Aaron Bostwick

22.8k total citations · 9 hit papers
192 papers, 15.8k citations indexed

About

Aaron Bostwick is a scholar working on Materials Chemistry, Atomic and Molecular Physics, and Optics and Electronic, Optical and Magnetic Materials. According to data from OpenAlex, Aaron Bostwick has authored 192 papers receiving a total of 15.8k indexed citations (citations by other indexed papers that have themselves been cited), including 150 papers in Materials Chemistry, 92 papers in Atomic and Molecular Physics, and Optics and 51 papers in Electronic, Optical and Magnetic Materials. Recurrent topics in Aaron Bostwick's work include Graphene research and applications (68 papers), 2D Materials and Applications (50 papers) and Topological Materials and Phenomena (47 papers). Aaron Bostwick is often cited by papers focused on Graphene research and applications (68 papers), 2D Materials and Applications (50 papers) and Topological Materials and Phenomena (47 papers). Aaron Bostwick collaborates with scholars based in United States, Germany and South Korea. Aaron Bostwick's co-authors include Eli Rotenberg, Thomas Seyller, K. Horn, Taisuke Ohta, J. L. McChesney, K. V. Emtsev, Luca Moreschini, Chris Jozwiak, Andreas K. Schmid and L. Ley and has published in prestigious journals such as Nature, Science and Journal of the American Chemical Society.

In The Last Decade

Aaron Bostwick

184 papers receiving 15.5k citations

Hit Papers

Controlling the Electronic Structure of Bilayer Graphene 2006 2026 2012 2019 2006 2009 2006 2018 2007 500 1000 1.5k 2.0k 2.5k
What are hit papers?

Hit papers significantly outperform the citation benchmark for their cohort. A paper qualifies if it has ≥500 total citations, achieves ≥1.5× the top-1% citation threshold for papers in the same subfield and year (this is the minimum needed to enter the top 1%, not the average within it), or reaches the top citation threshold in at least one of its specific research topics.

  1. Controlling the Electronic Structure of Bilayer Graphene
    2006 2.7k citations Aaron Bostwick, Eli Rotenberg et al. profile →
  2. Towards wafer-size graphene layers by atmospheric pressure graphitization of silicon carbide
    2009 2.1k citations Aaron Bostwick, J. L. McChesney et al. Nature Materials profile →
  3. Quasiparticle dynamics in graphene
    2006 908 citations Aaron Bostwick, Eli Rotenberg et al. Nature Physics profile →
  4. Massive Dirac fermions in a ferromagnetic kagome metal
    2018 652 citations Linda Ye, Mingu Kang et al. profile →
  5. Interlayer Interaction and Electronic Screening in Multilayer Graphene Investigated with Angle-Resolved Photoemission Spectroscopy
    2007 601 citations Aaron Bostwick, J. L. McChesney et al. Physical Review Letters profile →
  6. Friction and Dissipation in Epitaxial Graphene Films
    2009 480 citations J. L. McChesney, Aaron Bostwick et al. Physical Review Letters profile →
  7. Giant Faraday rotation in single- and multilayer graphene
    2010 475 citations Aaron Bostwick, Eli Rotenberg et al. Nature Physics profile →
  8. Twofold van Hove singularity and origin of charge order in topological kagome superconductor CsV3Sb5
    2022 251 citations Mingu Kang, Shiang Fang et al. Nature Physics profile →
  9. Magnetism and charge density wave order in kagome FeGe
    2023 105 citations Xiaokun Teng, Ji Seop Oh et al. Nature Physics profile →

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
Aaron Bostwick United States 51 12.4k 6.7k 4.6k 2.8k 2.6k 192 15.8k
Cory R. Dean United States 56 17.6k 1.4× 8.9k 1.3× 6.2k 1.3× 2.5k 0.9× 1.7k 0.7× 143 21.4k
Oleg V. Yazyev Switzerland 49 13.0k 1.0× 5.9k 0.9× 5.0k 1.1× 1.8k 0.6× 1.5k 0.6× 169 15.3k
Yugui Yao China 68 16.1k 1.3× 12.8k 1.9× 4.0k 0.9× 3.1k 1.1× 4.0k 1.5× 315 21.3k
Emanuel Tutuc United States 53 16.2k 1.3× 6.7k 1.0× 8.9k 1.9× 2.7k 0.9× 1.5k 0.6× 190 21.2k
Shiang Fang United States 30 9.8k 0.8× 6.7k 1.0× 2.7k 0.6× 1.8k 0.6× 2.5k 0.9× 64 13.0k
Zhenyu Zhang China 58 7.6k 0.6× 3.9k 0.6× 4.1k 0.9× 2.7k 1.0× 1.4k 0.5× 309 11.4k
Walter R. L. Lambrecht United States 57 8.9k 0.7× 3.2k 0.5× 5.5k 1.2× 3.5k 1.3× 3.6k 1.4× 293 13.2k
Evgeny Y. Tsymbal United States 77 12.5k 1.0× 6.1k 0.9× 6.1k 1.3× 9.8k 3.5× 3.9k 1.5× 325 18.7k
Qi‐Kun Xue China 59 7.9k 0.6× 7.2k 1.1× 3.3k 0.7× 4.3k 1.5× 4.6k 1.8× 309 14.0k
K. Horn Germany 51 11.0k 0.9× 7.9k 1.2× 5.1k 1.1× 1.3k 0.5× 782 0.3× 244 14.9k

Countries citing papers authored by Aaron Bostwick

Since Specialization
Citations

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

Fields of papers citing papers by Aaron Bostwick

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

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

Co-authorship network of co-authors of Aaron Bostwick

This figure shows the co-authorship network connecting the top 25 collaborators of Aaron Bostwick. A scholar is included among the top collaborators of Aaron Bostwick 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 Aaron Bostwick. Aaron Bostwick 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.
Lain, Michael, et al.. (2025). Graphite Development From a Manufacturers Perspective: Processing, Formation, and Benchmarking. SHILAP Revista de lepidopterología. 4(4).
2.
Wen, Ming, Qiuyang Li, Wenhao Liu, et al.. (2025). Large exciton binding energy in a bulk van der Waals magnet from quasi-1D electronic localization. Nature Communications. 16(1). 1134–1134. 11 indexed citations
3.
Lâm, Nguyễn Hữu, Jinwoong Hwang, Aaron Bostwick, et al.. (2024). Emergence of two distinct phase transitions in monolayer CoSe2 on graphene. Nano Convergence. 11(1). 21–21. 1 indexed citations
4.
Ulstrup, Søren, Jill A. Miwa, Kathleen M. McCreary, et al.. (2024). Observation of interlayer plasmon polaron in graphene/WS2 heterostructures. Nature Communications. 15(1). 3845–3845. 10 indexed citations
5.
Lin, Yi, Giovanni Marini, Luca Moreschini, et al.. (2024). Ultrafast creation of a light-induced semimetallic state in strongly excited 1T-TiSe 2. Science Advances. 10(19). eadl4481–eadl4481. 7 indexed citations
6.
Kang, Mingu, Yuting Qian, Paul M. Neves, et al.. (2024). Measurements of the quantum geometric tensor in solids. Nature Physics. 21(1). 110–117. 22 indexed citations
7.
Jo, Na Hyun, Chris Jozwiak, Aaron Bostwick, et al.. (2023). Synthesis and physical properties of a new layered ferromagnet Cr1.21Te2. Physical Review Materials. 7(4). 8 indexed citations
8.
Wang, Ke, Fabio Boschini, Marta Zonno, et al.. (2023). Symmetry-enforced Fermi degeneracy in topological semimetal RhSb3. Physical Review Materials. 7(7).
9.
Teng, Xiaokun, Ji Seop Oh, Hengxin Tan, et al.. (2023). Magnetism and charge density wave order in kagome FeGe. Nature Physics. 19(6). 814–822. 105 indexed citations breakdown →
10.
Xie, Lilia S., Matteo Michiardi, Sergey Gorovikov, et al.. (2023). Comparative Electronic Structures of the Chiral Helimagnets Cr1/3NbS2 and Cr1/3TaS2. Chemistry of Materials. 35(17). 7239–7251. 9 indexed citations
11.
Utama, M. Iqbal Bakti, Jonathan D. Denlinger, C. G. Fatuzzo, et al.. (2022). Correlation-driven electron-hole asymmetry in graphene field effect devices. npj Quantum Materials. 7(1). 12 indexed citations
12.
Kang, Mingu, Shiang Fang, Jonggyu Yoo, et al.. (2022). Charge order landscape and competition with superconductivity in kagome metals. Nature Materials. 22(2). 186–193. 64 indexed citations
13.
Biswas, Deepnarayan, Davide Curcio, Nicola Lanatà, et al.. (2021). Visualizing band structure hybridization and superlattice effects in twisted MoS 2 /WS 2 heterobilayers. 2D Materials. 9(1). 15032–15032. 12 indexed citations
14.
Wong, Joeson, Artur R. Davoyan, Bolin Liao, et al.. (2021). Spatiotemporal Imaging of Thickness-Induced Band-Bending Junctions. Nano Letters. 21(13). 5745–5753. 11 indexed citations
15.
Kastl, Christoph, Roland J. Koch, Christopher T. Chen, et al.. (2019). Effects of Defects on Band Structure and Excitons in WS2 Revealed by Nanoscale Photoemission Spectroscopy. ACS Nano. 13(2). 1284–1291. 64 indexed citations
16.
Waldecker, Lutz, Archana Raja, Malte Rösner, et al.. (2019). Rigid Band Shifts in Two-Dimensional Semiconductors through External Dielectric Screening. Physical Review Letters. 123(20). 206403–206403. 74 indexed citations
17.
Kuo, Cheng‐Tai, G. Ghiringhelli, Ping Yang, et al.. (2017). Determining the depth distribution of RIXS excitations through standing-wave excitation. Bulletin of the American Physical Society. 2017. 1 indexed citations
18.
Barfuss, Arne, M. R. Scholz, C. Blumenstein, et al.. (2013). 調節できるFermi準位を持つ元素トポロジカル絶縁体:InSb(001)上の歪があるα-Sn. Physical Review Letters. 111(15). 1–157205. 13 indexed citations
19.
Jeon, Ki‐Joon, Zonghoon Lee, Elad Pollak, et al.. (2011). Fluorographene: A Wide Bandgap Semiconductor with Ultraviolet Luminescence. ACS Nano. 5(2). 1042–1046. 382 indexed citations
20.
Döbrich, K. M., Aaron Bostwick, J. L. McChesney, et al.. (2010). Fermi-Surface Topology and Helical Antiferromagnetism in Heavy Lanthanide Metals. Physical Review Letters. 104(24). 246401–246401. 26 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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