T. M. Davison

3.3k total citations
88 papers, 2.0k citations indexed

About

T. M. Davison is a scholar working on Astronomy and Astrophysics, Geophysics and Aerospace Engineering. According to data from OpenAlex, T. M. Davison has authored 88 papers receiving a total of 2.0k indexed citations (citations by other indexed papers that have themselves been cited), including 62 papers in Astronomy and Astrophysics, 24 papers in Geophysics and 14 papers in Aerospace Engineering. Recurrent topics in T. M. Davison's work include Astro and Planetary Science (61 papers), Planetary Science and Exploration (58 papers) and High-pressure geophysics and materials (18 papers). T. M. Davison is often cited by papers focused on Astro and Planetary Science (61 papers), Planetary Science and Exploration (58 papers) and High-pressure geophysics and materials (18 papers). T. M. Davison collaborates with scholars based in United Kingdom, United States and Australia. T. M. Davison's co-authors include G. S. Collins, F. J. Ciesla, D. Elbeshausen, P. A. Bland, J. L. Black, K. Wünnemann, Y. Au, V. V. Kruglyak, E. Ahmad and Sabina D. Raducan and has published in prestigious journals such as Physical Review Letters, Nature Communications and Applied Physics Letters.

In The Last Decade

T. M. Davison

86 papers receiving 1.9k citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
T. M. Davison United Kingdom 27 1.2k 507 312 242 209 88 2.0k
R. M. Jones United States 18 321 0.3× 158 0.3× 172 0.6× 346 1.4× 224 1.1× 96 1.6k
M. J. Taylor United States 22 943 0.8× 171 0.3× 555 1.8× 79 0.3× 21 0.1× 63 1.4k
Tomoaki Kubo Japan 30 360 0.3× 2.0k 4.0× 63 0.2× 55 0.2× 26 0.1× 97 3.4k
János Lichtenberger Hungary 20 807 0.7× 477 0.9× 158 0.5× 45 0.2× 307 1.5× 76 1.4k
G. Pérès Italy 33 3.0k 2.5× 105 0.2× 61 0.2× 15 0.1× 106 0.5× 192 3.5k
B. E. Clark United States 36 3.1k 2.6× 683 1.3× 521 1.7× 48 0.2× 917 4.4× 125 3.3k
W. Allan Canada 31 1.9k 1.6× 787 1.6× 499 1.6× 17 0.1× 38 0.2× 138 3.1k
William H. Beasley United States 29 2.0k 1.7× 256 0.5× 260 0.8× 9 0.0× 200 1.0× 86 2.9k
D. C. Thompson United States 24 970 0.8× 377 0.7× 148 0.5× 5 0.0× 311 1.5× 86 1.7k
J. Morton United States 24 154 0.1× 34 0.1× 612 2.0× 29 0.1× 121 0.6× 46 1.7k

Countries citing papers authored by T. M. Davison

Since Specialization
Citations

This map shows the geographic impact of T. M. Davison'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 T. M. Davison with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites T. M. Davison more than expected).

Fields of papers citing papers by T. M. Davison

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by T. M. Davison. 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 T. M. Davison. The network helps show where T. M. Davison may publish in the future.

Co-authorship network of co-authors of T. M. Davison

This figure shows the co-authorship network connecting the top 25 collaborators of T. M. Davison. A scholar is included among the top collaborators of T. M. Davison 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 T. M. Davison. T. M. Davison 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.
Kurosawa, Kosuke, et al.. (2025). Impact-driven oxidation of organics explains chondrite shock metamorphism dichotomy. Nature Communications. 16(1). 3608–3608.
2.
DeCoster, Mallory E., R. Luther, G. S. Collins, et al.. (2024). The Relative Effects of Surface and Subsurface Morphology on the Deflection Efficiency of Kinetic Impactors: Implications for the DART Mission. The Planetary Science Journal. 5(1). 21–21. 5 indexed citations
3.
Rae, Auriol S. P., et al.. (2024). The Distribution of Impactor Core Material During Large Impacts on Earth-like Planets. The Planetary Science Journal. 5(4). 90–90. 3 indexed citations
4.
Muxworthy, Adrian R., et al.. (2024). The Effect of Stress on Paleomagnetic Signals: A Micromagnetic Study of Magnetite's Single‐Vortex Response. Geophysical Research Letters. 51(2). 1 indexed citations
5.
Zhu, Meng‐Hua, et al.. (2024). Impact Momentum Transfer—Insights from Numerical Simulation of Impacts on Large Boulders of Asteroids. The Planetary Science Journal. 5(9). 214–214. 2 indexed citations
6.
Luther, R., Sabina D. Raducan, K. Wünnemann, et al.. (2022). Momentum Enhancement during Kinetic Impacts in the Low-intermediate-strength Regime: Benchmarking and Validation of Impact Shock Physics Codes. The Planetary Science Journal. 3(10). 227–227. 9 indexed citations
7.
Davison, T. M. & G. S. Collins. (2022). Complex Crater Formation by Oblique Impacts on the Earth and Moon. Geophysical Research Letters. 49(21). 12 indexed citations
8.
Wakita, Shigeru, et al.. (2021). Jetting during oblique impacts of spherical impactors. Icarus. 360. 114365–114365. 17 indexed citations
9.
Harrison, Matthew Tom, Brendan Cullen, Dianne Mayberry, et al.. (2021). Carbon myopia: The urgent need for integrated social, economic and environmental action in the livestock sector. Global Change Biology. 27(22). 5726–5761. 108 indexed citations
10.
Wakita, Shigeru, et al.. (2021). Impactor material records the ancient lunar magnetic field in antipodal anomalies. Nature Communications. 12(1). 6543–6543. 13 indexed citations
11.
Lyons, Richard, T. J. Bowling, F. J. Ciesla, T. M. Davison, & G. S. Collins. (2019). The effects of impacts on the cooling rates of iron meteorites. Meteoritics and Planetary Science. 54(7). 1604–1618. 6 indexed citations
12.
Raducan, Sabina D., T. M. Davison, R. Luther, & G. S. Collins. (2019). The role of asteroid strength, porosity and internal friction in impact momentum transfer. Icarus. 329. 282–295. 55 indexed citations
13.
Rae, Auriol S. P., G. S. Collins, M. H. Poelchau, et al.. (2019). Stress‐Strain Evolution During Peak‐Ring Formation: A Case Study of the Chicxulub Impact Structure. Journal of Geophysical Research Planets. 124(2). 396–417. 35 indexed citations
14.
Bowling, T. J., F. J. Ciesla, T. M. Davison, et al.. (2018). Post-impact thermal structure and cooling timescales of Occator crater on asteroid 1 Ceres. Icarus. 320. 110–118. 40 indexed citations
15.
Chapman, David J., T. M. Davison, J. Piroto Duarte, et al.. (2018). Investigating shock processes in bimodal powder compaction through modelling and experiment at the mesoscale. International Journal of Solids and Structures. 163. 211–219. 2 indexed citations
16.
Davison, T. M., et al.. (2018). Mesoscale simulations of shock compaction of a granular ceramic: effects of mesostructure and mixed-cell strength treatment. Modelling and Simulation in Materials Science and Engineering. 26(3). 35009–35009. 4 indexed citations
17.
Hirabayashi, Motohiro, C. I. Fassett, David A. Minton, et al.. (2018). Topographic Diffusion as a Cause of Variations in Crater Density on Ceres. Lunar and Planetary Science Conference. 2091. 1 indexed citations
18.
Collins, G. S., et al.. (2017). A numerical assessment of simple airblast models of impact airbursts. Meteoritics and Planetary Science. 52(8). 1542–1560. 31 indexed citations
19.
Davison, T. M., G. S. Collins, & P. A. Bland. (2016). MESOSCALE MODELING OF IMPACT COMPACTION OF PRIMITIVE SOLAR SYSTEM SOLIDS. The Astrophysical Journal. 821(1). 68–68. 38 indexed citations
20.
Collins, G. S., T. M. Davison, D. Elbeshausen, & K. Wünnemann. (2009). Numerical Simulations of Oblique Impacts: The Effect of Impact Angle and Target Strength on Crater Shape. LPI. 1620. 4 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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