Max T. Birch

844 total citations
28 papers, 466 citations indexed

About

Max T. Birch is a scholar working on Atomic and Molecular Physics, and Optics, Condensed Matter Physics and Materials Chemistry. According to data from OpenAlex, Max T. Birch has authored 28 papers receiving a total of 466 indexed citations (citations by other indexed papers that have themselves been cited), including 21 papers in Atomic and Molecular Physics, and Optics, 13 papers in Condensed Matter Physics and 12 papers in Materials Chemistry. Recurrent topics in Max T. Birch's work include Magnetic properties of thin films (19 papers), Magnetic and transport properties of perovskites and related materials (8 papers) and 2D Materials and Applications (8 papers). Max T. Birch is often cited by papers focused on Magnetic properties of thin films (19 papers), Magnetic and transport properties of perovskites and related materials (8 papers) and 2D Materials and Applications (8 papers). Max T. Birch collaborates with scholars based in United Kingdom, Germany and Japan. Max T. Birch's co-authors include G. Balakrishnan, P. D. Hatton, Aleš Štefančič, P. D. Hatton, D. P. Halliday, Luke Turnbull, Markus Weigand, Sebastian Wintz, Kai Litzius and Gisela Schütz and has published in prestigious journals such as Nature, Physical Review Letters and Advanced Materials.

In The Last Decade

Max T. Birch

28 papers receiving 464 citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
Max T. Birch United Kingdom 12 307 209 182 148 126 28 466
Alexandra Churikova United States 3 470 1.5× 126 0.6× 283 1.6× 176 1.2× 196 1.6× 3 536
Licong Peng China 10 426 1.4× 125 0.6× 269 1.5× 302 2.0× 78 0.6× 20 579
Christopher Klose Germany 4 438 1.4× 96 0.5× 239 1.3× 151 1.0× 157 1.2× 4 476
G. Lengaigne France 10 336 1.1× 126 0.6× 121 0.7× 85 0.6× 130 1.0× 21 390
Hee‐Sung Han South Korea 9 441 1.4× 84 0.4× 184 1.0× 209 1.4× 109 0.9× 24 487
M. Zhu United States 11 366 1.2× 167 0.8× 137 0.8× 125 0.8× 158 1.3× 26 484
Procopios Constantinou Switzerland 8 216 0.7× 108 0.5× 142 0.8× 128 0.9× 90 0.7× 19 354
Wenxin Tang China 9 334 1.1× 117 0.6× 167 0.9× 200 1.4× 91 0.7× 20 462
Sergii Parchenko Switzerland 12 169 0.6× 108 0.5× 119 0.7× 99 0.7× 131 1.0× 27 317
Mehran Vafaee Germany 12 199 0.6× 186 0.9× 250 1.4× 156 1.1× 118 0.9× 20 437

Countries citing papers authored by Max T. Birch

Since Specialization
Citations

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

Fields of papers citing papers by Max T. Birch

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

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

Co-authorship network of co-authors of Max T. Birch

This figure shows the co-authorship network connecting the top 25 collaborators of Max T. Birch. A scholar is included among the top collaborators of Max T. Birch 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 Max T. Birch. Max T. Birch 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.
Gomilšek, M., M. N. Wilson, Kévin J. A. Franke, et al.. (2025). Anisotropic Skyrmion and Multi-q Spin Dynamics in Centrosymmetric Gd2PdSi3. Physical Review Letters. 134(4). 46702–46702. 3 indexed citations
2.
Sun, Yuhan, Max T. Birch, Simone Finizio, et al.. (2025). Localized Spin Textures Stabilized by Geometry‐Induced Strain in 2D Magnet Fe 3 GeTe 2. Advanced Materials. 37(37). e2506279–e2506279. 1 indexed citations
3.
Fujishiro, Yukako, Satoru Hayami, Max T. Birch, et al.. (2025). Incommensurate broken helix induced by nonstoichiometry in the axion insulator candidate EuIn2As2. Physical review. B.. 111(8). 3 indexed citations
4.
Birch, Max T., Kai Litzius, Ondřej Hovorka, et al.. (2024). Control of stripe, skyrmion and skyrmionium formation in the 2D magnet Fe3−xGeTe2 by varying composition. 2D Materials. 11(2). 25008–25008. 3 indexed citations
5.
Birch, Max T., Fehmi Sami Yasin, Kai Litzius, et al.. (2024). Influence of Magnetic Sublattice Ordering on Skyrmion Bubble Stability in 2D Magnet Fe5GeTe2. ACS Nano. 18(28). 18246–18256. 4 indexed citations
6.
Birch, Max T., Ilya Belopolski, Yukako Fujishiro, et al.. (2024). Dynamic transition and Galilean relativity of current-driven skyrmions. Nature. 633(8030). 554–559. 6 indexed citations
7.
Birch, Max T., Kai Litzius, Sebastian Wintz, et al.. (2023). Seeding and Emergence of Composite Skyrmions in a van der Waals Magnet. Advanced Materials. 35(12). 31 indexed citations
8.
Birch, Max T., Kai Litzius, Sebastian Wintz, et al.. (2023). Skyrmion and skyrmionium formation in the two-dimensional magnet Cr2Ge2Te6. Physical review. B.. 108(21). 13 indexed citations
9.
Litzius, Kai, Max T. Birch, R. A. Gallardo, et al.. (2023). Direct Observation of Propagating Spin Waves in the 2D van der Waals Ferromagnet Fe5GeTe2. Nano Letters. 23(22). 10126–10131. 7 indexed citations
10.
Turnbull, Luke, M. N. Wilson, Max T. Birch, et al.. (2022). Enhanced skyrmion metastability under applied strain in FeGe. Physical review. B.. 106(21). 3 indexed citations
11.
Birch, Max T., Sebastian Wintz, Ondřej Hovorka, et al.. (2022). History-dependent domain and skyrmion formation in 2D van der Waals magnet Fe3GeTe2. Nature Communications. 13(1). 3035–3035. 74 indexed citations
12.
Birch, Max T., Kai Litzius, Sebastian Wintz, et al.. (2022). Single Skyrmion Generation via a Vertical Nanocontact in a 2D Magnet-Based Heterostructure. Nano Letters. 22(23). 9236–9243. 4 indexed citations
13.
Birch, Max T., David Cortés‐Ortuño, Kai Litzius, et al.. (2022). Toggle-like current-induced Bloch point dynamics of 3D skyrmion strings in a room temperature nanowire. Nature Communications. 13(1). 3630–3630. 15 indexed citations
14.
Twitchett-Harrison, A. C., J. C. Loudon, Max T. Birch, et al.. (2022). Confinement of Skyrmions in Nanoscale FeGe Device-like Structures. ACS Applied Electronic Materials. 4(9). 4427–4437. 5 indexed citations
15.
Birch, Max T., David Cortés‐Ortuño, N. D. Khanh, et al.. (2021). Topological defect-mediated skyrmion annihilation in three dimensions. Communications Physics. 4(1). 25 indexed citations
16.
Birch, Max T., M. N. Wilson, Aleš Štefančič, et al.. (2020). Position-dependent stability and lifetime of the skyrmion state in nickel-substituted Cu2OSeO3. Physical review. B.. 102(22). 4 indexed citations
17.
Turnbull, Luke, Max T. Birch, Angus Laurenson, et al.. (2020). Tilted X-Ray Holography of Magnetic Bubbles in MnNiGa Lamellae. ACS Nano. 15(1). 387–395. 17 indexed citations
18.
Franke, Kévin J. A., Monica Ciomaga Hatnean, Max T. Birch, et al.. (2019). Investigating the magnetic ground state of the skyrmion host material Cu2OSeO3 using long-wavelength neutron diffraction. Science and Technology Facilities Council. 2 indexed citations
19.
Loudon, J. C., A. C. Twitchett-Harrison, David Cortés‐Ortuño, et al.. (2019). Do Images of Biskyrmions Show Type‐II Bubbles?. Advanced Materials. 31(16). e1806598–e1806598. 75 indexed citations
20.
Birch, Max T., R. Takagi, S. Seki, et al.. (2019). Increased lifetime of metastable skyrmions by controlled doping. Physical review. B.. 100(1). 32 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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