J. S. Reparaz

3.4k total citations
92 papers, 2.6k citations indexed

About

J. S. Reparaz is a scholar working on Materials Chemistry, Electrical and Electronic Engineering and Biomedical Engineering. According to data from OpenAlex, J. S. Reparaz has authored 92 papers receiving a total of 2.6k indexed citations (citations by other indexed papers that have themselves been cited), including 69 papers in Materials Chemistry, 34 papers in Electrical and Electronic Engineering and 27 papers in Biomedical Engineering. Recurrent topics in J. S. Reparaz's work include Thermal properties of materials (21 papers), Advanced Thermoelectric Materials and Devices (20 papers) and ZnO doping and properties (18 papers). J. S. Reparaz is often cited by papers focused on Thermal properties of materials (21 papers), Advanced Thermoelectric Materials and Devices (20 papers) and ZnO doping and properties (18 papers). J. S. Reparaz collaborates with scholars based in Spain, Germany and United States. J. S. Reparaz's co-authors include Markus R. Wagner, Bartłomiej Graczykowski, A. Hoffmann, F. Alzina, M. I. Alonso, A. R. Goñi, Marianna Sledzinska, Gordon Callsen, Jordi Gomis‐Brescó and Mariano Campoy‐Quiles and has published in prestigious journals such as Nature Communications, The Journal of Chemical Physics and Nature Materials.

In The Last Decade

J. S. Reparaz

89 papers receiving 2.6k citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
J. S. Reparaz Spain 33 1.8k 972 659 474 406 92 2.6k
Xiaojia Wang United States 27 1.6k 0.9× 714 0.7× 364 0.6× 413 0.9× 482 1.2× 79 2.5k
Insun Jo United States 16 3.7k 2.1× 1.1k 1.1× 559 0.8× 277 0.6× 732 1.8× 23 4.1k
Sheng Chu China 26 1.9k 1.1× 1.4k 1.4× 771 1.2× 930 2.0× 101 0.2× 88 3.0k
Zhiting Tian United States 34 3.5k 2.0× 1.1k 1.1× 321 0.5× 338 0.7× 982 2.4× 89 3.9k
M. Lomascolo Italy 26 1.7k 0.9× 1.5k 1.6× 773 1.2× 372 0.8× 134 0.3× 132 3.0k
Urcan Guler United States 22 1.1k 0.6× 918 0.9× 1.5k 2.2× 1.6k 3.4× 614 1.5× 43 3.4k
Ali K. Okyay Türkiye 31 1.7k 1.0× 2.2k 2.3× 1.4k 2.0× 831 1.8× 121 0.3× 156 3.6k
Toshihide Nabatame Japan 31 1.7k 1.0× 3.1k 3.2× 562 0.9× 1.0k 2.1× 166 0.4× 261 4.2k
Sun‐Kyung Kim South Korea 33 1.4k 0.8× 2.0k 2.1× 1.6k 2.4× 924 1.9× 463 1.1× 178 4.1k
Baratunde A. Cola United States 32 2.5k 1.4× 948 1.0× 640 1.0× 332 0.7× 604 1.5× 96 3.4k

Countries citing papers authored by J. S. Reparaz

Since Specialization
Citations

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

Fields of papers citing papers by J. S. Reparaz

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

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

Co-authorship network of co-authors of J. S. Reparaz

This figure shows the co-authorship network connecting the top 25 collaborators of J. S. Reparaz. A scholar is included among the top collaborators of J. S. Reparaz 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 J. S. Reparaz. J. S. Reparaz 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.
Zapata‐Arteaga, Osnat, Aleksandr Perevedentsev, Renee Kroon, et al.. (2025). Microstructural Evolution Dominates the Changes in the Thermal Conductivity of Conjugated Polymers Upon Doping. Advanced Functional Materials. 36(3). 1 indexed citations
2.
Riera‐Galindo, Sergi, Aleksandr Perevedentsev, J. S. Reparaz, et al.. (2025). Low-bandgap oligothiophene-naphthalimide oligomeric semiconductors for thermoelectric applications. Journal of Materials Chemistry C. 13(13). 6922–6932. 4 indexed citations
3.
Rodríguez‐Martínez, Xabier, Fernán Saiz, Bernhard Dörling, et al.. (2024). On The Thermal Conductivity of Conjugated Polymers for Thermoelectrics. Advanced Energy Materials. 14(35). 13 indexed citations
4.
Zapata‐Arteaga, Osnat, et al.. (2024). Upscaling Thermoelectrics: Micron-Thick, Half-a-Meter-Long Carbon Nanotube Films with Monolithic Integration of p- and n-Legs. ACS Applied Electronic Materials. 6(5). 2978–2987. 2 indexed citations
5.
Garriga, M., et al.. (2024). Impacts of graphene quantum dots on the optical, electrical and thermal properties of the archetypal conducting polymer PEDOT:PSS. Results in Optics. 16. 100737–100737. 1 indexed citations
6.
Griggs, Sophie, Renee Kroon, J. S. Reparaz, et al.. (2023). Impact of Oligoether Side-Chain Length on the Thermoelectric Properties of a Polar Polythiophene. ACS Applied Electronic Materials. 6(5). 2909–2916. 16 indexed citations
7.
Goñi, A. R., M. I. Alonso, Xavier Borrisé, et al.. (2023). In-plane thermal diffusivity determination using beam-offset frequency-domain thermoreflectance with a one-dimensional optical heat source. International Journal of Heat and Mass Transfer. 214. 124376–124376. 9 indexed citations
8.
Zapata‐Arteaga, Osnat, Sara Marina, Guangzheng Zuo, et al.. (2022). Design Rules for Polymer Blends with High Thermoelectric Performance. Advanced Energy Materials. 12(19). 23 indexed citations
9.
Pérez, Luis A., Markus R. Wagner, Bernhard Dörling, et al.. (2022). Anisotropic thermoreflectance thermometry: A contactless frequency-domain thermoreflectance approach to study anisotropic thermal transport. Review of Scientific Instruments. 93(3). 34902–34902. 13 indexed citations
10.
Dörling, Bernhard, et al.. (2021). Soluble alkali-metal carbon nanotube salts for n-type thermoelectric composites with improved stability. Applied Physics Letters. 118(21). 14 indexed citations
11.
Beardo, Albert, Miquel López-Suárez, Luis A. Pérez, et al.. (2021). Observation of second sound in a rapidly varying temperature field in Ge. Dipòsit Digital de Documents de la UAB (Universitat Autònoma de Barcelona). 53 indexed citations
12.
Zapata‐Arteaga, Osnat, Aleksandr Perevedentsev, Sara Marina, et al.. (2020). Reduction of the Lattice Thermal Conductivity of Polymer Semiconductors by Molecular Doping. ACS Energy Letters. 5(9). 2972–2978. 54 indexed citations
13.
Zapata‐Arteaga, Osnat, Bernhard Dörling, Aleksandr Perevedentsev, et al.. (2020). Closing the Stability–Performance Gap in Organic Thermoelectrics by Adjusting the Partial to Integer Charge Transfer Ratio. Macromolecules. 53(2). 609–620. 49 indexed citations
14.
Liu, Zilu, Tianjun Liu, Christopher N. Savory, et al.. (2020). Controlling the Thermoelectric Properties of Organometallic Coordination Polymers via Ligand Design. Advanced Functional Materials. 30(32). 24 indexed citations
15.
Abol-Fotouh, Deyaa, Bernhard Dörling, Osnat Zapata‐Arteaga, et al.. (2019). Farming thermoelectric paper. Energy & Environmental Science. 12(2). 716–726. 80 indexed citations
16.
Livneh, Tsachi, J. S. Reparaz, & A. R. Goñi. (2017). Low-temperature resonant Raman asymmetry in 2H-MoS2 under high pressure. Journal of Physics Condensed Matter. 29(43). 435702–435702. 3 indexed citations
17.
Zúñiga‐Pérez, J., Vincent Consonni, L. Lymperakis, et al.. (2016). Polarity in GaN and ZnO: Theory, measurement, growth, and devices. Applied Physics Reviews. 3(4). 110 indexed citations
18.
Reparaz, J. S., Emigdio Chávez‐Ángel, Markus R. Wagner, et al.. (2014). A novel contactless technique for thermal conductivity determination: Two-laser Raman thermometry. 1–3. 4 indexed citations
19.
Callsen, Gordon, Markus R. Wagner, Thomas Kure, et al.. (2012). Optical signature of Mg-doped GaN: Transfer processes. Physical Review B. 86(7). 48 indexed citations
20.
Reparaz, J. S.. (2008). Optical Properties of Low-Dimensional Semiconductor Nanostructures under High Pressure. Dipòsit Digital de Documents de la UAB (Universitat Autònoma de Barcelona). 1 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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