S. Sen

2.3k total citations
55 papers, 1.9k citations indexed

About

S. Sen is a scholar working on Electrical and Electronic Engineering, Renewable Energy, Sustainability and the Environment and Materials Chemistry. According to data from OpenAlex, S. Sen has authored 55 papers receiving a total of 1.9k indexed citations (citations by other indexed papers that have themselves been cited), including 32 papers in Electrical and Electronic Engineering, 14 papers in Renewable Energy, Sustainability and the Environment and 13 papers in Materials Chemistry. Recurrent topics in S. Sen's work include Advanced Semiconductor Detectors and Materials (16 papers), CO2 Reduction Techniques and Catalysts (9 papers) and Advanced battery technologies research (9 papers). S. Sen is often cited by papers focused on Advanced Semiconductor Detectors and Materials (16 papers), CO2 Reduction Techniques and Catalysts (9 papers) and Advanced battery technologies research (9 papers). S. Sen collaborates with scholars based in United States, India and South Korea. S. Sen's co-authors include G. Tayhas R. Palmore, Peter A. Curreri, D. M. Stefanescu, B. K. Dhindaw, Chandra S. Ray, M. H. Kalisher, Signo T. Reis, David R. Rhiger, Adrian V. Catalina and Leslie G. Bland and has published in prestigious journals such as Applied Physics Letters, Macromolecules and ACS Catalysis.

In The Last Decade

S. Sen

53 papers receiving 1.9k 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. Sen United States 21 809 693 640 373 294 55 1.9k
Hisayoshi Matsushima Japan 25 1.3k 1.6× 812 1.2× 713 1.1× 195 0.5× 259 0.9× 96 2.2k
Margitta Uhlemann Germany 37 1.9k 2.4× 1.8k 2.6× 518 0.8× 214 0.6× 598 2.0× 136 3.8k
Han Wang China 31 1.1k 1.4× 1.5k 2.2× 548 0.9× 47 0.1× 444 1.5× 150 3.1k
Akihiko Ohi Japan 22 915 1.1× 1.1k 1.6× 137 0.2× 533 1.4× 283 1.0× 114 2.0k
Roberto Ribeiro de Avillez Brazil 23 517 0.6× 1.3k 1.9× 119 0.2× 496 1.3× 289 1.0× 108 2.0k
Varghese Swamy Malaysia 29 1.1k 1.3× 2.7k 3.9× 862 1.3× 71 0.2× 498 1.7× 84 3.9k
Nozomu Hatakeyama Japan 22 425 0.5× 810 1.2× 279 0.4× 143 0.4× 158 0.5× 94 1.9k
Yoshinori Murakami Japan 22 739 0.9× 678 1.0× 709 1.1× 64 0.2× 202 0.7× 120 1.7k
Kasala Prabhakar Reddy India 23 725 0.9× 1.1k 1.6× 985 1.5× 261 0.7× 92 0.3× 43 1.9k
Jenel Vatamanu United States 39 5.0k 6.2× 570 0.8× 443 0.7× 1.1k 2.9× 311 1.1× 57 6.7k

Countries citing papers authored by S. Sen

Since Specialization
Citations

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

Fields of papers citing papers by S. Sen

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

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

Co-authorship network of co-authors of S. Sen

This figure shows the co-authorship network connecting the top 25 collaborators of S. Sen. A scholar is included among the top collaborators of S. Sen 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. Sen. S. Sen 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.
Sen, S., Steven M. Brown, McLain Leonard, & Fikile R. Brushett. (2019). Electroreduction of carbon dioxide to formate at high current densities using tin and tin oxide gas diffusion electrodes. Journal of Applied Electrochemistry. 49(9). 917–928. 53 indexed citations
3.
Sen, S., et al.. (2017). Electroactive nanofluids with high solid loading and low viscosity for rechargeable redox flow batteries. Journal of Applied Electrochemistry. 47(5). 593–605. 28 indexed citations
4.
Sen, S., et al.. (2017). Pulsed Electrodeposition of Tin Electrocatalysts Onto Gas Diffusion Layers for CO2 Reduction to Formate. ECS Meeting Abstracts. MA2017-01(24). 1178–1178. 1 indexed citations
5.
Brushett, Fikile R., et al.. (2016). Development of Novel Tin Nanostructures Using Pulse Plating Methods for the Electroreduction of Carbon Dioxide to Formic Acid. ECS Meeting Abstracts. MA2016-02(40). 3012–3012. 1 indexed citations
6.
Sen, S., et al.. (2016). In Situ Measurement of Voltage-Induced Stress in Conducting Polymers with Redox-Active Dopants. ACS Applied Materials & Interfaces. 8(36). 24168–24176. 16 indexed citations
7.
Sen, S., et al.. (2015). Electrochemical reduction of CO2 with clathrate hydrate electrolytes and copper foam electrodes. Electrochemistry Communications. 52. 13–16. 38 indexed citations
8.
Sen, S., Elena V. Timofeeva, Christopher J. Pelliccione, et al.. (2015). Development of Nanoelectrofuel Electrodes for Flow Batteries : Rheology and Electrochemistry of Fluidized Nanoparticles. ECS Meeting Abstracts. MA2015-01(1). 224–224. 3 indexed citations
9.
Timofeeva, Elena V., S. Sen, John P. Katsoudas, et al.. (2015). From Nanofluids to Nanoelectrofuels: Suspension Electrodes and Application in Flow Batteries. ECS Meeting Abstracts. MA2015-01(1). 227–227. 1 indexed citations
10.
Sen, S., et al.. (2014). Electrochemical Reduction of CO2 at Copper Nanofoams. ACS Catalysis. 4(9). 3091–3095. 487 indexed citations
11.
Liu, Xinyuan, S. Sen, Jingyu Liu, et al.. (2011). Antioxidant Deactivation on Graphenic Nanocarbon Surfaces. Small. 7(19). 2775–2785. 128 indexed citations
12.
Ray, Chandra S., et al.. (2006). Mössbauer and EPR spectra for glasses and glass-ceramics prepared from simulated compositions of Lunar and Martian soils. Journal of Non-Crystalline Solids. 352(32-35). 3677–3684. 14 indexed citations
13.
Berding, M. A., W.D. Nix, David R. Rhiger, S. Sen, & A. Sher. (2000). Critical thickness in the HgCdTe/CdZnTe system. Journal of Electronic Materials. 29(6). 676–679. 22 indexed citations
14.
Stefanescu, D. M., et al.. (1998). Particle engulfment and pushing by solidifying interfaces: Part II. Microgravity experiments and theoretical analysis. Metallurgical and Materials Transactions A. 29(6). 1697–1706. 116 indexed citations
15.
Sen, S., Peter A. Curreri, William F. Kaukler, & D. M. Stefanescu. (1997). Dynamics of solid/liquid interface shape evolution near an insoluble particle—An X-ray transmission microscopy investigation. Metallurgical and Materials Transactions A. 28(10). 2129–2135. 46 indexed citations
16.
Sen, S., B. K. Dhindaw, D. M. Stefanescu, Adrian V. Catalina, & Peter A. Curreri. (1997). Melt convection effects on the critical velocity of particle engulfment. Journal of Crystal Growth. 173(3-4). 574–584. 36 indexed citations
17.
Sen, S., et al.. (1996). Reduction of CdZnTe substrate defects and relation to epitaxial HgCdTe quality. Journal of Electronic Materials. 25(8). 1188–1195. 49 indexed citations
18.
Sen, S., et al.. (1994). Developments in the bulk growth of Cd1−xZnxTe for substrates. Progress in Crystal Growth and Characterization of Materials. 29(1-4). 253–273. 29 indexed citations
19.
Sen, S., et al.. (1989). Growth of Large-Diameter CdZnTe and CdTeSe Boules for Hg1−xCdxTe Epitaxy: Status and Prospects. MRS Proceedings. 161. 8 indexed citations
20.
Smith, E. J., et al.. (1987). Epitaxial growth, characterization, and phase diagram of HgZnTe. Journal of Vacuum Science & Technology A Vacuum Surfaces and Films. 5(5). 3043–3047. 16 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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