Thomas Lecas

598 total citations
38 papers, 501 citations indexed

About

Thomas Lecas is a scholar working on Electrical and Electronic Engineering, Materials Chemistry and Mechanics of Materials. According to data from OpenAlex, Thomas Lecas has authored 38 papers receiving a total of 501 indexed citations (citations by other indexed papers that have themselves been cited), including 23 papers in Electrical and Electronic Engineering, 18 papers in Materials Chemistry and 12 papers in Mechanics of Materials. Recurrent topics in Thomas Lecas's work include Metal and Thin Film Mechanics (11 papers), Dust and Plasma Wave Phenomena (10 papers) and Plasma Diagnostics and Applications (10 papers). Thomas Lecas is often cited by papers focused on Metal and Thin Film Mechanics (11 papers), Dust and Plasma Wave Phenomena (10 papers) and Plasma Diagnostics and Applications (10 papers). Thomas Lecas collaborates with scholars based in France, Germany and Morocco. Thomas Lecas's co-authors include Pascal Brault, Anne‐Lise Thomann, Amaël Caillard, Maxime Mikikian, Nadjib Semmar, A. L. Thomann, Rémi Dussart, Eva Kovačević, M.F. Barthe and Pierre‐Antoine Cormier and has published in prestigious journals such as Physical Review Letters, Applied Physics Letters and Journal of Applied Physics.

In The Last Decade

Thomas Lecas

37 papers receiving 485 citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
Thomas Lecas France 16 276 213 159 82 81 38 501
Katarína Sedlačková Slovakia 14 250 0.9× 348 1.6× 104 0.7× 30 0.4× 53 0.7× 61 668
K. G. Grigorov Bulgaria 15 256 0.9× 261 1.2× 194 1.2× 19 0.2× 52 0.6× 46 594
Yuriy Kudriavtsev Mexico 12 280 1.0× 314 1.5× 64 0.4× 101 1.2× 60 0.7× 48 470
Marie‐Laure David France 17 358 1.3× 571 2.7× 60 0.4× 154 1.9× 134 1.7× 61 830
Pavel Moskovkin Belgium 14 238 0.9× 148 0.7× 157 1.0× 80 1.0× 62 0.8× 30 427
A. Gorbunov Germany 13 317 1.1× 89 0.4× 126 0.8× 53 0.6× 88 1.1× 37 527
Maurício A. Sortica Sweden 15 239 0.9× 159 0.7× 144 0.9× 159 1.9× 71 0.9× 34 455
Jenq‐Horng Liang Taiwan 14 620 2.2× 294 1.4× 68 0.4× 100 1.2× 140 1.7× 86 873
M. Zier Germany 13 121 0.4× 429 2.0× 86 0.5× 26 0.3× 86 1.1× 28 577
Rodica Vlădoiu Romania 12 258 0.9× 147 0.7× 206 1.3× 16 0.2× 86 1.1× 65 420

Countries citing papers authored by Thomas Lecas

Since Specialization
Citations

This map shows the geographic impact of Thomas Lecas'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 Thomas Lecas with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Thomas Lecas more than expected).

Fields of papers citing papers by Thomas Lecas

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Thomas Lecas. 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 Thomas Lecas. The network helps show where Thomas Lecas may publish in the future.

Co-authorship network of co-authors of Thomas Lecas

This figure shows the co-authorship network connecting the top 25 collaborators of Thomas Lecas. A scholar is included among the top collaborators of Thomas Lecas 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 Thomas Lecas. Thomas Lecas 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.
Henri, Pierre, Patrizio Dazzi, Gaëtan Wattieaux, et al.. (2023). Instrumentation for Ionized Space Environments: New High Time Resolution Instrumental Modes of Mutual Impedance Experiments. Journal of Geophysical Research Space Physics. 128(2). 1 indexed citations
2.
Thomann, Anne‐Lise, et al.. (2021). Properties of Ti-oxide thin films grown in reactive magnetron sputtering with self-heating target. Vacuum. 197. 110813–110813. 12 indexed citations
3.
Lecas, Thomas, et al.. (2020). Controlling the flux of reactive species: a case study on thin film deposition in an aniline/argon plasma. Scientific Reports. 10(1). 15913–15913. 2 indexed citations
4.
Thomann, Anne‐Lise, et al.. (2020). Hot target magnetron sputtering process: Effect of infrared radiation on the deposition of titanium and titanium oxide thin films. Vacuum. 181. 109734–109734. 23 indexed citations
5.
Kovačević, Eva, et al.. (2019). Formation and behavior of negative ions in low pressure aniline-containing RF plasmas. Scientific Reports. 9(1). 10886–10886. 6 indexed citations
6.
Kovačević, Eva, Thomas Lecas, Aurélien Canizarès, et al.. (2018). Enhancement of catalytic effect for CNT growth at low temperature by PECVD. Applied Surface Science. 453. 436–441. 15 indexed citations
7.
Lecas, Thomas, et al.. (2018). Nanoparticle growth in ethanol based plasmas. AIP conference proceedings. 1923. 20025–20025. 1 indexed citations
8.
Thomann, Anne‐Lise, Pascal Brault, Thomas Lecas, et al.. (2017). Substrate temperature and ion kinetic energy effects on first steps of He+ implantation in tungsten: Experiments and simulations. Acta Materialia. 141. 47–58. 16 indexed citations
9.
Thomann, Anne‐Lise, Amaël Caillard, Thomas Lecas, et al.. (2016). Low flux and low energy helium ion implantation into tungsten using a dedicated plasma source. Nuclear Instruments and Methods in Physics Research Section B Beam Interactions with Materials and Atoms. 383. 38–46. 5 indexed citations
10.
Mikikian, Maxime, et al.. (2016). Optical diagnostics of dusty plasmas during nanoparticle growth. Plasma Physics and Controlled Fusion. 59(1). 14034–14034. 16 indexed citations
11.
Thomann, Anne‐Lise, et al.. (2015). Sputtered Ag thin films with modified morphologies: Influence on wetting property. Applied Surface Science. 347. 101–108. 16 indexed citations
12.
Brault, Pascal, et al.. (2015). Low energy and low fluence helium implantations in tungsten: Molecular dynamics simulations and experiments. Journal of Nuclear Materials. 470. 44–54. 54 indexed citations
13.
Caillard, Amaël, Thomas Lecas, Nadjib Semmar, et al.. (2015). Membrane patterned by pulsed laser micromachining for proton exchange membrane fuel cell with sputtered ultra-low catalyst loadings. Journal of Power Sources. 298. 299–308. 36 indexed citations
14.
Canizarès, Aurélien, Mireille Gaillard, Thomas Lecas, et al.. (2014). In situ Raman spectroscopy for growth monitoring of vertically aligned multiwall carbon nanotubes in plasma reactor. Applied Physics Letters. 105(21). 16 indexed citations
15.
Lecas, Thomas, et al.. (2014). Characterization of low frequency instabilities in a Krypton dusty plasma. Plasma Sources Science and Technology. 23(6). 65009–65009. 5 indexed citations
16.
Caillard, Amaël, et al.. (2014). Energy Transferred From a Hot Nickel Target During Magnetron Sputtering. IEEE Transactions on Plasma Science. 42(10). 2802–2803. 12 indexed citations
17.
Mikikian, Maxime, et al.. (2014). Unstable Plasmoids in Dusty Plasma Experiments. IEEE Transactions on Plasma Science. 42(10). 2670–2671. 6 indexed citations
18.
Lecas, Thomas, et al.. (2014). Deposition of Pt inside fuel cell electrodes using high power impulse magnetron sputtering. Journal of Physics D Applied Physics. 47(27). 272001–272001. 17 indexed citations
19.
Cormier, Pierre‐Antoine, Anne‐Lise Thomann, V. Dolique, et al.. (2013). IR emission from the target during plasma magnetron sputter deposition. Thin Solid Films. 545. 44–49. 37 indexed citations
20.
Mikikian, Maxime, et al.. (2012). Merging and Splitting of Plasma Spheroids in a Dusty Plasma. Physical Review Letters. 109(24). 245007–245007. 11 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.

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