ライフサイエンスコーパス: ultrafast

1 cal systems occurs at short distances and is ultrafast.

2 of the Tyr/ZnO-rGO/ITO bioelectrode revealed ultrafast (0.34 +/- 0.09 s) detection of DA in a wide li

3 state-of-the-art numerical calculations, an ultrafast ( 10 fs) relaxation due to Hund excitations an

4 1) MLCT state, 30 % of the molecules undergo ultrafast (150 fs) relaxation to the (3) MC state, in co

5 -nanotube photoluminescence spectroscopy and ultrafast 2D correlation.

6 By ultrafast 3D lattice light-sheet microscopy, we observed

7 ity of the nanotube ensemble and reveal that ultrafast (~50 fs) modulation of the exciton frequencies

8 lts, age < 50 y, using ultrahigh-field (7 T) ultrafast (802 ms) fMRI optimized for single-participant

9 ytical figures of merit of a low-dispersion (ultrafast) ablation cell geometry within the Cobalt abla

10 olasers and demonstrate their application to ultrafast all-optical switching at room temperature.

11 in, we report a semi-solid process featuring ultrafast and high-yield synthesis, and outstanding scal

12 photon-photon interactions are required for ultrafast and quantum optical signal processing circuitr

13 method for polymer-drug conjugates using an ultrafast and reversible click reaction in a post-polyme

14 This class of materials exhibits ultrafast and reversible structural transitions in respo

15 -pyridine reagents were shown to react in an ultrafast and selective manner with several cysteine-tag

16 We here report an ultrafast and sensitive dual-luciferase-based method to

17 akes, this study compares the ability of two ultrafast and ultrasensitive mass spectrometry technique

18 on of solar cell devices in combination with ultrafast broadband transient absorption spectroscopy, w

19 ence transients are directly imaged using an ultrafast camera.

20 The ultrafast carrier transfer across the van der Waals inte

21 Yet, the ultrafast carrier transport in mid-infrared QCLs has so

22 orescence up-conversion spectroscopy evinces ultrafast chalcogen-bonding cascade switching in the exc

23 l when seeking a detailed connection between ultrafast changes in optical-electronic properties and l

24 ple is not destroyed, providing insight into ultrafast charge and spin dynamics.

25 Understanding and controlling ultrafast charge carrier dynamics is of fundamental impo

26 probe the excited-state dynamics, revealing ultrafast charge separation (~4 ps) occurring from the P

27 The ultrafast charge transfer probed at high electron donor

28 Ultrafast charge transfer processes in polymer/fullerene

29 tworks, and their abundant interfaces enable ultrafast charger diffusion across the entire electrode.

30 The spontaneous ultrafast chemical reaction D(*+)-A(*-)-R(*) -> D(*+)-A-

31 All that we view of the world begins with an ultrafast cis to trans photoisomerization of the retinyl

32 oach paves the way toward the fabrication of ultrafast CMOS-compatible ferroelectric memories and ult

33 origin of its strong nonlinear response, the ultrafast coherent dynamics and the associated nanoscale

34 An advanced understanding of ultrafast coherent electron dynamics is necessary for th

35 ute perhaps the most viable solution towards ultrafast, compact, and tunable lasers in the UV spectra

36 ave been made to develop power-efficient and ultrafast computing machines in this post-Moore's law er

37 An overall ultrafast control mechanism is proposed by combining ins

38 ternal degrees of freedom, relaxation can be ultrafast, converting electronic energy in a few fs, or

39 Herein we show that, unlike in ferromagnets, ultrafast damping plays a crucial role in antiferromagne

40 In time-resolved measurements, we find that ultrafast damping results in an immediate spin canting a

41 n fermented beverages was developed coupling ultrafast dansylation conditions with ultra-high-perform

42 some dielectric media, showing potential for ultrafast data storage applications.

43 tructural property underlying the universal, ultrafast deactivation behavior of eumelanin in response

44 creen transition-metal complexes for similar ultrafast decays to optimize photochemical performance.

45 er than 100 femtoseconds-a phenomenon called ultrafast demagnetization(2-4).

46 ive properties for potential applications in ultrafast devices(1-3).

47 d computational and experimental study about ultrafast diffractive imaging of sucrose clusters which

48 verse acoustic (TA) phonons coexist with the ultrafast diffusion of Ag ions in the superionic phase,

49 optoacoustic imaging), MRI (abbreviated and ultrafast, diffusion-weighted imaging), and molecular br

50 A detailed study on the ultrafast dipole moment reorientation dynamics demonstra

51 We conclude that ultrafast dissociative-ionization could be a promising t

52 We also observed another ultrafast dynamic reflecting a weakening and restoring o

53 Here we reveal the ultrafast dynamics controlled by Hund's physics in stron

54 This new model explains the recent ultrafast dynamics in flavodoxin and elucidates the fund

55 Measurements of the ultrafast dynamics of a vibrational probe (the CN stretc

56 olecules, such as water and alcohols, on the ultrafast dynamics of diphenylcarbene in acetonitrile at

57 sers provide uniquely detailed access to the ultrafast dynamics of physical, chemical, and biological

58 The structure and ultrafast dynamics of the electric double layer (EDL) ar

59 osensitizers can only be determined from the ultrafast dynamics of the full photocycle, which is of p

60 f free space alone does not always result in ultrafast dynamics.

61 Such an ultrafast, economic, and scalable process for high-quali

62 new sciences using near-parallel, bright and ultrafast electron beams for single-shot imaging, to dir

63 specially for future high charge single-shot ultrafast electron diffraction (UED) and ultrafast elect

64 monochromator with 10(-5) energy spread for ultrafast electron diffraction (UED) and ultrafast elect

65 We combine ultrafast electron diffraction and time-resolved teraher

66 Here we show that ultrafast electron diffraction can be used to simultaneo

67 tter information into the mega-electron-volt ultrafast electron diffraction pattern.

68 ace is an indispensable step in studying the ultrafast electron dynamics on the attosecond scale.

69 We employ an ultrafast electron microscope to record movies of the su

70 hot ultrafast electron diffraction (UED) and ultrafast electron microscopy (UEM) experiments.

71 for ultrafast electron diffraction (UED) and ultrafast electron microscopy (UEM) is presented.

72 Here, we use two-color near-field ultrafast electron microscopy to photo-induce the insula

73 d transient absorption spectroscopy to study ultrafast electron transfer (ET) dynamics in a model don

74 We show that ultrafast electron transfer to MV(2+) and slow charge re

75 ctroscopies, enabling the disentanglement of ultrafast electronic and structural dynamics.

76 spectroscopy, is a new route to the study of ultrafast electronic dynamics in carbon-containing molec

77 e transition holds the promise of low-power, ultrafast electronics(2), but the relative roles of dopi

78 Ultrafast electrooptical sampling reveals the tightly sh

79 nal recycling pathways have been discovered, ultrafast endocytosis and activity-dependent bulk endocy

80 erize for the first time a dynamin-dependent ultrafast endocytosis in IHCs.SIGNIFICANCE STATEMENT Oto

81 hair cells also display a dynamin-dependent ultrafast endocytosis.

82 lecules that funnel all excitation quanta by ultrafast energy transfer to individual light-redirectin

83 By referencing ultrafast energy-resolved surface sensitive spectroscopy

84 Here, we show that these ultrafast ET dynamics highly depend on the coupling betw

85 Raman spectroscopy is applied to follow the ultrafast evolution of two different proteins, each bear

86 electronic chromophores photoselected by an ultrafast excitation pulse tuned through the UV-visible

87 While free electrons in metals respond to ultrafast excitation with refractive index changes on fe

88 pected thickness-dependent modulation of the ultrafast excited state dynamics in the 2DP/MoS(2) heter

89 d-state coherence data may be used to tailor ultrafast excited-state dynamics through targeted synthe

90 ic vesicle cycle, notably in triggering both ultrafast exocytosis and endocytosis and recruiting syna

91 ation of VO(2) the PIPT alone contributes to ultrafast expansion of this material as large as 0.45%,

92 Here, using ultrafast fluorescence spectroscopy, computational metho

93 form of cytosine chains (dC)(10), using the ultrafast fluorescence up-conversion technique.

94 ked at one of their imide positions, reveals ultrafast formation of the (T(1)T(1)) state.

95 In addition, we found a set of ultrafast funneling molecules that harvest three times m

96 this notion, semiconductor ring lasers with ultrafast gain recovery(9,10) can enter frequency comb r

97 that GluA3 contributes to the generation of ultrafast glutamatergic currents at these synapses, whic

98 ls' intrinsic spatial scale, we investigated ultrafast H-bond dynamics between water and biomimetic s

99 Time-resolved and ultrafast hard X-ray imaging, scattering and spectroscop

100 e the sample density is preserved during the ultrafast heating, we could estimate an initial internal

101 In this paper an ultrafast high-resolution method is introduced for the s

102 overcome these limitations, we developed an ultrafast high-temperature sintering (UHS) process for t

103 Ultrafast, high-intensity light-matter interactions lead

104 his acceleration is not the direct result of ultrafast hole extraction by the scavenger, but is rathe

105 measurements, we have clearly identified an ultrafast hole transfer process with a lifetime of about

106 ntration allows us to temporally resolve the ultrafast hydrogen adsorption and evolution processes in

107 on-linear x-ray interaction are decisive for ultrafast imaging applications.

108 els allow optimization of the parameters for ultrafast imaging experiments.

109 e the exciting progress it has opened by the ultrafast imaging of plasmonic phenomena on the nanofemt

110 This system also allowed three-dimensional ultrafast imaging of the linear polarization properties

111 The results show that MEA-SICM provides an ultrafast imaging platform for investigating the functio

112 e implementations: hyperspectral imaging and ultrafast imaging.

113 Although the previously characterized ultrafast indicators iGlu(u) and iGlu(f) had monophasic

114 volume regions in polymeric materials using ultrafast infrared (IR) polarization-selective pump-prob

115 Our joint ultrafast infrared spectroscopic and ab initio molecular

116 el the full relaxation pathway: Following an ultrafast interband transition, a void nanometer-sized b

117 date that the polaron pair is formed through ultrafast intra-layer hole transfer coupled with coheren

118 We show that GluA3 largely determines the ultrafast kinetics of endbulb synapses glutamatergic cur

119 Furthermore, the ultrafast kinetics we have explored, shows that the inje

120 easurements: time-resolved diffusion NMR and ultrafast Laplace NMR.

121 of such pulses is traditionally realized via ultrafast laser excitation of a light-to-strain transduc

122 Although ultrafast laser materials processing has advanced at a b

123 n the synergy between chemical synthesis and ultrafast laser processing.

124 ng electrons in an accumulation layer via an ultrafast laser pulse and monitoring their relaxation vi

125 Tuneable ultrafast laser pulses are a powerful tool for measuring

126 ties by spatially and temporally focusing an ultrafast laser to implement a projection-based layer-by

127 extreme light-matter interactions, including ultrafast laser-driven particle acceleration, attosecond

128 We find U atoms and UO molecules co-exist in ultrafast laser-produced plasmas even at early times aft

129 aradigm shift in the traditional concepts of ultrafast laser-solid interactions.

130 are promising for application as low-power, ultrafast lasers and modulators and for the study of man

131 ng, spintronics, plasmonics, photodetectors, ultrafast lasers, batteries, supercapacitors, and thermo

132 Advances in ultrafast lasers, chirped pulse amplifiers, and frequenc

133 y and coherent microscopy measurements using ultrafast lasers.

134 We also introduce an ultrafast local volume excitation (ULoVE) method for kil

135 ed on knowledge of how MoS(2) interacts with ultrafast (< 1 ps) pulses.

136 itation by these long-wave pulses undergo an ultrafast (<100 fs) charge separation in ~45% of particl

137 olution of (1)H and (19)F afforded by 60 kHz ultrafast magic angle spinning (MAS) and enable the anal

138 unique advantages for low-energy control of ultrafast magnetic dynamics(2).

139 scloses a highly efficient route towards the ultrafast manipulation of magnetism in antiferromagnetic

140 of exclusive intraband transitions to enable ultrafast manipulation of surface THz conductivity in Bi

141 Ultrafast measurements of the contractile response using

142 We propose a new high-throughput ultrafast method for large-scale proteomics approaches b

143 S spectra to provide a simple, reliable, and ultrafast methodology for olive oils classification in t

144 driven laser in these systems as well as for ultrafast microcavity LEDs using van der Waals (vdW) mat

145 Irreversible high-intensity ultrafast MIR laser-solid interactions are of primary in

146 ng the pulse behavior during the birth of an ultrafast mode-locked laser pulse and the stable single-

147 experimental investigation of high-intensity ultrafast modifications of silicon by single femtosecond

148 s approach will result in a new paradigm for ultrafast molecular diagnosis and can facilitate NA-base

149 By integrating the ultrafast MoS(2) rectifier with a flexible Wi-Fi-band an

150 and nanotribology is challenging due to its ultrafast motion, and the complex interplay of inter-mol

151 cific intracellular molecular vibrations via ultrafast multicolor stimulated Raman scattering (SRS) m

152 In this review, ultrafast NA-POCT platforms are discussed, outlining the

153 es as well as delineating recent advances in ultrafast NAAT applications.

154 ld form the basis for improved nonlinear and ultrafast nanophotonic devices.

155 The ultrafast nature and meso- and microscopic ordering of H

156 Due to their ultrafast nature and vast complexity, monitoring conical

157 ease of dopamine, which may contribute to an ultrafast negative feedback mechanism to constrain TIDA

158 To achieve ultrafast neurotransmission, neurons assemble synapses w

159 erstanding of excited state processes during ultrafast nonadiabatic chemical reactions.

160 We use ultrafast nonlinear coherent photoelectron microscopy to

161 We identify an unusual regime of ultrafast nonlinear dynamics in which an optical shock w

162 in, e.g., nanoparticle tracking analysis or ultrafast nonlinear frequency conversion.

163 r non-centrosymmetric photonic platforms for ultrafast nonlinear optics with scalable bandwidth.

164 resolves this paradox and reveals origins of ultrafast OHC function and power output in the context o

165 GHz, which is promising for next-generation ultrafast on-chip optical communications.

166 emerged given their unique properties (e.g. ultrafast operation, large bandwidths, low cross-talk).

167 l 6-hydroxydopamine (6-OHDA) lesion using an ultrafast opsin (Chronos).

168 By utilizing ultrafast optical measurements, we have clearly identifi

169 , we used an innovative strategy that merges ultrafast optical membrane potential and Ca(2+) measurem

170 y represent the three pillars of the virtual ultrafast optical spectrometer, able to deliver transien

171 Here, we combine polarization-resolved ultrafast optical spectroscopy and state-of-the-art dyna

172 Ultrafast optical spectroscopy confirms passivation of t

173 This is demonstrated by ultrafast optical spectroscopy with independent approach

174 ave been investigated using a combination of ultrafast optical transient absorption and Eu L3 X-ray t

175 We first review the progress in ultrafast optics, which has enabled the generation of br

176 and open up new opportunities for developing ultrafast opto-electronics using Weyl physics.

177 , ultrasensitive biomedical diagnostics, and ultrafast optoelectronic integrated circuits through the

178 The ultrafast partial deactivation of the (3) MLCT state con

179 arge separation suggests the existence of an ultrafast pathway for charge separation in the SMA-PSI t

180 ) biomarker for lung cancer, and complete an ultrafast PCR test in less than 3 min using a high power

181 Ultrafast perfusion enabled us to perform chemical modif

182 ron laser can unveil atomic-scale details of ultrafast phenomena.

183 ndividual nanowire of VO(2), we observe that ultrafast photo-doping drives the system into a metallic

184 for generating picosecond strain pulses via ultrafast photo-induced first-order phase transitions (P

185 ion is achieved by tuning photoexcitation of ultrafast photocurrents via the photogalvanic effect.

186 Ultrafast photoemission electron microscopy (PEEM) has d

187 implementing stereo-polarimetric compressed ultrafast photography (SP-CUP) to record light-speed hig

188 lambda) DS dynamics imaged by STS compressed ultrafast photography, enabling imaging at up to trillio

189 excited to form a charge-separated state via ultrafast photoinduced electron transfer from the PE(4)

190 is achievable now regarding the modeling of ultrafast photoinduced processes in complex molecular ar

191 The ultrafast photoinduced ring-opening of 1,3-cyclohexadien

192 to simulate the nonadiabatic dynamics of the ultrafast photoreaction in bR.

193 We present a simulation study on the ultrafast photorelaxation of uracil, based on a quantum

194 microvessel imaging (UMI), when applied with ultrafast planewave acquisitions, has demonstrated super

195 In this work, we report on a series of ultrafast plasmonic measurements that provide a direct m

196 power and speed, such as the mantis shrimp's ultrafast predatory strike and the flea's jump.

197 Such beams will be important for ultrafast probing of magnetic materials.

198 osecond science, namely, the manipulation of ultrafast processes with a tailored sequence of attoseco

199 s been designed to enable the observation of ultrafast processes with near-atomic spatial resolution.

200 s emergent moire ferroelectricity may enable ultrafast, programmable and atomically thin carbon-based

201 Possible mechanisms of tyrosine oxidation by ultrafast proton-coupled ET in CraCRY, a process about 4

202 Manipulating spins by ultrafast pulse laser provides a new avenue to switch th

203 We introduce an ultrafast pulsed laser welding approach that relies on f

204 half-metallic La(0.7) Sr(0.3) MnO(3) film by ultrafast pump-probe technique.

205 Electronic spectral, potentiometric, and ultrafast pump-probe transient dynamical data demonstrat

206 This state is shown to contribute to the ultrafast quenching of both neutral molecular excitation

207 ve led to advances in compact atomic clocks, ultrafast ranging, and spectroscopy.

208 versatile tools for precision spectroscopy, ultrafast ranging, as channel generators for telecom net

209 The (1) TT state could form at ultrafast rate and nearly quantitatively in solution.

210 chnology that could synthesize and count the ultrafast rate of the oscillating cycles of light.

211 ors can store and release electric energy at ultrafast rates and are extensively studied for applicat

212 idence detection and pattern recognition, at ultrafast rates.

213 THz AHE at room temperature demonstrates the ultrafast readout for the antiferromagnetic spintronics

214 , and the new QCL-irradiation mode, used for ultrafast recording at specific wavenumbers (the two dia

215 Simultaneous and efficient ultrafast recording of multiple photon tags contributes

216 als spin-polarized photocurrent generated by ultrafast relaxation of excited photocarriers separated

217 lowest electronically excited states undergo ultrafast relaxation.

218 about dynamical photochemical processes with ultrafast resolution and atomic specificity.

219 The biosensor exhibited ultrafast response (<3 s) to glucose with a considerably

220 uctor nonlinear plasmonic modulator, with an ultrafast response time of 290 fs.

221 e(2) hybrid sensor exhibits low noise level, ultrafast response/recovery times, and good flexibility

222 ultraviolet free-electron laser to trace the ultrafast ring opening of gas-phase thiophenone molecule

223 archers, new NAATs have developed to achieve ultrafast sample-to-answer protocols for the point-of-ca

224 tein-protein interaction site prediction and ultrafast scanning of protein surfaces for prediction of

225 Progress in ultrafast science allows for probing quantum superpositi

226 impact and opens new vistas in the field of ultrafast science and technology.

227 elds, including renewable energy devices and ultrafast sensors.

228 A method utilizing turbulent flow to perform ultrafast separations and screen chiral compounds in sup

229 Recent progress in high power ultrafast short-wave and mid-wave infrared lasers has en

230 nstruct the full 108-atom molecular movie of ultrafast singlet fission in a pentacene dimer, explicit

231 The ultrafast sintering method by Joule heating effectively

232 lization of computational predictions by the ultrafast sintering technique for the rapid optimization

233 able material quality are synthesized via an ultrafast sintering technique.

234 tial of a vanishing skyrmion Hall effect and ultrafast skyrmion dynamics.

235 their three-dimensional cone-shaped webs as ultrafast slingshots that catapult both the spider and t

236 This drives the need for ultrafast sources capable of delivering 10-15 fs duratio

237 Here, we report compressed ultrafast spectral photography (CUSP), which attains sev

238 Immunoblotting, mass spectrometry, and ultrafast spectroscopic results support the absence of a

239 Steady-state and ultrafast spectroscopic techniques were used to track th

240 c framework, 2D COF-5, is investigated using ultrafast spectroscopic techniques.

241 Ultrafast spectroscopies have become an important tool f

242 Using a combination of ultrafast spectroscopies, we investigate how such excite

243 Here, we report ultrafast spectroscopy experiments and quantum dynamics

244 Importantly, ultrafast spectroscopy has further proved that Cu N(x) c

245 In this work, ultrafast spectroscopy is used to explore the nature of

246 imental techniques based on photocurrent and ultrafast spectroscopy measurements.

247 tural dynamics is opening up new avenues for ultrafast spectroscopy of condensed matter.

248 Ultrafast spectroscopy of DA pinpoints the importance of

249 unprecedented view of electron dynamics and ultrafast spectroscopy on the atto- and femtosecond time

250 Ultrafast spectroscopy techniques use sequences of ultra

251 Quantum chemistry and ultrafast spectroscopy were used to identify a sequentia

252 e combined use of reaction kinetic analysis, ultrafast spectroscopy, and stoichiometric organometalli

253 pealing properties like zero stray field and ultrafast spin dynamics.

254 ations for high-density information storage, ultrafast spintronics, and effective microwave devices.

255 Ultrafast, sub-10-fs 2DES tracks the coherent motion of

256 Here, employing ultrafast surface-specific spectroscopy, we report the i

257 areas, e.g., optical memory, flip-flop, and ultrafast switches etc.

258 s important potential for energy conversion, ultrafast switching, nano-photonics, and nonlinear optic

259 n in the precursor solution phase and 2) the ultrafast synthesis of alloy MMNCs using thermal shock h

260 storage density, but remain unexplored using ultrafast techniques.

261 r locations in a new crystalline phase on an ultrafast time scale.

262 , we directly imaged individual "roamers" on ultrafast time scales in the prototypical formaldehyde d

263 Excited-state injection often occurs on ultrafast time scales with yields that can be tuned from

264 ectronic degrees of freedom-were observed in ultrafast time-resolved absorption measurements after ML

265 With the aid of the ultrafast time-resolved emission spectroscopy, the mecha

266 Remarkably, the ultrafast time-resolved experiments quantified for the f

267 100 K and 4 and 4.7 atm using shock tube and ultrafast, time-resolve laser absorption diagnostic tech

268 First, because of the ultrafast timescales and large energy gaps involved, mea

269 how a biological reaction can be followed on ultrafast timescales at the EuXFEL.

270 ently occur on fast (sub)microsecond but not ultrafast timescales which are difficult to probe experi

271 ust be exploited to modulate the QCL gain on ultrafast timescales.

272 xperiment and can be used for development of ultrafast Tm-doped fibre laser systems.

273 Ultrafast Tm-doped fibre lasers have been actively studi

274 Learning of anticipatory forces must be ultrafast to minimize tilting a visually symmetric objec

275 ) (Ln = Pr, Er, Yb) is studied using intense ultrafast transform limited (TL) and linearly chirped la

276 To this end we have used ultrafast transient absorbance spectroscopy, to define h

277 ents, electronic structure calculations, and ultrafast transient absorption revealed that efficient i

278 Ultrafast transient absorption spectroscopy in solution

279 action mixtures, via "backside irradiation." Ultrafast transient absorption spectroscopy indicates a

280 formation on a variety of factors and, using ultrafast transient absorption spectroscopy, elucidate t

281 mbining these findings with the results from ultrafast transient absorption spectroscopy, we show tha

282 rom that of bulk chlorophyll-a We present an ultrafast transient absorption study of FR-PSII, investi

283 Here, ultrafast transient infrared absorption spectroscopy is

284 o a substantial loss of their energy through ultrafast trapping.

285 Here, using ultrafast two-dimensional electronic spectroscopy (2DES)

286 Ultrafast two-dimensional infrared (2D-IR) spectra can n

287 as a model system to evaluate the ability of ultrafast two-dimensional infrared (2D-IR) spectroscopy

288 combination of site-specific isotope labels, ultrafast two-dimensional infrared spectroscopy, and spe

289 lly image TIPS-pentacene microcrystals using ultrafast two-dimensional white-light microscopy and dis

290 Using an ultrafast two-photon fluorescence microscope empowered b

291 Here we use ultrafast, two-dimensional infrared spectroscopy and mol

292 We measure the ultrafast (un)folding kinetics of five natural WW domain

293 Ultrafast UV-pump/soft-X-ray-probe spectroscopy is a sub

294 Ultrafast UV-Vis and mid-IR transient absorption data su

295 Here, we introduce an ultrafast vibrational fingerprinting approach for probin

296 Such a class of ultrafast wavefront shaper is capable of generating a se

297 Next, we review the achievements of ultrafast X-ray and electron diffraction, which provide

298 rop impact on a wide range of liquids, using ultrafast X-ray phase-contrast imaging.

299 to map the change in electron density using ultrafast x-ray scattering.

300 (0)/(1)Q(1) spin-orbit states is revealed by ultrafast XUV transient absorption measuring iodine 4d c