Michael W. Czabaj

1.2k total citations
58 papers, 835 citations indexed

About

Michael W. Czabaj is a scholar working on Mechanics of Materials, Mechanical Engineering and Materials Chemistry. According to data from OpenAlex, Michael W. Czabaj has authored 58 papers receiving a total of 835 indexed citations (citations by other indexed papers that have themselves been cited), including 36 papers in Mechanics of Materials, 30 papers in Mechanical Engineering and 9 papers in Materials Chemistry. Recurrent topics in Michael W. Czabaj's work include Mechanical Behavior of Composites (30 papers), Fatigue and fracture mechanics (12 papers) and Ultrasonics and Acoustic Wave Propagation (9 papers). Michael W. Czabaj is often cited by papers focused on Mechanical Behavior of Composites (30 papers), Fatigue and fracture mechanics (12 papers) and Ultrasonics and Acoustic Wave Propagation (9 papers). Michael W. Czabaj collaborates with scholars based in United States, Sweden and Denmark. Michael W. Czabaj's co-authors include James G. Ratcliffe, William Whitacre, Mark L. Riccio, Barry D. Davidson, Alan T. Zehnder, T Kevin O'Brien, John Fisher, Emilie J. Siochi, Godfrey Sauti and Roberto J. Cano and has published in prestigious journals such as Acta Materialia, Carbon and Materials Science and Engineering A.

In The Last Decade

Michael W. Czabaj

58 papers receiving 825 citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
Michael W. Czabaj United States 16 499 299 151 146 125 58 835
Markus Stommel Germany 16 360 0.7× 328 1.1× 150 1.0× 67 0.5× 207 1.7× 98 847
Garth Pearce Australia 17 430 0.9× 360 1.2× 223 1.5× 133 0.9× 103 0.8× 60 1.1k
Arun Dev Dhar Dwivedi India 16 358 0.7× 386 1.3× 144 1.0× 288 2.0× 108 0.9× 69 1.2k
L. Roy Xu United States 20 708 1.4× 372 1.2× 277 1.8× 86 0.6× 181 1.4× 54 1.1k
S. C. Garcea United Kingdom 9 569 1.1× 381 1.3× 105 0.7× 51 0.3× 97 0.8× 16 877
Yutong Fu China 14 287 0.6× 246 0.8× 41 0.3× 169 1.2× 108 0.9× 57 657
Matthew Blacklock United Kingdom 12 451 0.9× 205 0.7× 73 0.5× 51 0.3× 160 1.3× 22 643
Steven Le Corre France 16 624 1.3× 599 2.0× 120 0.8× 99 0.7× 112 0.9× 58 1.0k
A.R. Chambers United Kingdom 17 435 0.9× 470 1.6× 189 1.3× 49 0.3× 150 1.2× 44 958
F. Roger France 17 276 0.6× 557 1.9× 105 0.7× 157 1.1× 93 0.7× 29 879

Countries citing papers authored by Michael W. Czabaj

Since Specialization
Citations

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

Fields of papers citing papers by Michael W. Czabaj

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Michael W. Czabaj. 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 Michael W. Czabaj. The network helps show where Michael W. Czabaj may publish in the future.

Co-authorship network of co-authors of Michael W. Czabaj

This figure shows the co-authorship network connecting the top 25 collaborators of Michael W. Czabaj. A scholar is included among the top collaborators of Michael W. Czabaj 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 Michael W. Czabaj. Michael W. Czabaj 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.
Jolowsky, Claire, et al.. (2024). Characterization of multidirectional carbon-nanotube-yarn/bismaleimide laminates under tensile loading. Composites Part B Engineering. 280. 111465–111465. 3 indexed citations
2.
Dávila, Carlos G., et al.. (2024). Propagation rate transients in J-controlled fatigue characterization of adhesives. International Journal of Fatigue. 185. 108377–108377. 2 indexed citations
3.
Jolowsky, Claire, et al.. (2024). Scaled-Up Continuous Carbon Nanotube Yarn Unidirectional Composite Laminates With Carbon Nanotube Aerogel. Digital Commons - Michigan Tech (Michigan Technological University). 1 indexed citations
4.
Park, Jin Gyu, Claire Jolowsky, Michael W. Czabaj, et al.. (2023). Gamma-ray irradiation to achieve high tensile performance of unidirectional CNT yarn laminates. Carbon. 216. 118530–118530. 11 indexed citations
5.
Jolowsky, Claire, et al.. (2023). Scalable High Tensile Modulus Composite Laminates Using Continuous Carbon Nanotube Yarns for Aerospace Applications. ACS Applied Nano Materials. 6(13). 11260–11268. 20 indexed citations
6.
Czabaj, Michael W., et al.. (2023). Machine learning guided design of experiments to accelerate exploration of a material extrusion process parameter space. Journal of Intelligent Manufacturing. 36(1). 491–508. 2 indexed citations
7.
8.
Czabaj, Michael W., et al.. (2022). In-situ imaging of advanced materials subjected to in-plane biaxial loading using X-ray micro-computed tomography. Composites Science and Technology. 224. 109453–109453. 14 indexed citations
9.
Fisher, John, et al.. (2020). 4D Imaging of ceramic matrix composites during polymer infiltration and pyrolysis. Acta Materialia. 201. 547–560. 21 indexed citations
10.
Carvalho, N.V. De, Michael W. Czabaj, & James G. Ratcliffe. (2020). Piecewise-linear generalizable cohesive element approach for simulating mixed-mode delamination. Engineering Fracture Mechanics. 242. 107484–107484. 8 indexed citations
11.
Carvalho, N.V. De, et al.. (2020). Experimental reexamination of transverse tensile strength for IM7/8552 tape-laminate composites. Journal of Composite Materials. 54(23). 3297–3312. 7 indexed citations
12.
Czabaj, Michael W., et al.. (2018). Interlayer fracture toughness of additively manufactured unreinforced and carbon-fiber-reinforced acrylonitrile butadiene styrene. Additive manufacturing. 22. 883–890. 29 indexed citations
13.
Barnard, Harold, Alastair A. MacDowell, Dilworth Y. Parkinson, et al.. (2017). Synchrotron X-ray micro-tomography at the Advanced Light Source: Developments in high-temperature in-situ mechanical testing. Journal of Physics Conference Series. 849. 12043–12043. 11 indexed citations
14.
15.
Czabaj, Michael W., Barry D. Davidson, & James G. Ratcliffe. (2016). A Modified Edge Crack Torsion Test for Measurement of Mode III Fracture Toughness of Laminated Tape Composites. 2 indexed citations
16.
Czabaj, Michael W., et al.. (2016). Development of a novel in-plane Tension-tension biaxial cruciform specimen. 1 indexed citations
17.
Leone, Frank A., et al.. (2015). Simulation of delamination–migration and core crushing in a CFRP sandwich structure. Composites Part A Applied Science and Manufacturing. 79. 192–202. 20 indexed citations
18.
Czabaj, Michael W., Mark L. Riccio, & William Whitacre. (2014). Three-Dimensional Imaging and Numerical Reconstruction of Graphite/Epoxy Composite Microstructure Based on Ultra-High Resolution X-Ray Computed Tomography. NASA STI Repository (National Aeronautics and Space Administration). 2 indexed citations
19.
Czabaj, Michael W. & James G. Ratcliffe. (2012). Comparison of Intralaminar and Interlaminar Mode-I Fracture Toughness of Unidirectional IM7/8552 Graphite/Epoxy Composite. NASA STI Repository (National Aeronautics and Space Administration). 102–119. 15 indexed citations
20.
Davidson, Barry D., et al.. (2012). Damage characterization of quasi-statically indented composite sandwich structures. Journal of Composite Materials. 47(10). 1211–1229. 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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