organic photochemical reactions in homogeneous

159 The ultrafast orientational disorder of molecular dipoles, a

160 (in terms of speed and energy) of these-the ultrafast outflows-are the subset of X-ray-detected outf

161 Employing an ultrafast p-i-n photodiode with smaller active area diam

162 We present the operation of an ultrafast passively mode-locked fibre laser, in which fl

163 sensitive biomolecules because of strong and ultrafast perturbations from biomolecule-solvent interac

164 n of detailed structural descriptions of the ultrafast photochemical events that they undergo, in par

165 Ultrafast photochemical reactions in liquids occur on si

166 ring of graphene nanoribbons (GNRs) on their ultrafast photoconductivity is investigated.

167 ponse time has shown remarkable potential in ultrafast photodetection.

168 n-thermal phase developing immediately after ultrafast photoexcitation and lasting few picoseconds.

169 ulations offer molecular-level insights into ultrafast photoinduced charge separation potentially tri

170 forming highly efficient energy transfer and ultrafast photoinduced electron transfer in well-defined

171 Such ultrafast photoinduced reactions do no longer obey the K

172 As such, the measurements, performed via ultrafast photoluminescence, relate the dependence of ch

173 timize the material bandgap without altering ultrafast photophysics is reported.

174 n applications ranging from spectroscopy and ultrafast physics, through to absolute frequency measure

175 t X-ray absorption to sensitively follow the ultrafast pipi*/npi* electronic relaxation of hetero-org

176 Ultrafast, polarization-selective time-resolved X-ray ab

177 urfactant-free, inertial centralisation, and ultrafast polymerisation, in a scalable flow reactor.

178 sonances at the carbon K-edge establishes an ultrafast population of the T1 state ((3)pipi*) in AcAc

179 Ultrafast processes in light-absorbing proteins have bee

180 f attosecond methods to the investigation of ultrafast processes in molecules, with emphasis in molec

181 cal detection and identification, studies of ultrafast processes, and laser metrology.

182 applications, e.g., the characterization of ultrafast processes, time-resolved fluorescence imaging,

183 sed matter systems, the time scale for such "ultrafast" processes is typically set by the Fermi energ

184 ering (TR-SWAXS) is capable of tracking such ultrafast protein dynamics.

185 Ultrafast proton migration and isomerization are key pro

186 We describe ultrafast proton transfer in the ground electronic state

187 terfering them with an arbitrarily polarized ultrafast pulse under measurement.

188 ed coherent control of a single SiV(-) using ultrafast pulses as short as 1 ps, significantly faster

189 ans of producing coherent, short wavelength, ultrafast pulses from a compact set-up.

190 he basis of microscopic theory combined with ultrafast pump-probe experiments, we reveal a new low-in

191 ere we summarise recent experimental (mostly ultrafast pump-probe spectroscopy studies) and computati

192 brational dynamics in WTe2 crystals by using ultrafast pump-probe spectroscopy.

193 Here, we reveal an ultrafast radiative cooling regime between neighboring p

194 This review discusses the combination of ultrafast Raman spectroscopic techniques with plasmonic

195 directly, making it possible to identify the ultrafast reaction pathways.

196 An ultrafast rechargeable multi-ions battery is presented,

197 by high-frequency stimulation and support an ultrafast recovery of neurotransmitter release after low

198 This ultrafast relaxation differs from dynamics occurring on

199 happening in most cases, uracil exhibits an ultrafast relaxation mechanism from the electronically e

200 over, our theoretical calculations show that ultrafast relaxation of the wavepacket to a lower excite

201 An ultrafast release of the compressive strain along the su

202 We here demonstrate that ultrafast reorientation dynamics of leucine amino acids

203 trate that the transition is cooperative and ultrafast, requiring a critical absorbed photon density

204 matter interactions at the atomic scale with ultrafast resolution in image, diffraction, and energy s

205 ide access to coupled degrees of freedom and ultrafast response functions on the characteristic lengt

206 proposed as an effective approach to achieve ultrafast response ultraviolet sensing in p-Si/n-ZnO het

207 Ultrafast, reversible intersystem crossing (ISC) is repo

208 00Hz) were detected in 23 of 40 patients and ultrafast ripples (UFRs; 1,000-2,000Hz) in almost half o

209 id all-fiber ring laser using DNA film as an ultrafast SA and using Erbium-doped fiber as an efficien

210 We also demonstrated ultrafast saturable absorption (SA) with a modulation de

211 Here, we utilize a novel technique, ultrafast-scanning fluorescence correlation spectroscopy

212 For example, the field of ultrafast science has been built on lasers that lock man

213 tspots, and finally the potential for future ultrafast SERS studies.

214 lse in time), and the temporal profile of an ultrafast signal is then encoded in the probe spectrum.

215 in the optical fiber, thus, slowing down the ultrafast signal to time scales easily recorded with fas

216 spectroscopy allow the capture of an entire ultrafast signal waveform in a single probe shot, which

217 se two approaches, a new unique, simple, yet ultrafast solid-state explosive reaction is proposed to

218 Stokes shift from 2DES spectra revealing an ultrafast solvent relaxation.

219 The ultrafast spatial and temporal dynamics of excited carri

220 Our findings provide new insight into the ultrafast spatial dynamics of excited carriers in materi

221 r, owing to the interdependent nanoscale and ultrafast spatiotemporal scales.

222 The ultrafast spectroelectrochemical experiments described h

223 Methods based on site-specific labeling and ultrafast spectroscopic detection of fluorescence signal

224 Recent advances of ultrafast spectroscopy allow the capture of an entire ul

225 f experimental quantifications, most notably ultrafast spectroscopy and quantum yield measurements in

226 Here, such optimization using ultrafast spectroscopy as a tool to optimize the materia

227 Ultrafast spectroscopy offers temporal resolution for pr

228 Ultrafast spectroscopy was used to probe the excited sta

229 Ultrafast spectroscopy, used together with steady-state

230 Thanks to the development of ultrafast (spectroscopy and imaging) tools, we are witne

231 parasitic mites over their wing margin with ultrafast speed and high spatial precision.

232 Ultrafast spincrossover is studied in Fe-Co Prussian blu

233 ce is undegraded by giant strain, as well as ultrafast strain sensors that exploit strain-dependent c

234 The emphasis is on the ultrafast structural dynamics of molecules at interfaces

235 However, using HEX-rays for ultrafast studies has been limited due to the lack of so

236 ulses, opening the possibility of performing ultrafast studies of X-ray-induced phenomena.

237 Using an ultrafast sub band gap probe of 400 nm and white light,

238 rt in the fabricated GNRs was studied on the ultrafast, sub-picosecond time scale using time-resolved

239 Ultrafast surface-enhanced Raman spectroscopy (SERS) has

240 Ultrafast switching (in the range of a few nanoseconds)

241 A recent example is an optically induced ultrafast switching device based on the transition betwe

242 has potential practical implications for the ultrafast switching of materials properties, such as opt

243 independence of the two nonlinearities, the ultrafast temporal dynamics of the material permittivity

244 n of a broadband high-contrast nanoprobe for ultrafast temporal resolution is challenging due to the

245 the atomic-scale spatial resolution, and the ultrafast temporal resolution of UEC represent the key e

246 resonant, internal quantum transitions using ultrafast terahertz quasi-particle transport.

247 , using gold bipyramids and light to achieve ultrafast thermocycling.

248 xpanding spectrum of these techniques in the ultrafast time domain is delivering new insight into the

249 ight-driven rotary motor are followed on the ultrafast time scale by femtosecond stimulated Raman spe

250 of phase reaction processes on the nanometer-ultrafast time scale opens new venues for engineering va

251 With the focus on the ultrafast time scale, we here discuss the light-induced

252 ter-protein interactions and dynamics on the ultrafast time scale.

253 he electronic structure of the flavin on the ultrafast time scale.

254 ight of structural and electronic changes at ultrafast time scales that often are very difficult or i

255 Ultrafast time-domain methods applied to strongly intera

256 of lipid bilayers by using a combination of ultrafast time-resolved infrared spectroscopy, molecular

257 Mott state with no cuprate analogue by using ultrafast time-resolved optical reflectivity to uncover

258 and YBa2Cu3O(6+x) (YBCO) single crystals by ultrafast time-resolved reflectivity.

259 tion have a variety of applications, such as ultrafast time-resolved spectroscopy and supercontinuum

260 ges or geminately recombine-is determined at ultrafast times, despite the fact that their actual spat

261 o manipulate light-matter interaction on the ultrafast timescale.

262 erently to a vibronically excited (1)(TT) on ultrafast timescales (<50 fs).

263 roposed to mediate singlet fission, forms on ultrafast timescales (in 300 fs) and that its formation

264 h lattice participation has been gathered on ultrafast timescales due to the irreversibility of solid

265 van der Waals-layered materials, at least on ultrafast timescales.

266 matter with tunable electronic properties on ultrafast timescales.

267 s are at present less clear, particularly on ultrafast timescales.

268 Ultrafast transfer of positive charge from the molecular

269 ons in the shell domain, as was confirmed by ultrafast transient absorption and emission lifetime mea

270 Ultrafast transient absorption and photoluminescence mea

271 The TET quantum efficiencies determined by ultrafast transient absorption measurements showed the s

272 onium lead iodide (CH3NH3PbI3) thin films by ultrafast transient absorption microscopy, demonstrating

273 Quantum chemical calculations and ultrafast transient absorption spectroscopy experiments

274 are directly and simultaneously observed by ultrafast transient absorption spectroscopy in the extre

275 cence lifetime microscopy of whole cells and ultrafast transient absorption spectroscopy of purified

276 ic CN radical can be observed directly using ultrafast transient absorption spectroscopy.

277 s been investigated in dichloromethane using ultrafast transient electronic absorption spectroscopy a

278 epting units, is observed in real time using ultrafast transient infrared absorption spectroscopy.

279 In contrast to the classical route of ultrafast transition to the lowest energy excited state

280 polaron localization is responsible for the ultrafast trapping of photoexcited carriers in haematite

281 We experimentally realise an ultrafast tunable metasurface consisting of subwavelengt

282 Here, Shcherbakov et al. realise an ultrafast tunable metasurface with picosecond-scale larg

283 Ultrafast two-dimensional infrared spectroscopy (2D IR)

284 Ultrafast two-dimensional infrared spectroscopy observes

285 Here we combine ultrafast two-dimensional vibrational spectroscopy and m

286 Applying an ultrafast UVpump(excitation)-IRpump(perturbation)-IRprob

287 Here, we implement ultrafast vacuum-UV (VUV)-driven electron-ion coincidenc

288 -based mutagenesis of OaAEP1, we obtained an ultrafast variant having hundreds of times faster cataly

289 molecular dynamics simulations as well as in ultrafast vibrational spectroscopy has led to new and de

290 te, which was studied using a combination of ultrafast visible and IR pump-probe spectroscopies and T

291 ent densities, crucial for many applications.Ultrafast vortex dynamics driven by strong currents defi

292 been thoroughly investigated, the physics of ultrafast vortices under strong currents remains largely

293 Advanced membranes that enable ultrafast water flux while demonstrating anti-biofouling

294 ) at low relative pressure of P/P0 = 0.4 and ultrafast water wetting capability in less than 10.0 s.

295 Ultrafast X-ray diffraction allows the direct imaging of

296 rmation within the protein active site using ultrafast x-ray pulses from an x-ray free-electron laser

297 electron lasers (XFELs) capable of producing ultrafast x-ray pulses has significantly impacted the un

298 ts demonstrate how free-electron-laser-based ultrafast X-ray scattering can be utilized to shed light

299 We review the tremendous advances in ultrafast X-ray science, over the past 15 years, making

300 erate the NMR measurement, we implemented an ultrafast Z-spectroscopic (UFZ) CEST method to boost the