David Goldhaber‐Gordon

14.7k total citations · 6 hit papers
137 papers, 11.2k citations indexed

About

David Goldhaber‐Gordon is a scholar working on Atomic and Molecular Physics, and Optics, Materials Chemistry and Electrical and Electronic Engineering. According to data from OpenAlex, David Goldhaber‐Gordon has authored 137 papers receiving a total of 11.2k indexed citations (citations by other indexed papers that have themselves been cited), including 103 papers in Atomic and Molecular Physics, and Optics, 77 papers in Materials Chemistry and 56 papers in Electrical and Electronic Engineering. Recurrent topics in David Goldhaber‐Gordon's work include Quantum and electron transport phenomena (76 papers), Graphene research and applications (53 papers) and Topological Materials and Phenomena (32 papers). David Goldhaber‐Gordon is often cited by papers focused on Quantum and electron transport phenomena (76 papers), Graphene research and applications (53 papers) and Topological Materials and Phenomena (32 papers). David Goldhaber‐Gordon collaborates with scholars based in United States, Japan and Israel. David Goldhaber‐Gordon's co-authors include Hadas Shtrikman, M. A. Kastner, D. Mahalu, U. Meirav, Benjamin Huard, N. Stander, David Abusch-Magder, Kenji Watanabe, Joseph Sulpizio and Takashi Taniguchi and has published in prestigious journals such as Nature, Science and Proceedings of the National Academy of Sciences.

In The Last Decade

David Goldhaber‐Gordon

136 papers receiving 11.0k citations

Hit Papers

Kondo effect in a single-... 1998 2026 2007 2016 1998 1998 2009 2007 2019 500 1000 1.5k
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. Kondo effect in a single-electron transistor
    1998 1.7k citations David Goldhaber‐Gordon, M. A. Kastner et al. profile →
  2. From the Kondo Regime to the Mixed-Valence Regime in a Single-Electron Transistor
    1998 619 citations David Goldhaber‐Gordon, M. A. Kastner et al. Physical Review Letters profile →
  3. Evidence for Klein Tunneling in GraphenepnJunctions
    2009 538 citations N. Stander, Benjamin Huard et al. Physical Review Letters profile →
  4. Transport Measurements Across a Tunable Potential Barrier in Graphene
    2007 521 citations Benjamin Huard, Joseph Sulpizio et al. Physical Review Letters profile →
  5. Data for: Emergent ferromagnetism near three-quarters filling in twisted bilayer graphene
    2019 518 citations Aaron L. Sharpe, Eli Fox et al. profile →
  6. Signatures of tunable superconductivity in a trilayer graphene moiré superlattice
    2019 485 citations Guorui Chen, Aaron L. Sharpe et al. profile →

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
David Goldhaber‐Gordon United States 47 8.7k 5.2k 4.2k 2.5k 863 137 11.2k
Paweł Hawrylak Canada 54 10.2k 1.2× 5.3k 1.0× 5.4k 1.3× 1.5k 0.6× 984 1.1× 326 12.5k
K. Eberl Germany 54 8.9k 1.0× 3.8k 0.7× 6.6k 1.6× 1.7k 0.7× 1.5k 1.8× 391 11.8k
K. Ensslin Switzerland 60 11.0k 1.3× 5.3k 1.0× 5.2k 1.2× 1.7k 0.7× 1.2k 1.4× 441 13.4k
H. Q. Xu Sweden 49 6.7k 0.8× 5.3k 1.0× 5.1k 1.2× 1.9k 0.8× 3.6k 4.1× 276 11.6k
Antti‐Pekka Jauho Denmark 54 8.8k 1.0× 4.4k 0.9× 5.3k 1.3× 1.2k 0.5× 1.9k 2.2× 206 11.9k
Andreas D. Wieck Germany 54 10.2k 1.2× 3.0k 0.6× 5.8k 1.4× 1.5k 0.6× 1.1k 1.3× 688 12.9k
Tsuneya Ando Japan 62 17.6k 2.0× 11.7k 2.3× 7.3k 1.7× 3.5k 1.4× 1.3k 1.6× 303 22.3k
Igor Žutić United States 44 10.2k 1.2× 6.0k 1.2× 4.6k 1.1× 4.1k 1.7× 310 0.4× 146 14.1k
D. Weiß Germany 51 8.2k 0.9× 2.6k 0.5× 2.5k 0.6× 3.3k 1.3× 944 1.1× 231 9.6k
Michael E. Flatté United States 49 6.8k 0.8× 3.0k 0.6× 4.6k 1.1× 1.7k 0.7× 460 0.5× 275 9.3k

Countries citing papers authored by David Goldhaber‐Gordon

Since Specialization
Citations

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

Fields of papers citing papers by David Goldhaber‐Gordon

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by David Goldhaber‐Gordon. 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 David Goldhaber‐Gordon. The network helps show where David Goldhaber‐Gordon may publish in the future.

Co-authorship network of co-authors of David Goldhaber‐Gordon

This figure shows the co-authorship network connecting the top 25 collaborators of David Goldhaber‐Gordon. A scholar is included among the top collaborators of David Goldhaber‐Gordon 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 David Goldhaber‐Gordon. David Goldhaber‐Gordon 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.
Panna, Alireza R., Peng Zhang, Lixuan Tai, et al.. (2025). A unified realization of electrical quantities from the quantum International System of Units. Nature Electronics. 8(8). 663–671. 1 indexed citations
2.
Xia, Li-Qiao, Sergio C. de la Barrera, Aviram Uri, et al.. (2025). Topological bands and correlated states in helical trilayer graphene. Nature Physics. 21(2). 239–244. 7 indexed citations
3.
Hocking, M. B., Mihir Pendharkar, Nathan J. Bittner, et al.. (2024). Thermal relaxation of strain and twist in ferroelectric hexagonal boron nitride moiré interfaces. Journal of Applied Physics. 136(2). 1 indexed citations
4.
Pendharkar, Mihir, Joe Finney, Aaron L. Sharpe, et al.. (2024). Torsional force microscopy of van der Waals moirés and atomic lattices. Proceedings of the National Academy of Sciences. 121(10). e2314083121–e2314083121. 11 indexed citations
5.
Chen, Guorui, Ya-Hui Zhang, Ya-Hui Zhang, et al.. (2023). Magnetic Field-Stabilized Wigner Crystal States in a Graphene Moiré Superlattice. Nano Letters. 23(15). 7023–7028. 10 indexed citations
6.
Matt, C. E., Yu Liu, Pengcheng Chen, et al.. (2023). Visualizing the atomic-scale origin of metallic behavior in Kondo insulators. Science. 379(6638). 1214–1218. 13 indexed citations
7.
Mikheev, Evgeny, et al.. (2023). A clean ballistic quantum point contact in strontium titanate. Nature Electronics. 6(6). 417–424. 4 indexed citations
8.
Boulat, E., et al.. (2023). Z3 Parafermion in the Double Charge Kondo Model. Physical Review Letters. 130(14). 146201–146201. 14 indexed citations
9.
Panna, Alireza R., Ilan T. Rosen, Peng Zhang, et al.. (2022). Metrological Assessment of Quantum Anomalous Hall Properties. Physical Review Applied. 18(3). 8 indexed citations
10.
Chen, Yi‐Ting, et al.. (2022). Nanoscale Electronic Transparency of Wafer-Scale Hexagonal Boron Nitride. Nano Letters. 22(11). 4608–4615. 3 indexed citations
11.
Salehi, M., Hassan Shapourian, Ilan T. Rosen, et al.. (2019). Quantum‐Hall to Insulator Transition in Ultra‐Low‐Carrier‐Density Topological Insulator Films and a Hidden Phase of the Zeroth Landau Level. Advanced Materials. 31(36). e1901091–e1901091. 14 indexed citations
12.
Allen, Monica, Yong‐Tao Cui, Yue Ma, et al.. (2019). Visualization of an axion insulating state at the transition between 2 chiral quantum anomalous Hall states. Proceedings of the National Academy of Sciences. 116(29). 14511–14515. 59 indexed citations
13.
Fox, Eli, Ilan T. Rosen, Yanfei Yang, et al.. (2018). Part-per-million quantization and current-induced breakdown of the quantum anomalous Hall effect. Physical review. B.. 98(7). 66 indexed citations
14.
Tang, Kechao, Andrew C. Meng, Fei Hui, et al.. (2017). Distinguishing Oxygen Vacancy Electromigration and Conductive Filament Formation in TiO2Resistance Switching Using Liquid Electrolyte Contacts. Nano Letters. 17(7). 4390–4399. 55 indexed citations
15.
Nowack, Katja C., Eric Spanton, Matthias Baenninger, et al.. (2013). Imaging currents in HgTe quantum wells in the quantum spin Hall regime. Nature Materials. 12(9). 787–791. 183 indexed citations
16.
Hosseini, Ali, et al.. (2012). Molecular Junctions of Self-Assembled Monolayers with Conducting Polymer Contacts. ACS Nano. 6(11). 9920–9931. 39 indexed citations
17.
Stander, N., Benjamin Huard, & David Goldhaber‐Gordon. (2009). Evidence for Klein Tunneling in GraphenepnJunctions. Physical Review Letters. 102(2). 26807–26807. 538 indexed citations breakdown →
18.
Stander, N., Benjamin Huard, & David Goldhaber‐Gordon. (2008). Observation of Klein tunneling in graphene p-n junctions. arXiv (Cornell University). 3 indexed citations
19.
Cronenwett, S. M., David Goldhaber‐Gordon, Leo P. Kouwenhoven, et al.. (2002). Low-Temperature Fate of the 0.7 Structure in a Point Contact: A Kondo-like Correlated State in an Open System. Physical Review Letters. 88(22). 226805–226805. 312 indexed citations
20.
Klein, O., David Goldhaber‐Gordon, Claudio Chamon, & M. A. Kastner. (1996). Magnetic-field dependence of the level spacing of a small electron droplet. Physical review. B, Condensed matter. 53(8). R4221–R4224. 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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