Observation of Ultrafast Nonequilibrium Collective Dynamics in Warm Dense Hydrogen

Fäustlin, R. R.; Bornath, Th.; Döppner, T.; Düsterer, S.; Förster, E.; Fortmann, C.; Glenzer, S. H.; Göde, S.; Gregori, G.; Irsig, Robert; Laarmann, Tim; Lee, H.J.; Li, B.; Meiwes‐Broer, K. H.; Mithen, J.; Nagler, Bob; Przystawik, Andreas; Redlin, H.; Redmer, R.; Reinholz, H.; Röpke, G.; Tavella, F.; Thiele, R.; Tiggesbäumker, J.; Toleikis, S.; Uschmann, I.; Vinko, S. M.; Whitcher, T.; Zastrau, U.; Ziaja, Beata; Tschentscher, Thomas

doi:10.1103/physrevlett.104.125002

Cited by 103 publications

(94 citation statements)

References 38 publications

(37 reference statements)

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“…We also measured the single-pulse off-Bragg (diffuse) forward scattering spectrum from thin HOPG films (15 m) with a scattering angle of 30 (scattering vector k % 0:52 A À1 ) using a curved HOPG crystal spectrometer (close to von Hamos geometry [14]) with a resolution of 3.5 eV and a spectral width of 300 eV. Off resonance (''diffuse'' or ''Thomson'') x-ray scattering [15] has been developed and applied recently to study high-energy density plasmas using longerwavelength XFELs [16].…”

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confidence: 99%

Ultrafast Transitions from Solid to Liquid and Plasma States of Graphite Induced by X-Ray Free-Electron Laser Pulses

et al. 2012

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We used photon pulses from an x-ray free-electron laser to study ultrafast x-ray-induced transitions of graphite from solid to liquid and plasma states. This was accomplished by isochoric heating of graphite samples and simultaneous probing via Bragg and diffuse scattering at high time resolution. We observe that disintegration of the crystal lattice and ion heating of up to 5 eV occur within tens of femtoseconds. The threshold fluence for Bragg-peak degradation is smaller and the ion-heating rate is faster than current x-ray-matter interaction models predict. [2,3], and in high-energy-density science [4]. Triggered by intense photon pulses in the laboratory, such phase transitions are complex. The kinetics of optical photoninduced transitions has been studied extensively [1,5,6]. Optical photons are absorbed through collective electronic processes [7]. In contrast, x-ray-induced dynamics are expected to differ substantially because x rays generate high-energy photoelectrons that equilibrate through collisional ionization and develop into a hot electron gas. Additionally, x rays penetrate materials to depths of more than 1 m, whereas optical penetration depths are rather short ($ 10 nm). The emergence of x-ray free-electron lasers (XFELs) now enables the study of ultrafast x-rayinduced transitions at extremely high time resolution and over a large, isochorically heated volume.We used pulses from an XFEL to excite graphite isochorically to extreme conditions with electron temperatures up to about 10 eV [8]. This induced ultrafast electronic processes and, ultimately, an order-disorder transformation. We characterized the x-ray-induced ultrafast ionization, lattice destruction, and temperaturerelaxation dynamics with a temporal resolution of tens of femtoseconds by measuring the dynamic structure factor, Sðk; !Þ, simultaneously both on and off the Bragg resonance. At low x-ray intensities, the crystal structure stays intact, the Bragg peak is very strong, and diffuse scattering is weak. With increasing intensities, the Bragg peak degrades due to atomic ionization and motion, and the forward diffuse elastic-scattering signal increases correspondingly. The combined measurements of the pulse-width dependence and fluence dependence of these signals allowed us to extract the ion temperature as a function of time.We performed the experiments at the Linac Coherent Light Source (LCLS) [9], using an x-ray energy of 2 keV, pulse energies of up to 2.8 mJ, and pulse durations of 40, 60, and 80 fs. We determined the multiple-shot averaged x-ray pulse duration from statistical analysis of single-shot spectra within an error of 30% [10]. The pulse energy was measured for each shot using an upstream nitrogenfluorescence detector [11]. The transmission of the beam line was about ð15 AE 3Þ% [12]. The focal spot area was determined from microscopic analysis of low-fluence beam imprints in yttrium aluminum garnet [13]. We focused the x-ray pulses to a beam area of 36-10 m 2 onto a highly oriented pyrolytic-graphite (HOPG) crystal, a...

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Ultrafast Transitions from Solid to Liquid and Plasma States of Graphite Induced by X-Ray Free-Electron Laser Pulses

et al. 2012

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“…Losing its energy in this process, the electron falls into the Fermi sea of the valence or conduction band electrons, thermalizing with them. It has been demonstrated in a number of works that for the case of XUV or X-ray excited electrons the low-energy electron fraction thermalizes much faster than the whole electron subsystem including the high-energy electron fraction [15][16][17][18][19]. The high-energy electrons, in contrast, remain nonthermalized over a few tens or even hundreds of femtoseconds.…”

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confidence: 99%

“…These brilliant FEL-sources of extreme ultraviolet and soft X-ray radiation provide short pulses of intensities inaccessible before. A response of irradiated materials to femtosecond X-ray laser pulses has been intensively studied both experimentally [5][6][7][8][9][10][11][12][13][14][15] and theoretically [13][14][15][16][17][18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Non-thermal phase transitions in semiconductors under femtosecond XUV irradiation

2013

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When a semiconductor or a dielectric is irradiated with ultrashort intense X-ray pulse, several processes occur: first the photoabsorption brings the electron subsystem out of equilibrium, bringing valence or deeper shells electrons into high energy states of the conduction band. Then, secondary electron cascading promotes further electrons of the valence to conduction band increasing their number there. These electrons also influence the atomic motion, modifying the interatomic forces. This process is known as a nonthermal melting. It can turn a material into a new phase state on ultrashort timescales. Recently developed hybrid model for treating all of these processes with different computational tools was reported in [N. Medvedev et al, New J. Phys. 15, 015016 (2013)]. Based on this model, we present here further investigations of nonthermal processes occurring in diamond under irradiation with a FLASH pulse of 10 fs FWHM and 92 eV photon energy. It is shown that the diamond turns into graphite under such irradiation, independently whether constant pressure or constant volume modeling is performed. However, for the latter case, the time of the nonthermal phase transition is longer (few tens of fs for P=const vs few hundreds of fs for V=const) and the damage threshold is slightly higher (0.69 eV/atom vs 0.74 eV/atom, correspondingly).

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“…Xrays emitted from laser produced plasmas [2,3] can probe the warm dense matter (WDM) region [4,5] with temperatures of several eV and densities close to solid density [6,7,8] up to compressed matter well above solid density at electron temperatures T e between 0.1 eV and several 10 eV [9,10,11,12,13]. The study of dense plasmas is also possible with the implementation of free-electron lasers which provide brilliant radiation in the soft x-ray region at the free-electron LASer Hamburg (FLASH) at DESY, Hamburg [14,15] or in the x-ray region at the Linac Coherent Light Source (LCLS) in Stanford [16], and will be available in the future at the European XFEL in Hamburg [17].…”

Section: Introductionmentioning

confidence: 99%

Two-color Thomson scattering at FLASH

Sperling

Thiele

Holst

et al. 2011

High Energy Density Physics

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We propose a two-color pump-probe Thomson scattering experiment at the FLASH facility in Hamburg to characterize warm dense matter states. The fundamental free electron laser wavelength of 40.5 nm is used to pump a liquid hydrogen jet that is subsequently probed with the third harmonic at 13.5 nm. We have considered the laser-target interaction in the pump and probe phase by using the radiation hydrodynamics code HELIOS. The calculation of the Thomson scattering spectrum is based on the Chihara formula which is evaluated using the Born-Mermin approximation for the free electron dynamic structure factor and the Debye-Hückel static structure factor for the elastic scattering part. We consider the full density-and temperature-dependent Thomson scattering cross section throughout the inhomogeneous target. The results indicate that the electron-ion equilibration rate can be extracted by measuring the electron and ion feature with varying time delays between the pump and the probe pulse.

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Observation of Ultrafast Nonequilibrium Collective Dynamics in Warm Dense Hydrogen

Cited by 103 publications

References 38 publications

Ultrafast Transitions from Solid to Liquid and Plasma States of Graphite Induced by X-Ray Free-Electron Laser Pulses

Ultrafast Transitions from Solid to Liquid and Plasma States of Graphite Induced by X-Ray Free-Electron Laser Pulses

Non-thermal phase transitions in semiconductors under femtosecond XUV irradiation

Two-color Thomson scattering at FLASH

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