M. J.-E. Manuel

2.2k total citations
65 papers, 991 citations indexed

About

M. J.-E. Manuel is a scholar working on Nuclear and High Energy Physics, Mechanics of Materials and Geophysics. According to data from OpenAlex, M. J.-E. Manuel has authored 65 papers receiving a total of 991 indexed citations (citations by other indexed papers that have themselves been cited), including 56 papers in Nuclear and High Energy Physics, 28 papers in Mechanics of Materials and 22 papers in Geophysics. Recurrent topics in M. J.-E. Manuel's work include Laser-Plasma Interactions and Diagnostics (51 papers), Laser-induced spectroscopy and plasma (28 papers) and High-pressure geophysics and materials (22 papers). M. J.-E. Manuel is often cited by papers focused on Laser-Plasma Interactions and Diagnostics (51 papers), Laser-induced spectroscopy and plasma (28 papers) and High-pressure geophysics and materials (22 papers). M. J.-E. Manuel collaborates with scholars based in United States, United Kingdom and France. M. J.-E. Manuel's co-authors include R. D. Petrasso, J. A. Frenje, R. Betti, D. D. Meyerhofer, J. R. Rygg, J. P. Knauer, N. Sinenian, O. V. Gotchev, D. T. Casey and F. H. Séguin and has published in prestigious journals such as Science, Physical Review Letters and Applied Physics Letters.

In The Last Decade

M. J.-E. Manuel

58 papers receiving 961 citations

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
M. J.-E. Manuel United States 17 865 422 344 241 219 65 991
H. G. Rinderknecht United States 21 945 1.1× 363 0.9× 382 1.1× 294 1.2× 267 1.2× 72 1.1k
D. P. Higginson United States 15 765 0.9× 339 0.8× 267 0.8× 252 1.0× 215 1.0× 60 844
P.M. Nilson United States 17 797 0.9× 536 1.3× 322 0.9× 349 1.4× 139 0.6× 42 930
R. P. J. Town United States 16 1.1k 1.2× 623 1.5× 364 1.1× 503 2.1× 93 0.4× 30 1.1k
H. Sio United States 15 459 0.5× 204 0.5× 222 0.6× 172 0.7× 117 0.5× 54 589
G. J. Williams United States 15 499 0.6× 266 0.6× 154 0.4× 271 1.1× 141 0.6× 55 645
Y. Aglitskiy United States 19 850 1.0× 506 1.2× 285 0.8× 393 1.6× 187 0.9× 47 1.0k
D. Klír Czechia 19 1.0k 1.2× 492 1.2× 124 0.4× 297 1.2× 360 1.6× 136 1.1k
M. Hohenberger United States 21 1.2k 1.4× 808 1.9× 369 1.1× 672 2.8× 104 0.5× 77 1.4k
Marius Schollmeier United States 19 1.0k 1.2× 683 1.6× 390 1.1× 546 2.3× 195 0.9× 44 1.1k

Countries citing papers authored by M. J.-E. Manuel

Since Specialization
Citations

This map shows the geographic impact of M. J.-E. Manuel's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by M. J.-E. Manuel with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites M. J.-E. Manuel more than expected).

Fields of papers citing papers by M. J.-E. Manuel

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by M. J.-E. Manuel. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by M. J.-E. Manuel. The network helps show where M. J.-E. Manuel may publish in the future.

Co-authorship network of co-authors of M. J.-E. Manuel

This figure shows the co-authorship network connecting the top 25 collaborators of M. J.-E. Manuel. A scholar is included among the top collaborators of M. J.-E. Manuel based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with M. J.-E. Manuel. M. J.-E. Manuel is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Arefiev, Alexey, O. Klimo, M. J.-E. Manuel, et al.. (2025). Compact in-vacuum gamma-ray spectrometer for high-repetition rate PW-class laser–matter interaction. Review of Scientific Instruments. 96(2).
2.
Bailly-Grandvaux, M., B. J. Winjum, M. J.-E. Manuel, et al.. (2025). Direct evidence of the effect of a moderate external magnetic field on stimulated Raman scattering in the kinetic regime. Physics of Plasmas. 32(9).
3.
Weber, S., et al.. (2025). Collimated γ-ray emission enabled by efficient direct laser acceleration. New Journal of Physics. 27(2). 23024–23024. 2 indexed citations
4.
Arefiev, Alexey, et al.. (2025). High-resolution direct phase control in the spectral domain in ultrashort pulse lasers for pulse-shaping applications. Journal of Instrumentation. 20(5). P05002–P05002.
5.
Forsman, A., M. J.-E. Manuel, Jarrod Williams, et al.. (2024). High repetition-rate foam targetry for laser–plasma interaction experiments: Concept and preliminary results. Review of Scientific Instruments. 95(6). 4 indexed citations
6.
Higginson, D. P., G. F. Swadling, David J. Larson, et al.. (2024). A deep learning approach to fast analysis of collective Thomson scattering spectra. Physics of Plasmas. 31(7). 2 indexed citations
7.
8.
Manuel, M. J.-E., et al.. (2024). A customizable data management framework for high-repetition-rate high-energy-density science. Review of Scientific Instruments. 95(9). 1 indexed citations
9.
Manuel, M. J.-E., et al.. (2024). State of Research Data Management in Latin American Universities 2022. Procedia Computer Science. 249. 209–215.
10.
Bailly-Grandvaux, M., B. J. Winjum, M. J.-E. Manuel, et al.. (2023). Validation of magnetized gas-jet experiments to investigate the effects of an external magnetic field on laser-plasma instabilities. Journal of Plasma Physics. 89(2). 4 indexed citations
11.
Tubman, Eleanor, B. B. Pollock, D. P. Higginson, et al.. (2023). Demonstrating imaging plate detector stacks for proton radiography using exploding pusher capsules. Nuclear Instruments and Methods in Physics Research Section A Accelerators Spectrometers Detectors and Associated Equipment. 1060. 169027–169027. 1 indexed citations
12.
Hartigan, Patrick, Rachel Young, Sallee Klein, et al.. (2022). Experimental observations of detached bow shock formation in the interaction of a laser-produced plasma with a magnetized obstacle. Physics of Plasmas. 29(1). 6 indexed citations
13.
Manuel, M. J.-E., S. Ghosh, F. N. Beg, et al.. (2022). Experimental evidence of early-time saturation of the ion-Weibel instability in counterstreaming plasmas of CH, Al, and Cu. Physical review. E. 106(5). 55205–55205. 4 indexed citations
14.
Higginson, A., S. Zhang, M. Bailly-Grandvaux, et al.. (2021). Electron acceleration at oblique angles via stimulated Raman scattering at laser irradiance >1016Wcm2μm2. Physical review. E. 103(3). 33203–33203. 2 indexed citations
15.
Manuel, M. J.-E., L. Willingale, A. Maksimchuk, et al.. (2020). Enhanced spatial resolution of Eljen-204 plastic scintillators for use in rep-rated proton diagnostics. Review of Scientific Instruments. 91(10). 103301–103301. 7 indexed citations
16.
Zylstra, A. B., R. S. Craxton, J. R. Rygg, et al.. (2020). Saturn-ring proton backlighters for the National Ignition Facility. Review of Scientific Instruments. 91(9). 93505–93505. 2 indexed citations
17.
Kim, J., A. Link, P. Fitzsimmons, et al.. (2020). Dynamic focusing of laser driven positron jets by self-generated fields. New Journal of Physics. 22(12). 123020–123020. 3 indexed citations
18.
Willingale, L., Alexey Arefiev, G. J. Williams, et al.. (2018). The unexpected role of evolving longitudinal electric fields in generating energetic electrons in relativistically transparent plasmas. New Journal of Physics. 20(9). 93024–93024. 37 indexed citations
19.
Williams, G. J., Daniel Barnak, G. Fiksel, et al.. (2016). Target material dependence of positron generation from high intensity laser-matter interactions. Physics of Plasmas. 23(12). 16 indexed citations
20.
Manuel, M. J.-E., C. K. Li, F. H. Séguin, et al.. (2012). First Measurements of Rayleigh-Taylor-Induced Magnetic Fields in Laser-Produced Plasmas. Physical Review Letters. 108(25). 255006–255006. 53 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

Explore authors with similar magnitude of impact

Breakdown of academic impact, for papers by H. G. Rinderknecht Breakdown of academic impact, for papers by D. P. Higginson Breakdown of academic impact, for papers by P.M. Nilson Breakdown of academic impact, for papers by R. P. J. Town Breakdown of academic impact, for papers by H. Sio Breakdown of academic impact, for papers by G. J. Williams Breakdown of academic impact, for papers by Y. Aglitskiy Breakdown of academic impact, for papers by D. Klír Breakdown of academic impact, for papers by M. Hohenberger Breakdown of academic impact, for papers by Marius Schollmeier
Rankless by CCL
2026