Demonstration of Scale-Invariant Rayleigh-Taylor Instability Growth in Laser-Driven Cylindrical Implosion Experiments

J. P. Sauppe; S. Palaniyappan; B. J. Tobias; J. L. Kline; K. A. Flippo; O. L. Landen; D. Shvarts; S. H. Batha; P. A. Bradley; E. N. Loomis; N. N. Vazirani; C. F. Kawaguchi; L. Kot; D. W. Schmidt; T. H. Day; A. B. Zylstra; E. Malka

doi:10.1103/PhysRevLett.124.185003

Demonstration of Scale-Invariant Rayleigh-Taylor Instability Growth in Laser-Driven Cylindrical Implosion Experiments

J. P. Sauppe
, S. Palaniyappan
, B. J. Tobias
, J. L. Kline
, K. A. Flippo
, O. L. Landen
, D. Shvarts
, S. H. Batha
, P. A. Bradley
, E. N. Loomis
, N. N. Vazirani
, C. F. Kawaguchi
, L. Kot
, D. W. Schmidt
, T. H. Day
, A. B. Zylstra
, E. Malka

Department of Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

51 Scopus citations

Abstract

Rayleigh-Taylor instability growth is shown to be hydrodynamically scale invariant in convergent cylindrical implosions for targets that varied in radial dimension and implosion timescale by a factor of 3. The targets were driven directly by laser irradiation providing a short impulse, and instability growth at an embedded aluminum interface occurs as it converges radially inward by a factor of 2.25 and decelerates on a central foam core. Late-time growth factors of 14 are observed for a single-mode m=20 azimuthal perturbation at both scales, despite the differences in laser drive conditions between the experimental facilities, consistent with predictions from radiation-hydrodynamics simulations. This platform enables detailed investigations into the limits of hydrodynamic scaling in high-energy-density systems.

Original language	English
Article number	185003
Journal	Physical Review Letters
Volume	124
Issue number	18
DOIs	https://doi.org/10.1103/PhysRevLett.124.185003
State	Published - 8 May 2020

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.124.185003

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Sauppe, J. P., Palaniyappan, S., Tobias, B. J., Kline, J. L., Flippo, K. A., Landen, O. L., Shvarts, D., Batha, S. H., Bradley, P. A., Loomis, E. N., Vazirani, N. N., Kawaguchi, C. F., Kot, L., Schmidt, D. W., Day, T. H., Zylstra, A. B., & Malka, E. (2020). Demonstration of Scale-Invariant Rayleigh-Taylor Instability Growth in Laser-Driven Cylindrical Implosion Experiments. Physical Review Letters, 124(18), Article 185003. https://doi.org/10.1103/PhysRevLett.124.185003

@article{ccfe2b07934245ce8a2bff5fd9307c05,

title = "Demonstration of Scale-Invariant Rayleigh-Taylor Instability Growth in Laser-Driven Cylindrical Implosion Experiments",

abstract = "Rayleigh-Taylor instability growth is shown to be hydrodynamically scale invariant in convergent cylindrical implosions for targets that varied in radial dimension and implosion timescale by a factor of 3. The targets were driven directly by laser irradiation providing a short impulse, and instability growth at an embedded aluminum interface occurs as it converges radially inward by a factor of 2.25 and decelerates on a central foam core. Late-time growth factors of 14 are observed for a single-mode m=20 azimuthal perturbation at both scales, despite the differences in laser drive conditions between the experimental facilities, consistent with predictions from radiation-hydrodynamics simulations. This platform enables detailed investigations into the limits of hydrodynamic scaling in high-energy-density systems.",

author = "Sauppe, \{J. P.\} and S. Palaniyappan and Tobias, \{B. J.\} and Kline, \{J. L.\} and Flippo, \{K. A.\} and Landen, \{O. L.\} and D. Shvarts and Batha, \{S. H.\} and Bradley, \{P. A.\} and Loomis, \{E. N.\} and Vazirani, \{N. N.\} and Kawaguchi, \{C. F.\} and L. Kot and Schmidt, \{D. W.\} and Day, \{T. H.\} and Zylstra, \{A. B.\} and E. Malka",

note = "Publisher Copyright: {\textcopyright} 2020 American Physical Society.",

year = "2020",

month = may,

day = "8",

doi = "10.1103/PhysRevLett.124.185003",

language = "English",

volume = "124",

journal = "Physical Review Letters",

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Sauppe, JP, Palaniyappan, S, Tobias, BJ, Kline, JL, Flippo, KA, Landen, OL, Shvarts, D, Batha, SH, Bradley, PA, Loomis, EN, Vazirani, NN, Kawaguchi, CF, Kot, L, Schmidt, DW, Day, TH, Zylstra, AB & Malka, E 2020, 'Demonstration of Scale-Invariant Rayleigh-Taylor Instability Growth in Laser-Driven Cylindrical Implosion Experiments', Physical Review Letters, vol. 124, no. 18, 185003. https://doi.org/10.1103/PhysRevLett.124.185003

TY - JOUR

T1 - Demonstration of Scale-Invariant Rayleigh-Taylor Instability Growth in Laser-Driven Cylindrical Implosion Experiments

AU - Sauppe, J. P.

AU - Palaniyappan, S.

AU - Tobias, B. J.

AU - Kline, J. L.

AU - Flippo, K. A.

AU - Landen, O. L.

AU - Shvarts, D.

AU - Batha, S. H.

AU - Bradley, P. A.

AU - Loomis, E. N.

AU - Vazirani, N. N.

AU - Kawaguchi, C. F.

AU - Kot, L.

AU - Schmidt, D. W.

AU - Day, T. H.

AU - Zylstra, A. B.

AU - Malka, E.

PY - 2020/5/8

Y1 - 2020/5/8

N2 - Rayleigh-Taylor instability growth is shown to be hydrodynamically scale invariant in convergent cylindrical implosions for targets that varied in radial dimension and implosion timescale by a factor of 3. The targets were driven directly by laser irradiation providing a short impulse, and instability growth at an embedded aluminum interface occurs as it converges radially inward by a factor of 2.25 and decelerates on a central foam core. Late-time growth factors of 14 are observed for a single-mode m=20 azimuthal perturbation at both scales, despite the differences in laser drive conditions between the experimental facilities, consistent with predictions from radiation-hydrodynamics simulations. This platform enables detailed investigations into the limits of hydrodynamic scaling in high-energy-density systems.

AB - Rayleigh-Taylor instability growth is shown to be hydrodynamically scale invariant in convergent cylindrical implosions for targets that varied in radial dimension and implosion timescale by a factor of 3. The targets were driven directly by laser irradiation providing a short impulse, and instability growth at an embedded aluminum interface occurs as it converges radially inward by a factor of 2.25 and decelerates on a central foam core. Late-time growth factors of 14 are observed for a single-mode m=20 azimuthal perturbation at both scales, despite the differences in laser drive conditions between the experimental facilities, consistent with predictions from radiation-hydrodynamics simulations. This platform enables detailed investigations into the limits of hydrodynamic scaling in high-energy-density systems.

UR - https://www.scopus.com/pages/publications/85084750186

U2 - 10.1103/PhysRevLett.124.185003

DO - 10.1103/PhysRevLett.124.185003

M3 - Article

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AN - SCOPUS:85084750186

SN - 0031-9007

VL - 124

JO - Physical Review Letters

JF - Physical Review Letters

IS - 18

M1 - 185003

ER -

Demonstration of Scale-Invariant Rayleigh-Taylor Instability Growth in Laser-Driven Cylindrical Implosion Experiments

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