Heterogeneous to homogeneous melting transition visualized with ultrafast electron diffraction

Mo, Mianzhen; Chen, Zhijiang; Li, Renkai; Dunning, M.; Witte, B. B. L.; Baldwin, J. Kevin; Fletcher, L. B.; Kim, J. B.; Ng, A.; Redmer, R.; Reid, Alexander H.; Shekhar, Prashant; Shen, Xiaozhe; Shen, Mei; Sokolowski‐Tinten, K.; Tsui, Ying Y.; Wang, Y. Q.; Zheng, Qiang; Wang, X. J.; Glenzer, S. H.

doi:10.1126/science.aar2058

Cited by 159 publications

(186 citation statements)

References 47 publications

(55 reference statements)

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“…Homogeneous melting can be studied experimentally with special design of sample containers or energy input (Daeges et al, 1986;Mo et al, 2018). This process differs from that studied experimentally where nucleation sites, provided by sample containers and grain-grain contacts, are typically abundant.…”

Section: Theorymentioning

confidence: 99%

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Melting of CaSiO₃ Perovskite at High Pressure

Braithwaite

Stixrude

2019

Geophysical Research Letters

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Ab initio molecular dynamics simulations predict that CaSiO3 perovskite melts at 5600 K at 136 GPa, and 6400 K at 300 GPa, significantly higher than MgSiO3 perovskite. The entropy of melting (1.8 kB per atom) is much larger than that of many silicates at ambient pressure and of simple liquids and varies little with pressure. The volume of melting decreases rapidly with increasing pressure, to 3 % at 136 GPa, producing a melting slope that diminishes rapidly with pressure. We determine the melting temperature via the ZW method, combining the Z method, for which we clarify the theoretical basis, with a waiting time analysis. The ZW method results are internally confirmed by integrating the Clausius‐Clapeyron equation, which also yields our results for the entropy and volume of melting. We find the eutectic composition on the MgSiO3‐CaSiO3 join to be xCa = 0.26 at 136 GPa and that metasilicate melt is denser than coexisting silicates.

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Section: Theorymentioning

confidence: 99%

“…The homogeneous melting point is always greater than the equilibrium melting temperature. Homogeneous melting can be studied experimentally with special design of sample containers or energy input (Daeges et al, 1986;Mo et al, 2018).…”

Section: Theorymentioning

confidence: 99%

Melting of CaSiO₃ Perovskite at High Pressure

Braithwaite

Stixrude

2019

Geophysical Research Letters

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“…In nature, melting is usually initiated heterogeneously on surfaces, and a solid material immediately transforms into a liquid that is maintained at higher than the material's melting temperature [3,4]. However, melting homogeneously occurs inside a crystal if surface melting is suppressed, which can be experimentally achieved using coating [5,6] or laser [7][8][9][10][11][12] techniques. Homogeneous melting can be defined as the phase transition from solid to liquid in the surface-and defectfree crystal, in which there is no trigger to initiate disordering except thermal fluctuations, and nucleation is equally likely to occur anywhere.…”

Section: Introductionmentioning

confidence: 99%

“…In an earlier study, the limit of superheating was predicted using two different parameters based on vibrational instability and elastic shear instability, the Lindemann [1] and Born criteria [2], respectively. Even though experimental observation of the initial stage of homogeneous melting remains challenging because of the random creation of a liquid nucleus and its subsequent fast growth [5][6][7][8][9][10][11][12][13], recent developments in computer simulation have enabled us to closely examine its microscopic details [14][15][16][17][18][19][20][21][22][23][24][25][26][27]. Using molecular-dynamics (MD) simulations for a Lennard-Jones fluid, a study by Jin et al observed that homogeneous melting is initiated by clusters of vibrationally destabilised particles by satisfying the Lindemann and Born criteria [16,28].…”

Section: Introductionmentioning

confidence: 99%

Computational Study on Homogeneous Melting of Benzene Phase I

Mochizuki

2019

Crystals

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Molecular-dynamics simulations are used for examining the microscopic details of the homogeneous melting of benzene phase I. The equilibrium melting temperatures of our model were initially determined using the direct-coexistence method. Homogeneous melting at a higher temperature is achieved by heating a defect-and surfacefree crystal. The temperature-dependent potential energy and lattice parameters do not indicate a premelting phase even under superheated conditions. Further, statistical analyses using induction times computed from 200 melting trajectories were conducted, denoting that the homogeneous melting of benzene occurs stochastically, and that there is no intermediate transient state between the crystal and liquid phases. Additionally, the critical nucleus size is estimated using the seeding approach, along with the local bond order parameter. We found that the large diffusive motion arising from defect migration or neighbor-molecule swapping is of little importance during nucleation. Instead, the orientational disorder activated using the flipping motion of the benzene plane results in the melting nucleus.

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“…In ultrafast pump-probe experiments, the dynamics are initiated by a pump laser, then the sample is probed with an ultrashort laser pulse, electron bunch or x-ray pulse. The opportunities for ultrafast diffraction have widened due to the rapid development of sources, detectors, and instrumentation which allow for studying matter in extreme conditions [9].…”

Section: Introductionmentioning

confidence: 99%

Parallel-plate waveguides for terahertz-driven MeV electron bunch compression

Othman

Hoffmann²,

Kozina³

et al. 2019

Opt. Express

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We demonstrate the electromagnetic performance of waveguides for femtosecond electron beam bunch manipulation and compression with strong-field terahertz (THz) pulses. The compressor structure is a dispersion-free exponentially-tapered parallel-plate waveguide (PPWG) that can focus single-cycle THz pulses along one dimension. We show test results of the tapered PPWG structure using electro-optic sampling (EOS) at the interaction region with peak fields of at least 300 kV/cm given 0.9 µJ of incoming THz energy. We also present a modified shorted design of the tapered PPWG for better beam manipulation and reduced magnetic field as an alternative to a dual-feed approach. As an example, we demonstrate that with 5 µJ of THz energy, the PPWG compresses a 2.5 MeV electron bunch by a compression factor of more than 4 achieving a bunch length of about 18 fs.

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Heterogeneous to homogeneous melting transition visualized with ultrafast electron diffraction

Cited by 159 publications

References 47 publications

Melting of CaSiO₃ Perovskite at High Pressure

Melting of CaSiO₃ Perovskite at High Pressure

Computational Study on Homogeneous Melting of Benzene Phase I

Parallel-plate waveguides for terahertz-driven MeV electron bunch compression

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Heterogeneous to homogeneous melting transition visualized with ultrafast electron diffraction

Cited by 159 publications

References 47 publications

Melting of CaSiO3 Perovskite at High Pressure

Melting of CaSiO3 Perovskite at High Pressure

Computational Study on Homogeneous Melting of Benzene Phase I

Parallel-plate waveguides for terahertz-driven MeV electron bunch compression

Contact Info

Product

Resources

About

Melting of CaSiO₃ Perovskite at High Pressure

Melting of CaSiO₃ Perovskite at High Pressure