S. E. de Graaf

794 total citations
38 papers, 533 citations indexed

About

S. E. de Graaf is a scholar working on Atomic and Molecular Physics, and Optics, Electrical and Electronic Engineering and Condensed Matter Physics. According to data from OpenAlex, S. E. de Graaf has authored 38 papers receiving a total of 533 indexed citations (citations by other indexed papers that have themselves been cited), including 28 papers in Atomic and Molecular Physics, and Optics, 16 papers in Electrical and Electronic Engineering and 13 papers in Condensed Matter Physics. Recurrent topics in S. E. de Graaf's work include Quantum and electron transport phenomena (15 papers), Physics of Superconductivity and Magnetism (13 papers) and Microwave and Dielectric Measurement Techniques (7 papers). S. E. de Graaf is often cited by papers focused on Quantum and electron transport phenomena (15 papers), Physics of Superconductivity and Magnetism (13 papers) and Microwave and Dielectric Measurement Techniques (7 papers). S. E. de Graaf collaborates with scholars based in United Kingdom, Sweden and Russia. S. E. de Graaf's co-authors include Sergey Kubatkin, Andrey Danilov, T. Lindström, O. V. Astafiev, J. S. Tsai, Zhihui Peng, Alexander Tzalenchuk, R. Shaikhaidarov, Nick Ridler and Thilo Bauch and has published in prestigious journals such as Physical Review Letters, Nature Communications and Applied Physics Letters.

In The Last Decade

S. E. de Graaf

35 papers receiving 524 citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
S. E. de Graaf United Kingdom 13 367 171 165 129 74 38 533
S. Wünsch Germany 13 355 1.0× 166 1.0× 126 0.8× 143 1.1× 40 0.5× 22 484
W. E. Shanks United States 10 577 1.6× 197 1.2× 193 1.2× 70 0.5× 83 1.1× 13 661
Shlomi Matityahu Israel 10 272 0.7× 140 0.8× 79 0.5× 54 0.4× 68 0.9× 17 344
Daniel Bothner Germany 13 404 1.1× 99 0.6× 147 0.9× 205 1.6× 35 0.5× 31 509
Kyle Serniak United States 13 496 1.4× 66 0.4× 306 1.9× 162 1.3× 58 0.8× 25 659
K. Inderbitzin Switzerland 7 281 0.8× 229 1.3× 56 0.3× 68 0.5× 111 1.5× 7 405
Xianjing Zhou China 10 279 0.8× 220 1.3× 49 0.3× 263 2.0× 220 3.0× 28 611
Orlando Quaranta United States 10 148 0.4× 103 0.6× 64 0.4× 127 1.0× 67 0.9× 33 351
Hiroyuki Shibata Japan 10 139 0.4× 151 0.9× 73 0.4× 118 0.9× 45 0.6× 31 401
T. Kutsuwa Japan 8 408 1.1× 294 1.7× 122 0.7× 42 0.3× 100 1.4× 20 563

Countries citing papers authored by S. E. de Graaf

Since Specialization
Citations

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

Fields of papers citing papers by S. E. de Graaf

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by S. E. de Graaf. 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 S. E. de Graaf. The network helps show where S. E. de Graaf may publish in the future.

Co-authorship network of co-authors of S. E. de Graaf

This figure shows the co-authorship network connecting the top 25 collaborators of S. E. de Graaf. A scholar is included among the top collaborators of S. E. de Graaf 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 S. E. de Graaf. S. E. de Graaf 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.
Barker, Thomas H., et al.. (2025). In situ scanning gate imaging of individual quantum two-level system defects in live superconducting circuits. Science Advances. 11(18). eadt8586–eadt8586.
2.
Graaf, S. E. de, et al.. (2024). Scaling of self-stimulated spin echoes. Applied Physics Letters. 124(2).
3.
Shang, Xiaobang, et al.. (2024). RF and microwave metrology for quantum computing – recent developments at the UK’s National Physical Laboratory. International Journal of Microwave and Wireless Technologies. 16(4). 535–543. 2 indexed citations
4.
Danilov, Andrey, L. V. Levitin, A. Casey, et al.. (2023). Quantum bath suppression in a superconducting circuit by immersion cooling. Nature Communications. 14(1). 3522–3522. 12 indexed citations
5.
6.
Ranjan, V., Yutian Wen, Sergey Kubatkin, et al.. (2022). Spin-Echo Silencing Using a Current-Biased Frequency-Tunable Resonator. Physical Review Letters. 129(18). 180504–180504. 9 indexed citations
7.
Graaf, S. E. de, Sun Un, Alexander G. Shard, & T. Lindström. (2022). Chemical and structural identification of material defects in superconducting quantum circuits. 2(3). 32001–32001. 13 indexed citations
8.
Un, Sun, S. E. de Graaf, Patrice Bertet, Sergey Kubatkin, & Andrey Danilov. (2022). On the nature of decoherence in quantum circuits: Revealing the structural motif of the surface radicals in α-Al2O3. Science Advances. 8(14). eabm6169–eabm6169. 7 indexed citations
9.
Graaf, S. E. de, et al.. (2021). Quantifying dynamics and interactions of individual spurious low-energy fluctuators in superconducting circuits. Physical review. B.. 103(17). 9 indexed citations
10.
Lehtinen, J. S., Alberto Ronzani, R. Shaikhaidarov, et al.. (2020). Enhancement of Superconductivity by Amorphizing Molybdenum Silicide Films Using a Focused Ion Beam. Nanomaterials. 10(5). 950–950. 6 indexed citations
11.
Burnett, Jonathan, Sergey Kubatkin, Andrey Danilov, et al.. (2020). Pulsed electron spin resonance of an organic microcrystal by dispersive readout. Journal of Magnetic Resonance. 321. 106853–106853. 3 indexed citations
12.
Graaf, S. E. de. (2020). Dual Fraunhofer interference and charge fluctuations in long quantum phase slip wires. Physical review. B.. 102(14). 1 indexed citations
13.
Cox, David, R. Shaikhaidarov, Sergey Kubatkin, et al.. (2019). Near-Field Scanning Microwave Microscopy in the Single Photon Regime. Scientific Reports. 9(1). 12539–12539. 22 indexed citations
14.
Shaikhaidarov, R., et al.. (2019). Probing photon statistics of coherent states by continuous wave mixing on a two-level system. Physical review. A. 100(1). 13 indexed citations
15.
Graaf, S. E. de, Sebastian T. Skacel, R. Shaikhaidarov, et al.. (2018). Charge quantum interference device. Nature Physics. 14(6). 590–594. 43 indexed citations
16.
George, Richard E., Jorden Senior, J. P. Pekola, et al.. (2017). Multiplexing Superconducting Qubit Circuit for Single Microwave Photon Generation. Journal of Low Temperature Physics. 189(1-2). 60–75. 10 indexed citations
17.
Peng, Zhihui, S. E. de Graaf, J. S. Tsai, & O. V. Astafiev. (2016). Tuneable on-demand single-photon source in the microwave range. Nature Communications. 7(1). 12588–12588. 77 indexed citations
18.
Graaf, S. E. de, Andrey Danilov, & Sergey Kubatkin. (2015). Coherent interaction with two-level fluctuators using near field scanning microwave microscopy. Scientific Reports. 5(1). 17176–17176. 6 indexed citations
19.
Graaf, S. E. de, R. Gwilliam, Sergey Kubatkin, et al.. (2014). Coupling of a locally implanted rare-earth ion ensemble to a superconducting micro-resonator. Applied Physics Letters. 105(10). 10 indexed citations
20.
Graaf, S. E. de, Juha Leppäkangas, Andrey Danilov, et al.. (2013). Charge Qubit Coupled to an Intense Microwave Electromagnetic Field in a Superconducting Nb Device: Evidence for Photon-Assisted Quasiparticle Tunneling. Physical Review Letters. 111(13). 137002–137002. 21 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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