M. Kammler scite author profile

The study of phase-transition dynamics in solids beyond a time-averaged kinetic description requires direct measurement of the changes in the atomic configuration along the physical pathways leading to the new phase. The timescale of interest is in the range 10(-14) to 10(-12) s. Until recently, only optical techniques were capable of providing adequate time resolution, albeit with indirect sensitivity to structural arrangement. Ultrafast laser-induced changes of long-range order have recently been directly established for some materials using time-resolved X-ray diffraction. However, the measurement of the atomic displacements within the unit cell, as well as their relationship with the stability limit of a structural phase, has to date remained obscure. Here we report time-resolved X-ray diffraction measurements of the coherent atomic displacement of the lattice atoms in photoexcited bismuth close to a phase transition. Excitation of large-amplitude coherent optical phonons gives rise to a periodic modulation of the X-ray diffraction efficiency. Stronger excitation corresponding to atomic displacements exceeding 10 per cent of the nearest-neighbour distance-near the Lindemann limit-leads to a subsequent loss of long-range order, which is most probably due to melting of the material.

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Ultrafast Bond Softening in Bismuth: Mapping a Solid's Interatomic Potential with X-rays

Fritz

Reis

Adams

et al. 2007

Science

373

267

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Intense femtosecond laser excitation can produce transient states of matter that would otherwise be inaccessible to laboratory investigation. At high excitation densities, the interatomic forces that bind solids and determine many of their properties can be substantially altered. Here, we present the detailed mapping of the carrier densityâdependent interatomic potential of bismuth approaching a solid-solid phase transition. Our experiments combine stroboscopic techniques that use a high-brightness linear electron acceleratorâbased x-ray source with pulse-by-pulse timing reconstruction for femtosecond resolution, allowing quantitative characterization of the interatomic potential energy surface of the highly excited solid.

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Detection of Nonthermal Melting by Ultrafast X-ray Diffraction

Siders¹,

Cavalleri²,

Sokolowski‐Tinten

et al. 1999

Science

515

234

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Using ultrafast, time-resolved, 1.54 angstrom x-ray diffraction, thermal and ultrafast nonthermal melting of germanium, involving passage through nonequilibrium extreme states of matter, was observed. Such ultrafast, optical-pump, x-ray diffraction probe measurements provide a way to study many other transient processes in physics, chemistry, and biology, including direct observation of the atomic motion by which many solid-state processes and chemical and biochemical reactions take place.

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Femtosecond X-Ray Measurement of Ultrafast Melting and Large Acoustic Transients

et al. 2001

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Anharmonic Lattice Dynamics in Germanium Measured with Ultrafast X-Ray Diffraction

et al. 2000

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Damping of impulsively generated coherent acoustic oscillations in a femtosecond laser-heated thin germanium film is measured as a function of fluence by means of ultrafast x-ray diffraction. By simultaneously measuring picosecond strain dynamics in the film and in the unexcited silicon substrate, we separate anharmonic damping from acoustic transmission through the buried interface. The measured damping rate and its dependence on the calculated temperature of the thermal bath is consistent with estimated four-body, elastic dephasing times (T2) for 7-GHz longitudinal acoustic phonons in germanium.

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M. Kammler

Femtosecond X-ray measurement of coherent lattice vibrations near the Lindemann stability limit

Ultrafast Bond Softening in Bismuth: Mapping a Solid's Interatomic Potential with X-rays

Detection of Nonthermal Melting by Ultrafast X-ray Diffraction

Femtosecond X-Ray Measurement of Ultrafast Melting and Large Acoustic Transients

Anharmonic Lattice Dynamics in Germanium Measured with Ultrafast X-Ray Diffraction

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