Nature

, volume 593 , issue 7859 , pages 351-361

The data-driven future of high-energy-density physics.

P. Hatfield ¹

Jim A. Gaffney ²

Gemma J Anderson ²

Suzanne Ali ²

L. A. Antonelli ³

Suzan Başeğmez Du Pree ⁴

Jonathan Citrin ⁵

Marta Fajardo ⁶

Patrick Knapp ⁷

B. Kettle ⁸

B. Kustowski ²

Michael J. MacDonald ²

Derek Mariscal ²

Madison E Martin ²

Taisuke NAGAYAMA ⁷

C. A. J. Palmer ⁹

John W. Peterson ²

S. J. Rose ^{1, 8}

J J Ruby ¹⁰

Carl Shneider ¹¹

M. J. V. Streeter ⁸

Will Trickey ³

Ben Williams ¹²

Hide authors affiliations Show authors affiliations: 12 affiliations

Clarendon Laboratory, University of Oxford, Oxford, UK |

Lawrence Livermore national Laboratory, Livermore, USA |

York Plasma Institute, Department of Physics, University of York, York, UK |

⁴

Nikhef, National Institute for Subatomic Physics, Amsterdam, The Netherlands |

⁵

DIFFER—Dutch Institute for Fundamental Energy Research, Eindhoven, the Netherlands |

⁶

Instituto de Plasmas e Fusão Nuclear, Instituto Superior Técnico, Lisbon, Portugal |

⁷

Sandia National Laboratories, Albuquerque, USA |

⁸

IMPERIAL College London, London, UK |

⁹

School of Mathematics and Physics, Queen’s University Belfast, Belfast, UK |

¹⁰

Laboratory for Laser Energetics, University of Rochester, Rochester, USA |

¹¹

Dutch National Center for Mathematics and Computer Science (CWI), Amsterdam, The Netherlands |

¹²

AWE Plc, Aldermaston, Reading, UK |

Publication type: Journal Article

Publication date: 2021-05-19

Springer Nature

Nature

scimago Q1

wos Q1

SJR: 18.288

CiteScore: 78.1

Impact factor: 48.5

ISSN: 00280836, 14764687

DOI: 10.1038/s41586-021-03382-w

Copy DOI

PubMed ID: 34012079

Multidisciplinary

Abstract

High-energy-density physics is the field of physics concerned with studying matter at extremely high temperatures and densities. Such conditions produce highly nonlinear plasmas, in which several phenomena that can normally be treated independently of one another become strongly coupled. The study of these plasmas is important for our understanding of astrophysics, nuclear fusion and fundamental physics—however, the nonlinearities and strong couplings present in these extreme physical systems makes them very difficult to understand theoretically or to optimize experimentally. Here we argue that machine learning models and data-driven methods are in the process of reshaping our exploration of these extreme systems that have hitherto proved far too nonlinear for human researchers. From a fundamental perspective, our understanding can be improved by the way in which machine learning models can rapidly discover complex interactions in large datasets. From a practical point of view, the newest generation of extreme physics facilities can perform experiments multiple times a second (as opposed to approximately daily), thus moving away from human-based control towards automatic control based on real-time interpretation of diagnostic data and updates of the physics model. To make the most of these emerging opportunities, we suggest proposals for the community in terms of research design, training, best practice and support for synthetic diagnostics and data analysis. This Perspective discusses how high-energy-density physics could tap the potential of AI-inspired algorithms for extracting relevant information and how data-driven automatic control routines may be used for optimizing high-repetition-rate experiments.

Found

2 citations

Kriz Ester

3 publications, 3 citations

h-index: 1

McGill University

Université de Montréal

1 citation

Delov Maksim

PhD in Engineering

26 publications, 72 citations

h-index: 5

National Research Nuclear University MEPhI

Research interests

Thermophysics

Top-30

Journals

	1 2 3 4 5 6 7 8 9
Physics of Plasmas	Physics of Plasmas, 9, 10.98% Physics of Plasmas 9 publications, 10.98%
Scientific Reports	Scientific Reports, 3, 3.66% Scientific Reports 3 publications, 3.66%
Machine Learning: Science and Technology	Machine Learning: Science and Technology, 3, 3.66% Machine Learning: Science and Technology 3 publications, 3.66%
Matter and Radiation at Extremes	Matter and Radiation at Extremes, 3, 3.66% Matter and Radiation at Extremes 3 publications, 3.66%
Review of Scientific Instruments	Review of Scientific Instruments, 3, 3.66% Review of Scientific Instruments 3 publications, 3.66%
High Energy Density Physics	High Energy Density Physics, 2, 2.44% High Energy Density Physics 2 publications, 2.44%
Plasma Physics and Controlled Fusion	Plasma Physics and Controlled Fusion, 2, 2.44% Plasma Physics and Controlled Fusion 2 publications, 2.44%
ACS applied materials & interfaces	ACS applied materials & interfaces, 2, 2.44% ACS applied materials & interfaces 2 publications, 2.44%
High Power Laser Science and Engineering	High Power Laser Science and Engineering, 2, 2.44% High Power Laser Science and Engineering 2 publications, 2.44%
Nuclear Science and Techniques/Hewuli	Nuclear Science and Techniques/Hewuli, 2, 2.44% Nuclear Science and Techniques/Hewuli 2 publications, 2.44%
Communications Physics	Communications Physics, 2, 2.44% Communications Physics 2 publications, 2.44%
Physical Review Research	Physical Review Research, 2, 2.44% Physical Review Research 2 publications, 2.44%
Journal of Physics: Conference Series	Journal of Physics: Conference Series, 1, 1.22% Journal of Physics: Conference Series 1 publication, 1.22%
npj Computational Materials	npj Computational Materials, 1, 1.22% npj Computational Materials 1 publication, 1.22%
Nature Communications	Nature Communications, 1, 1.22% Nature Communications 1 publication, 1.22%
Energy Sources, Part A: Recovery, Utilization and Environmental Effects	Energy Sources, Part A: Recovery, Utilization and Environmental Effects, 1, 1.22% Energy Sources, Part A: Recovery, Utilization and Environmental Effects 1 publication, 1.22%
Contributions to Plasma Physics	Contributions to Plasma Physics, 1, 1.22% Contributions to Plasma Physics 1 publication, 1.22%
Batteries	Batteries, 1, 1.22% Batteries 1 publication, 1.22%
Results in Physics	Results in Physics, 1, 1.22% Results in Physics 1 publication, 1.22%
Journal of the Taiwan Institute of Chemical Engineers	Journal of the Taiwan Institute of Chemical Engineers, 1, 1.22% Journal of the Taiwan Institute of Chemical Engineers 1 publication, 1.22%
New Journal of Physics	New Journal of Physics, 1, 1.22% New Journal of Physics 1 publication, 1.22%
Superconductor Science and Technology	Superconductor Science and Technology, 1, 1.22% Superconductor Science and Technology 1 publication, 1.22%
Japanese Journal of Applied Physics, Part 1: Regular Papers & Short Notes	Japanese Journal of Applied Physics, Part 1: Regular Papers & Short Notes, 1, 1.22% Japanese Journal of Applied Physics, Part 1: Regular Papers & Short Notes 1 publication, 1.22%
Polymers	Polymers, 1, 1.22% Polymers 1 publication, 1.22%
Journal of the American Chemical Society	Journal of the American Chemical Society, 1, 1.22% Journal of the American Chemical Society 1 publication, 1.22%
Nanoscale	Nanoscale, 1, 1.22% Nanoscale 1 publication, 1.22%
Journal of Plasma Physics	Journal of Plasma Physics, 1, 1.22% Journal of Plasma Physics 1 publication, 1.22%
Plasma	Plasma, 1, 1.22% Plasma 1 publication, 1.22%
Nature	Nature, 1, 1.22% Nature 1 publication, 1.22%
	1 2 3 4 5 6 7 8 9

Publishers

	2 4 6 8 10 12 14 16 18
AIP Publishing	AIP Publishing, 17, 20.73% AIP Publishing 17 publications, 20.73%
Springer Nature	Springer Nature, 16, 19.51% Springer Nature 16 publications, 19.51%
IOP Publishing	IOP Publishing, 11, 13.41% IOP Publishing 11 publications, 13.41%
Elsevier	Elsevier, 9, 10.98% Elsevier 9 publications, 10.98%
American Physical Society (APS)	American Physical Society (APS), 4, 4.88% American Physical Society (APS) 4 publications, 4.88%
Wiley	Wiley, 3, 3.66% Wiley 3 publications, 3.66%
MDPI	MDPI, 3, 3.66% MDPI 3 publications, 3.66%
American Chemical Society (ACS)	American Chemical Society (ACS), 3, 3.66% American Chemical Society (ACS) 3 publications, 3.66%
Royal Society of Chemistry (RSC)	Royal Society of Chemistry (RSC), 3, 3.66% Royal Society of Chemistry (RSC) 3 publications, 3.66%
Cambridge University Press	Cambridge University Press, 3, 3.66% Cambridge University Press 3 publications, 3.66%
Institute of Electrical and Electronics Engineers (IEEE)	Institute of Electrical and Electronics Engineers (IEEE), 2, 2.44% Institute of Electrical and Electronics Engineers (IEEE) 2 publications, 2.44%
Taylor & Francis	Taylor & Francis, 1, 1.22% Taylor & Francis 1 publication, 1.22%
Taiwan Institute of Chemical Engineers	Taiwan Institute of Chemical Engineers, 1, 1.22% Taiwan Institute of Chemical Engineers 1 publication, 1.22%
Japan Society of Applied Physics	Japan Society of Applied Physics, 1, 1.22% Japan Society of Applied Physics 1 publication, 1.22%
Frontiers Media S.A.	Frontiers Media S.A., 1, 1.22% Frontiers Media S.A. 1 publication, 1.22%
Association for Computing Machinery (ACM)	Association for Computing Machinery (ACM), 1, 1.22% Association for Computing Machinery (ACM) 1 publication, 1.22%
Optica Publishing Group	Optica Publishing Group, 1, 1.22% Optica Publishing Group 1 publication, 1.22%
Emerald	Emerald, 1, 1.22% Emerald 1 publication, 1.22%
	2 4 6 8 10 12 14 16 18

We do not take into account publications without a DOI.
Statistics recalculated weekly.

Are you a researcher?

Create a profile to get free access to personal recommendations for colleagues and new articles.

Metrics

Cite this

GOST |

Cite this

GOST Copy

Hatfield P. et al. The data-driven future of high-energy-density physics. // Nature. 2021. Vol. 593. No. 7859. pp. 351-361.

GOST all authors (up to 50) Copy

Hatfield P., Gaffney J. A., Anderson G. J., Ali S., Antonelli L. A., Başeğmez Du Pree S., Citrin J., Fajardo M., Knapp P., Kettle B., Kustowski B., MacDonald M. J., Mariscal D., Martin M. E., NAGAYAMA T., Palmer C. A. J., Peterson J. W., Rose S. J., Ruby J. J., Shneider C., Streeter M., Trickey W., Williams B. The data-driven future of high-energy-density physics. // Nature. 2021. Vol. 593. No. 7859. pp. 351-361.

RIS |

Cite this

RIS Copy

TY - JOUR

DO - 10.1038/s41586-021-03382-w

UR - https://doi.org/10.1038/s41586-021-03382-w

TI - The data-driven future of high-energy-density physics.

T2 - Nature

AU - Hatfield, P.

AU - Gaffney, Jim A.

AU - Anderson, Gemma J

AU - Ali, Suzanne

AU - Antonelli, L. A.

AU - Başeğmez Du Pree, Suzan

AU - Citrin, Jonathan

AU - Fajardo, Marta

AU - Knapp, Patrick

AU - Kettle, B.

AU - Kustowski, B.

AU - MacDonald, Michael J.

AU - Mariscal, Derek

AU - Martin, Madison E

AU - NAGAYAMA, Taisuke

AU - Palmer, C. A. J.

AU - Peterson, John W.

AU - Rose, S. J.

AU - Ruby, J J

AU - Shneider, Carl

AU - Streeter, M. J. V.

AU - Trickey, Will

AU - Williams, Ben

PY - 2021

DA - 2021/05/19

PB - Springer Nature

SP - 351-361

IS - 7859

VL - 593

PMID - 34012079

SN - 0028-0836

SN - 1476-4687

ER -

BibTex |

Cite this

BibTex (up to 50 authors) Copy

@article{2021_Hatfield,

author = {P. Hatfield and Jim A. Gaffney and Gemma J Anderson and Suzanne Ali and L. A. Antonelli and Suzan Başeğmez Du Pree and Jonathan Citrin and Marta Fajardo and Patrick Knapp and B. Kettle and B. Kustowski and Michael J. MacDonald and Derek Mariscal and Madison E Martin and Taisuke NAGAYAMA and C. A. J. Palmer and John W. Peterson and S. J. Rose and J J Ruby and Carl Shneider and M. J. V. Streeter and Will Trickey and Ben Williams},

title = {The data-driven future of high-energy-density physics.},

journal = {Nature},

year = {2021},

volume = {593},

publisher = {Springer Nature},

month = {may},

url = {https://doi.org/10.1038/s41586-021-03382-w},

number = {7859},

pages = {351--361},

doi = {10.1038/s41586-021-03382-w}

}

MLA

Cite this

MLA Copy

Hatfield, P., et al. “The data-driven future of high-energy-density physics..” Nature, vol. 593, no. 7859, May. 2021, pp. 351-361. https://doi.org/10.1038/s41586-021-03382-w.

Publisher

Springer Nature

Journal

Nature

scimago Q1

wos Q1

SJR

18.288

CiteScore

78.1

Impact factor

48.5

ISSN

00280836 (Print)

14764687 (Electronic)