Annika Kurzmann

1.4k total citations
37 papers, 994 citations indexed

About

Annika Kurzmann is a scholar working on Atomic and Molecular Physics, and Optics, Materials Chemistry and Electrical and Electronic Engineering. According to data from OpenAlex, Annika Kurzmann has authored 37 papers receiving a total of 994 indexed citations (citations by other indexed papers that have themselves been cited), including 32 papers in Atomic and Molecular Physics, and Optics, 26 papers in Materials Chemistry and 17 papers in Electrical and Electronic Engineering. Recurrent topics in Annika Kurzmann's work include Quantum and electron transport phenomena (27 papers), Graphene research and applications (21 papers) and Semiconductor Quantum Structures and Devices (13 papers). Annika Kurzmann is often cited by papers focused on Quantum and electron transport phenomena (27 papers), Graphene research and applications (21 papers) and Semiconductor Quantum Structures and Devices (13 papers). Annika Kurzmann collaborates with scholars based in Switzerland, Japan and Germany. Annika Kurzmann's co-authors include K. Ensslin, Thomas Ihn, Takashi Taniguchi, Kenji Watanabe, Marius Eich, Peter Rickhaus, Riccardo Pisoni, Hiske Overweg, Yongjin Lee and A. Lorke and has published in prestigious journals such as Science, Physical Review Letters and Nano Letters.

In The Last Decade

Annika Kurzmann

37 papers receiving 977 citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
Annika Kurzmann Switzerland 18 782 742 296 91 73 37 994
Hiske Overweg Switzerland 14 659 0.8× 819 1.1× 268 0.9× 37 0.4× 78 1.1× 21 929
Marius Eich Switzerland 19 830 1.1× 988 1.3× 342 1.2× 45 0.5× 89 1.2× 28 1.2k
A. K. Hüttel Germany 15 1.2k 1.5× 513 0.7× 641 2.2× 87 1.0× 97 1.3× 41 1.3k
Christian Volk Germany 16 789 1.0× 502 0.7× 470 1.6× 192 2.1× 151 2.1× 41 1.0k
Marta Prada United States 11 599 0.8× 233 0.3× 410 1.4× 37 0.4× 81 1.1× 30 702
Péter Rakyta Hungary 12 573 0.7× 733 1.0× 246 0.8× 53 0.6× 38 0.5× 25 888
Martin Fuechsle Australia 7 721 0.9× 236 0.3× 654 2.2× 159 1.7× 165 2.3× 10 1.0k
R. Knobel United States 10 803 1.0× 177 0.2× 509 1.7× 142 1.6× 97 1.3× 23 900
Wataru Izumida Japan 16 673 0.9× 355 0.5× 283 1.0× 55 0.6× 63 0.9× 39 822
Weidong Sheng China 22 979 1.3× 662 0.9× 596 2.0× 57 0.6× 122 1.7× 79 1.3k

Countries citing papers authored by Annika Kurzmann

Since Specialization
Citations

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

Fields of papers citing papers by Annika Kurzmann

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

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

Co-authorship network of co-authors of Annika Kurzmann

This figure shows the co-authorship network connecting the top 25 collaborators of Annika Kurzmann. A scholar is included among the top collaborators of Annika Kurzmann 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 Annika Kurzmann. Annika Kurzmann 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.
Kurzmann, Annika, Rüdiger Schott, Arne Ludwig, et al.. (2024). Quantum polyspectra approach to the dynamics of blinking quantum emitters at low photon rates without binning: Making every photon count. Physical review. A. 109(6). 2 indexed citations
2.
Tong, Chuyao, Annika Kurzmann, Rebekka Garreis, et al.. (2024). Pauli blockade catalogue and three- and four-particle Kondo effect in bilayer graphene quantum dots. Physical Review Research. 6(1). 6 indexed citations
3.
Tong, Chuyao, Annika Kurzmann, Rebekka Garreis, et al.. (2024). Three-Carrier Spin Blockade and Coupling in Bilayer Graphene Double Quantum Dots. Physical Review Letters. 133(1). 17001–17001. 3 indexed citations
4.
Garreis, Rebekka, Chuyao Tong, Kenji Watanabe, et al.. (2023). Counting statistics of single electron transport in bilayer graphene quantum dots. Physical Review Research. 5(1). 9 indexed citations
5.
Bucko, Jozef, Frank Schäfer, František Herman, et al.. (2023). Automated Reconstruction of Bound States in Bilayer Graphene Quantum Dots. Physical Review Applied. 19(2). 3 indexed citations
6.
Garreis, Rebekka, Chuyao Tong, Folkert K. de Vries, et al.. (2022). Single-Shot Spin Readout in Graphene Quantum Dots. PRX Quantum. 3(2). 25 indexed citations
7.
Kurzmann, Annika, et al.. (2022). Pushing the Limits in Real-Time Measurements of Quantum Dynamics. Physical Review Letters. 128(8). 87701–87701. 15 indexed citations
8.
Rickhaus, Peter, Folkert K. de Vries, Jihang Zhu, et al.. (2021). Correlated electron-hole state in twisted double-bilayer graphene. Science. 373(6560). 1257–1260. 55 indexed citations
9.
Garreis, Rebekka, Angelika Knothe, Chuyao Tong, et al.. (2021). Shell Filling and Trigonal Warping in Graphene Quantum Dots. Physical Review Letters. 126(14). 147703–147703. 26 indexed citations
10.
Knothe, Angelika, Annika Kurzmann, Kenji Watanabe, et al.. (2021). Coherent Jetting from a Gate-Defined Channel in Bilayer Graphene. Physical Review Letters. 127(4). 46801–46801. 23 indexed citations
11.
Vries, Folkert K. de, Jihang Zhu, Elías Portolés, et al.. (2020). Combined Minivalley and Layer Control in Twisted Double Bilayer Graphene. Physical Review Letters. 125(17). 176801–176801. 21 indexed citations
12.
Eich, Marius, Riccardo Pisoni, Chuyao Tong, et al.. (2020). Coulomb dominated cavities in bilayer graphene. Physical Review Research. 2(2). 3 indexed citations
13.
Kurzmann, Annika, et al.. (2020). Scanning gate microscopy of localized states in a gate-defined bilayer graphene channel. Repository for Publications and Research Data (ETH Zurich). 6 indexed citations
14.
Lee, Yongjin, Angelika Knothe, Hiske Overweg, et al.. (2020). Tunable Valley Splitting due to Topological Orbital Magnetic Moment in Bilayer Graphene Quantum Point Contacts. Physical Review Letters. 124(12). 126802–126802. 53 indexed citations
15.
Kurzmann, Annika, Marius Eich, Hiske Overweg, et al.. (2019). Excited States in Bilayer Graphene Quantum Dots. Physical Review Letters. 123(2). 26803–26803. 68 indexed citations
16.
Kurzmann, Annika, Rüdiger Schott, Arne Ludwig, et al.. (2019). Optical Detection of Single-Electron Tunneling into a Semiconductor Quantum Dot. Physical Review Letters. 122(24). 247403–247403. 40 indexed citations
17.
Eich, Marius, Riccardo Pisoni, Hiske Overweg, et al.. (2018). Spin and Valley States in Gate-Defined Bilayer Graphene Quantum Dots. Repository for Publications and Research Data (ETH Zurich). 111 indexed citations
18.
Kurzmann, Annika, et al.. (2017). Electron dynamics in transport and optical measurements of self‐assembled quantum dots. physica status solidi (b). 254(3). 6 indexed citations
19.
Kurzmann, Annika, et al.. (2017). Charge-driven feedback loop in the resonance fluorescence of a single quantum dot. Physical review. B.. 95(11). 4 indexed citations
20.
Kurzmann, Annika, Arne Ludwig, Andreas D. Wieck, A. Lorke, & M. Geller. (2016). Photoelectron generation and capture in the resonance fluorescence of a quantum dot. Applied Physics Letters. 108(26). 12 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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