Warm Dense Copper conductivity measurements using single-shot THz spectroscopy
ORAL
Abstract
Understanding WDM is critical for optimizing Inertial Confinement Fusion trajectory and modeling planetary dynamos. However, predicting WDM properties remains difficult due to the combination of non-trivial degeneracy and strong Coulomb coupling. While state-of-the-art computational tools are in development for predicting the transport properties of materials at WDM conditions, experimental data needed to validate such models are scarce [1].
Here we present near-zero-frequency (DC) electrical conductivity measurements of warm dense copper determined by THz spectroscopy [2,4]. Copper thin films were heated using intense laser pulses to WDM conditions and probed using single-cycle THz pulses. Combining the measured conductivities with temperature estimates based on the Two-Temperature model [5], the results of these measurements are compared with theoretical predictions and previous experimental measurements [6-9]. This represents an important step towards benchmark quality measurements, which are essential to provide critical tests of computational methods.
References:
[2] McKelvey, A., et al. 2017, Scientific Reports, 7(1), 7015
[3] B. K. Ofori-Okai, Rev. Sci. Instrum. 89(10), 10D109 (2019)
[4] B. K. Ofori-Okai, Phys. Plasmas 31(4), 042711 (2024)
[5] M. Maigler, Proc. SPIE 12939, High-Power Laser Ablation VIII, 129390Q (2024)
[6] S. Park, et al. Appl. Phys. Lett. 119(17), 174102 (2021)
[7] R. A. Matula, et al. J. Phys. Chem. Ref. Data 8, 1147 (1979)
[8] R. A. Grosse, Inorg. Nucl. Chem. Lett. 5, 963 (1969).
[9] A. W. DeSilva and J. D. Katsouros, Phys. Rev. E 57(5), 5945 (1998).
Here we present near-zero-frequency (DC) electrical conductivity measurements of warm dense copper determined by THz spectroscopy [2,4]. Copper thin films were heated using intense laser pulses to WDM conditions and probed using single-cycle THz pulses. Combining the measured conductivities with temperature estimates based on the Two-Temperature model [5], the results of these measurements are compared with theoretical predictions and previous experimental measurements [6-9]. This represents an important step towards benchmark quality measurements, which are essential to provide critical tests of computational methods.
References:
[2] McKelvey, A., et al. 2017, Scientific Reports, 7(1), 7015
[3] B. K. Ofori-Okai, Rev. Sci. Instrum. 89(10), 10D109 (2019)
[4] B. K. Ofori-Okai, Phys. Plasmas 31(4), 042711 (2024)
[5] M. Maigler, Proc. SPIE 12939, High-Power Laser Ablation VIII, 129390Q (2024)
[6] S. Park, et al. Appl. Phys. Lett. 119(17), 174102 (2021)
[7] R. A. Matula, et al. J. Phys. Chem. Ref. Data 8, 1147 (1979)
[8] R. A. Grosse, Inorg. Nucl. Chem. Lett. 5, 963 (1969).
[9] A. W. DeSilva and J. D. Katsouros, Phys. Rev. E 57(5), 5945 (1998).
*This work is supported by the DOE Office of Science, Fusion Energy Science under FWP 100182, FWP 100866, and by the DOE LDRD program at SLAC National Accelerator Laboratory, under contract DE-AC02-76SF00515 as part of the Panofsky Fellowship awarded to BKOO.
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Presenters
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Edna Rebeca R Toro Garza
- Stanford University