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Autores principales: Toro, Edna R., Held, Tobias, Bergermann, Armin, Ikeya, Megan, Maigler, Maximilian, Sung, Eric R., Gericke, Dirk O., Mo, Mianzhen, Rethfeld, Baerbel, Glenzer, Siegfried H., Ofori-Okai, Benjamin K.
Formato: Preprint
Publicado: 2026
Materias:
Acceso en línea:https://arxiv.org/abs/2604.15491
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author Toro, Edna R.
Held, Tobias
Bergermann, Armin
Ikeya, Megan
Maigler, Maximilian
Sung, Eric R.
Gericke, Dirk O.
Mo, Mianzhen
Rethfeld, Baerbel
Glenzer, Siegfried H.
Ofori-Okai, Benjamin K.
author_facet Toro, Edna R.
Held, Tobias
Bergermann, Armin
Ikeya, Megan
Maigler, Maximilian
Sung, Eric R.
Gericke, Dirk O.
Mo, Mianzhen
Rethfeld, Baerbel
Glenzer, Siegfried H.
Ofori-Okai, Benjamin K.
contents Ultrafast melting is fundamentally a structural transition of the ionic lattice, but this rearrangement also reshapes the electronic properties by changing the energy landscape and scattering mechanisms. Although the electrons react almost instantaneously, it is not a priori clear how much lattice disorder is required for a significant response. Here, we show that the onset of melting already produces a clear electronic signature in polycrystalline copper. Using single-shot terahertz time-domain spectroscopy on thin films excited over a wide range of laser fluences, we infer the transient conductivity during the first picoseconds after excitation. The data, supported by two-temperature molecular-dynamics simulations, show that before melting, electron transport is substantially limited by grain-boundary scattering and that melting strongly suppresses this channel. As melting begins at these interfaces, we observe a transient increase in the conductivity that directly marks the onset of the phase transition. More broadly, these results show that ionic and electronic relaxation stages are closely coupled in nonequilibrium laser-driven matter and that optical measurements can resolve distinct stages of melting.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15491
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Electronic Signature of Melting Onset in Polycrystalline Copper at Extreme Conditions
Toro, Edna R.
Held, Tobias
Bergermann, Armin
Ikeya, Megan
Maigler, Maximilian
Sung, Eric R.
Gericke, Dirk O.
Mo, Mianzhen
Rethfeld, Baerbel
Glenzer, Siegfried H.
Ofori-Okai, Benjamin K.
Materials Science
Ultrafast melting is fundamentally a structural transition of the ionic lattice, but this rearrangement also reshapes the electronic properties by changing the energy landscape and scattering mechanisms. Although the electrons react almost instantaneously, it is not a priori clear how much lattice disorder is required for a significant response. Here, we show that the onset of melting already produces a clear electronic signature in polycrystalline copper. Using single-shot terahertz time-domain spectroscopy on thin films excited over a wide range of laser fluences, we infer the transient conductivity during the first picoseconds after excitation. The data, supported by two-temperature molecular-dynamics simulations, show that before melting, electron transport is substantially limited by grain-boundary scattering and that melting strongly suppresses this channel. As melting begins at these interfaces, we observe a transient increase in the conductivity that directly marks the onset of the phase transition. More broadly, these results show that ionic and electronic relaxation stages are closely coupled in nonequilibrium laser-driven matter and that optical measurements can resolve distinct stages of melting.
title Electronic Signature of Melting Onset in Polycrystalline Copper at Extreme Conditions
topic Materials Science
url https://arxiv.org/abs/2604.15491