J. Osterholz

1.2k total citations
42 papers, 828 citations indexed

About

J. Osterholz is a scholar working on Mechanics of Materials, Nuclear and High Energy Physics and Atomic and Molecular Physics, and Optics. According to data from OpenAlex, J. Osterholz has authored 42 papers receiving a total of 828 indexed citations (citations by other indexed papers that have themselves been cited), including 26 papers in Mechanics of Materials, 21 papers in Nuclear and High Energy Physics and 12 papers in Atomic and Molecular Physics, and Optics. Recurrent topics in J. Osterholz's work include Laser-induced spectroscopy and plasma (24 papers), Laser-Plasma Interactions and Diagnostics (21 papers) and Laser Material Processing Techniques (10 papers). J. Osterholz is often cited by papers focused on Laser-induced spectroscopy and plasma (24 papers), Laser-Plasma Interactions and Diagnostics (21 papers) and Laser Material Processing Techniques (10 papers). J. Osterholz collaborates with scholars based in Germany, United Kingdom and Italy. J. Osterholz's co-authors include O. Willi, S. Kar, M. Borghesi, M. Cerchez, R. Jung, Andrea Macchi, D. Neely, G. Sarri, G. Pretzler and T. Ditmire and has published in prestigious journals such as Physical Review Letters, Scientific Reports and Geophysical Research Letters.

In The Last Decade

J. Osterholz

39 papers receiving 796 citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
J. Osterholz Germany 16 590 451 356 230 115 42 828
G. Schurtz France 19 829 1.4× 567 1.3× 393 1.1× 374 1.6× 119 1.0× 38 950
Shaoen Jiang China 14 611 1.0× 337 0.7× 349 1.0× 262 1.1× 94 0.8× 120 818
D. G. Schroen United States 16 600 1.0× 239 0.5× 276 0.8× 163 0.7× 93 0.8× 30 740
E. I. Moses United States 12 579 1.0× 310 0.7× 324 0.9× 243 1.1× 132 1.1× 30 890
F. Philippe France 15 420 0.7× 295 0.7× 242 0.7× 217 0.9× 61 0.5× 35 609
R. Wilson United Kingdom 12 531 0.9× 572 1.3× 290 0.8× 288 1.3× 69 0.6× 32 947
C. Goyon United States 17 692 1.2× 447 1.0× 400 1.1× 211 0.9× 100 0.9× 39 844
Dong Wu China 16 461 0.8× 258 0.6× 288 0.8× 157 0.7× 65 0.6× 64 625
S. Udrea Germany 14 634 1.1× 249 0.6× 333 0.9× 356 1.5× 180 1.6× 51 915
A. G. Rousskikh Russia 16 547 0.9× 359 0.8× 337 0.9× 81 0.4× 162 1.4× 80 836

Countries citing papers authored by J. Osterholz

Since Specialization
Citations

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

Fields of papers citing papers by J. Osterholz

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

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

Co-authorship network of co-authors of J. Osterholz

This figure shows the co-authorship network connecting the top 25 collaborators of J. Osterholz. A scholar is included among the top collaborators of J. Osterholz 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 J. Osterholz. J. Osterholz 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.
Reich, Stefan, et al.. (2024). Laser hardening of steel with a 120 kW laser at high throughput. Procedia CIRP. 124. 751–754. 1 indexed citations
2.
3.
Reich, Stefan, et al.. (2023). Change of dominant material properties in laser perforation process with high-energy lasers up to 120 kilowatt. Scientific Reports. 13(1). 21611–21611. 5 indexed citations
4.
Ramakrishna, B., S. Krishnamurthy, K. F. Kakolee, et al.. (2023). Probing bulk electron temperature via x-ray emission in a solid density plasma. Plasma Physics and Controlled Fusion. 65(4). 45005–45005. 1 indexed citations
5.
Reich, Stefan, et al.. (2021). Continuous wave high-power laser propagation in water is affected by strong thermal lensing and thermal blooming already at short distances. Scientific Reports. 11(1). 22619–22619. 13 indexed citations
6.
Wolfrum, Johannes, et al.. (2021). High-energy laser effects on carbon fiber reinforced polymer composites with a focus on perforation time. Journal of Composite Materials. 55(16). 2249–2262. 12 indexed citations
7.
Schmidt, Mischa, Ulf D. Kahlert, Donata Maciaczyk, et al.. (2014). Characterization of a Setup to test the Impact of High-Amplitude Pressure Waves on Living Cells. Scientific Reports. 4(1). 3849–3849. 12 indexed citations
8.
Kar, S., K. F. Kakolee, M. Cerchez, et al.. (2013). Experimental investigation of hole boring and light sail regimes of RPA by varying laser and target parameters. Plasma Physics and Controlled Fusion. 55(12). 124030–124030. 6 indexed citations
9.
Sarri, G., Andrea Macchi, C. A. Cecchetti, et al.. (2012). Dynamics of Self-Generated, Large Amplitude Magnetic Fields Following High-Intensity Laser Matter Interaction. Physical Review Letters. 109(20). 205002–205002. 56 indexed citations
10.
Romagnani, L., Alessandra Bigongiari, S. Kar, et al.. (2010). Observation of Magnetized Soliton Remnants in the Wake of Intense Laser Pulse Propagation through Plasmas. Physical Review Letters. 105(17). 175002–175002. 32 indexed citations
11.
Hidding, B., et al.. (2010). Monoenergetic Energy Doubling in a Hybrid Laser-Plasma Wakefield Accelerator. Physical Review Letters. 104(19). 195002–195002. 46 indexed citations
12.
Brandl, F., B. Hidding, J. Osterholz, et al.. (2009). Directed Acceleration of Electrons from a Solid Surface by Sub-10-fs Laser Pulses. Physical Review Letters. 102(19). 195001–195001. 13 indexed citations
13.
d’Humières, E., et al.. (2009). Guiding, Focusing, and Collimated Transport of Hot Electrons in a Canal in the Extended Tip of Cone Targets. Physical Review Letters. 102(20). 205003–205003. 17 indexed citations
14.
Osterholz, J., Martin Winter, Jürgen Winkler, et al.. (2009). Retinale Schäden durch flüssige Perfluorkarbone – eine Frage des spezifischen Gewichts? Intraokulare Druckspitzen und Scherkräfte. Klinische Monatsblätter für Augenheilkunde. 226(1). 38–47. 13 indexed citations
15.
Osterholz, J., Aaron Bernstein, G. Dyer, et al.. (2009). Characterization of two distinct, simultaneous hot electron beams in intense laser-solid interactions. Physical Review E. 80(5). 55402–55402. 16 indexed citations
16.
Osterholz, J., F. Brandl, Thomas Fischer, et al.. (2006). Production of Dense Plasmas with sub-10-fs Laser Pulses. Physical Review Letters. 96(8). 85002–85002. 21 indexed citations
17.
Jung, R., J. Osterholz, K. Löwenbrück, et al.. (2005). Study of Electron-Beam Propagation through Preionized Dense Foam Plasmas. Physical Review Letters. 94(19). 195001–195001. 54 indexed citations
18.
Willmann, Stefan, et al.. (2005). Measurement of the coagulation dynamics of bovine liver using the modified microscopic Beer–Lambert law. Lasers in Surgery and Medicine. 36(5). 365–370. 18 indexed citations
19.
Willmann, Stefan, et al.. (2003). Small-volume frequency-domain oximetry: phantom experiments and first in vivo results. Journal of Biomedical Optics. 8(4). 618–618. 5 indexed citations
20.
Willmann, Stefan, et al.. (2002). Absolute absorber quantification in turbid media at small source–detector separations. Applied Physics B. 74(6). 589–595. 6 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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