Thomas P. Burg

3.6k total citations · 1 hit paper
56 papers, 2.7k citations indexed

About

Thomas P. Burg is a scholar working on Biomedical Engineering, Electrical and Electronic Engineering and Atomic and Molecular Physics, and Optics. According to data from OpenAlex, Thomas P. Burg has authored 56 papers receiving a total of 2.7k indexed citations (citations by other indexed papers that have themselves been cited), including 30 papers in Biomedical Engineering, 21 papers in Electrical and Electronic Engineering and 20 papers in Atomic and Molecular Physics, and Optics. Recurrent topics in Thomas P. Burg's work include Mechanical and Optical Resonators (18 papers), Microfluidic and Bio-sensing Technologies (16 papers) and Microfluidic and Capillary Electrophoresis Applications (15 papers). Thomas P. Burg is often cited by papers focused on Mechanical and Optical Resonators (18 papers), Microfluidic and Bio-sensing Technologies (16 papers) and Microfluidic and Capillary Electrophoresis Applications (15 papers). Thomas P. Burg collaborates with scholars based in Germany, United States and Australia. Thomas P. Burg's co-authors include Scott R. Manalis, Ken Babcock, Michel Godin, Wenjiang Shen, John S. Foster, Scott M. Knudsen, G. Carlson, Mario M. Modena, Stefan Wuttke and Bastian Rühle and has published in prestigious journals such as Nature, Proceedings of the National Academy of Sciences and Physical Review Letters.

In The Last Decade

Thomas P. Burg

53 papers receiving 2.6k citations

Hit Papers

Weighing of biomolecules, single cells and single nanopar... 2007 2026 2013 2019 2007 250 500 750
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. Weighing of biomolecules, single cells and single nanoparticles in fluid
    2007 898 citations Thomas P. Burg, Michel Godin et al. Nature profile →

Peers

Thomas P. Burg
Karsten Hinrichs Germany
Michel Godin Canada
Dmitri Vezenov United States
Yunhan Luo China
Giuseppe Maruccio Italy
Michael A. Bevan United States
Maximilian Kreiter Germany
A. Yamaguchi Japan
P. G. Gucciardi Italy
Meng Lu United States
Karsten Hinrichs Germany
Thomas P. Burg
Citations per year, relative to Thomas P. Burg Thomas P. Burg (= 1×) peers Karsten Hinrichs

Countries citing papers authored by Thomas P. Burg

Since Specialization
Citations

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

Fields of papers citing papers by Thomas P. Burg

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Thomas P. Burg. 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 Thomas P. Burg. The network helps show where Thomas P. Burg may publish in the future.

Co-authorship network of co-authors of Thomas P. Burg

This figure shows the co-authorship network connecting the top 25 collaborators of Thomas P. Burg. A scholar is included among the top collaborators of Thomas P. Burg 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 Thomas P. Burg. Thomas P. Burg 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.
2.
Brückner, Martin, et al.. (2025). Cryo-iCLEM: Cryo correlative light and electron microscopy with immersion objectives. Journal of Structural Biology. 217(1). 108179–108179. 2 indexed citations
3.
Szabó, G., et al.. (2024). Model-Based Optimization of Solid-Supported Micro-Hotplates for Microfluidic Cryofixation. Micromachines. 15(9). 1069–1069. 1 indexed citations
4.
Yu, Xiangjiang, Jacopo Andreo, F. Javier del Campo, et al.. (2023). The Importance of Dean Flow in Microfluidic Nanoparticle Synthesis: A ZIF‐8 Case Study. Small Methods. 8(1). e2300603–e2300603. 10 indexed citations
5.
Stehr, Matthias, et al.. (2020). Nanofluidic Immobilization and Growth Detection of Escherichia coli in a Chip for Antibiotic Susceptibility Testing. Biosensors. 10(10). 135–135. 7 indexed citations
6.
Lowe, Rachel D., et al.. (2020). Biosensing based on optimized asymmetric optofluidic nanochannel gratings. Micro and Nano Engineering. 8. 100056–100056. 9 indexed citations
7.
Schaffer, Miroslava, et al.. (2019). In situ Microfluidic Cryofixation for Cryo Focused Ion Beam Milling and Cryo Electron Tomography. Scientific Reports. 9(1). 19133–19133. 23 indexed citations
8.
Wuttke, Stefan, Ulrich Lächelt, Hanna Engelke, & Thomas P. Burg. (2017). The chemistry of metal–organic framework nanoparticles. Acta Crystallographica Section A Foundations and Advances. 73(a2). C1282–C1283.
9.
Steltenkamp, Siegfried, et al.. (2016). Continuous high throughput nanofluidic separation through tangential-flow vertical nanoslit arrays. Lab on a Chip. 16(23). 4546–4553. 3 indexed citations
10.
Modena, Mario M. & Thomas P. Burg. (2015). Mass correlation spectroscopy for mass- and size-based nanoparticle characterization in fluid. Journal of Applied Physics. 118(22). 2 indexed citations
11.
Modena, Mario M., et al.. (2014). Label-Free Measurement of Amyloid Elongation by Suspended Microchannel Resonators. Analytical Chemistry. 87(3). 1821–1828. 11 indexed citations
12.
Jain, Rohit, Siegfried Steltenkamp, Stefan Becker, et al.. (2013). X-ray scattering experiments with high-flux X-ray source coupled rapid mixing microchannel device and their potential for high-flux neutron scattering investigations. The European Physical Journal E. 36(9). 109–109. 11 indexed citations
13.
Modena, Mario M., Yu Wang, Dietmar Riedel, & Thomas P. Burg. (2013). Resolution enhancement of suspended microchannel resonators for weighing of biomolecular complexes in solution. Lab on a Chip. 14(2). 342–350. 23 indexed citations
14.
Delgado, Francisco Feijó, et al.. (2011). Mass sensors with mechanical traps for weighing single cells in different fluids. Lab on a Chip. 11(24). 4174–4174. 25 indexed citations
15.
Lee, Jungchul, Rumi Chunara, Kristofor R. Payer, et al.. (2010). Suspended microchannel resonators with piezoresistive sensors. Lab on a Chip. 11(4). 645–651. 57 indexed citations
16.
Burg, Thomas P., John E. Sader, & Scott R. Manalis. (2009). Nonmonotonic Energy Dissipation in Microfluidic Resonators. Physical Review Letters. 102(22). 228103–228103. 46 indexed citations
17.
Burg, Thomas P., Michel Godin, Scott M. Knudsen, et al.. (2007). Weighing of biomolecules, single cells and single nanoparticles in fluid. Nature. 446(7139). 1066–1069. 898 indexed citations breakdown →
18.
Nowotny, Janusz, T. Bąk, & Thomas P. Burg. (2007). Electrical properties of polycrystalline TiO2· Thermoelectric power. Ionics. 13(3). 155–162. 13 indexed citations
19.
Burg, Thomas P. & Scott R. Manalis. (2005). Microfluidic Packaging of Suspended Microchannel Resonators for Biomolecular Detection. 264–267. 2 indexed citations
20.
Savran, Cagri A., Jian Li, Thomas P. Burg, et al.. (2002). Fabrication and characterization of a micromechanical sensor for differential detection of nanoscale motions. Journal of Microelectromechanical Systems. 11(6). 703–708. 29 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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