Generation of a large compressive strain wave in graphite by ultrashort-pulse laser irradiation

Xiaocui Wang; A. Jarnac; J. C. Ekström; U.J. Bengtsson; F. Dorchies; H. Enquist; A. Jurgilaitis; M. N. Pedersen; C. M. Tu; M. Wulff; J. Larsson

doi:10.1063/1.5089291

Generation of a large compressive strain wave in graphite by ultrashort-pulse laser irradiation

Xiaocui Wang, A. Jarnac, J. C. Ekström, U.J. Bengtsson, F. Dorchies, H. Enquist, A. Jurgilaitis, M. N. Pedersen, C. M. Tu, M. Wulff, J. Larsson^*

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電子物理學系

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2 引文斯高帕斯（Scopus）

摘要

We have studied strain wave generation in graphite induced by an intense ultrashort laser pulse. The study was performed in the intensity regime above the ablation threshold of graphite. The aim was to maximize the strain and, thus, also the internal pressure (stress). Laser pulses with a 1 ps temporal duration melt the surface of graphite resulting in a molten material which initially exists at the solid density. As the molten material expands, a compressive strain wave starts propagating into the crystal below the molten layer. The strain pulse was studied with time-resolved X-ray diffraction. At a temporal delay of 100 ps after laser excitation, we observed >10% compressive strain, which corresponds to a pressure of 7.2 GPa. This strain could be reproduced by hydrodynamic simulations, which also provided a temperature map as a function of time and depth.

原文	English
文章編號	024501
期刊	Structural Dynamics
卷	6
發行號	2
DOIs	https://doi.org/10.1063/1.5089291
出版狀態	Published - 1 3月 2019

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title = "Generation of a large compressive strain wave in graphite by ultrashort-pulse laser irradiation",

abstract = "We have studied strain wave generation in graphite induced by an intense ultrashort laser pulse. The study was performed in the intensity regime above the ablation threshold of graphite. The aim was to maximize the strain and, thus, also the internal pressure (stress). Laser pulses with a 1 ps temporal duration melt the surface of graphite resulting in a molten material which initially exists at the solid density. As the molten material expands, a compressive strain wave starts propagating into the crystal below the molten layer. The strain pulse was studied with time-resolved X-ray diffraction. At a temporal delay of 100 ps after laser excitation, we observed >10% compressive strain, which corresponds to a pressure of 7.2 GPa. This strain could be reproduced by hydrodynamic simulations, which also provided a temperature map as a function of time and depth.",

author = "Xiaocui Wang and A. Jarnac and Ekstr{\"o}m, {J. C.} and U.J. Bengtsson and F. Dorchies and H. Enquist and A. Jurgilaitis and Pedersen, {M. N.} and Tu, {C. M.} and M. Wulff and J. Larsson",

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T1 - Generation of a large compressive strain wave in graphite by ultrashort-pulse laser irradiation

AU - Wang, Xiaocui

AU - Jarnac, A.

AU - Ekström, J. C.

AU - Bengtsson, U.J.

AU - Dorchies, F.

AU - Enquist, H.

AU - Jurgilaitis, A.

AU - Pedersen, M. N.

AU - Tu, C. M.

AU - Wulff, M.

AU - Larsson, J.

PY - 2019/3/1

Y1 - 2019/3/1

N2 - We have studied strain wave generation in graphite induced by an intense ultrashort laser pulse. The study was performed in the intensity regime above the ablation threshold of graphite. The aim was to maximize the strain and, thus, also the internal pressure (stress). Laser pulses with a 1 ps temporal duration melt the surface of graphite resulting in a molten material which initially exists at the solid density. As the molten material expands, a compressive strain wave starts propagating into the crystal below the molten layer. The strain pulse was studied with time-resolved X-ray diffraction. At a temporal delay of 100 ps after laser excitation, we observed >10% compressive strain, which corresponds to a pressure of 7.2 GPa. This strain could be reproduced by hydrodynamic simulations, which also provided a temperature map as a function of time and depth.

AB - We have studied strain wave generation in graphite induced by an intense ultrashort laser pulse. The study was performed in the intensity regime above the ablation threshold of graphite. The aim was to maximize the strain and, thus, also the internal pressure (stress). Laser pulses with a 1 ps temporal duration melt the surface of graphite resulting in a molten material which initially exists at the solid density. As the molten material expands, a compressive strain wave starts propagating into the crystal below the molten layer. The strain pulse was studied with time-resolved X-ray diffraction. At a temporal delay of 100 ps after laser excitation, we observed >10% compressive strain, which corresponds to a pressure of 7.2 GPa. This strain could be reproduced by hydrodynamic simulations, which also provided a temperature map as a function of time and depth.

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DO - 10.1063/1.5089291

M3 - Article

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SN - 2329-7778

VL - 6

JO - Structural Dynamics

JF - Structural Dynamics

IS - 2

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ER -

Generation of a large compressive strain wave in graphite by ultrashort-pulse laser irradiation

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