Paul Pistor

2.4k total citations
69 papers, 2.1k citations indexed

About

Paul Pistor is a scholar working on Electrical and Electronic Engineering, Materials Chemistry and Atomic and Molecular Physics, and Optics. According to data from OpenAlex, Paul Pistor has authored 69 papers receiving a total of 2.1k indexed citations (citations by other indexed papers that have themselves been cited), including 67 papers in Electrical and Electronic Engineering, 59 papers in Materials Chemistry and 17 papers in Atomic and Molecular Physics, and Optics. Recurrent topics in Paul Pistor's work include Chalcogenide Semiconductor Thin Films (59 papers), Quantum Dots Synthesis And Properties (49 papers) and Copper-based nanomaterials and applications (24 papers). Paul Pistor is often cited by papers focused on Chalcogenide Semiconductor Thin Films (59 papers), Quantum Dots Synthesis And Properties (49 papers) and Copper-based nanomaterials and applications (24 papers). Paul Pistor collaborates with scholars based in Germany, Spain and Sweden. Paul Pistor's co-authors include Víctor Izquierdo‐Roca, Sergio Giraldo, Edgardo Saucedo, Wolfgang Fränzel, A. Pérez‐Rodríguez, Marcel Placidi, Markus Neuschitzer, R. Klenk, Andreu Cabot and Roland Scheer and has published in prestigious journals such as The Journal of Chemical Physics, Energy & Environmental Science and Applied Physics Letters.

In The Last Decade

Paul Pistor

69 papers receiving 2.0k citations

Peers — A (Enhanced Table)

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

Name h Career Trend Papers Cites
Paul Pistor Germany 23 2.0k 1.8k 408 135 94 69 2.1k
Joel N. Duenow United States 25 2.0k 1.0× 1.9k 1.0× 415 1.0× 43 0.3× 96 1.0× 81 2.2k
Bart Vermang Belgium 28 2.4k 1.2× 1.9k 1.0× 751 1.8× 50 0.4× 57 0.6× 162 2.5k
Junbo Gong China 25 1.7k 0.9× 1.4k 0.8× 196 0.5× 262 1.9× 102 1.1× 56 1.9k
Jimmy‐Xuan Shen United States 17 835 0.4× 777 0.4× 177 0.4× 84 0.6× 203 2.2× 45 1.1k
James M. Burst United States 22 1.8k 0.9× 1.6k 0.9× 354 0.9× 114 0.8× 55 0.6× 55 1.9k
Hannes Hempel Germany 24 2.1k 1.1× 1.7k 0.9× 169 0.4× 500 3.7× 89 0.9× 56 2.3k
Jun Haruyama Japan 14 1.9k 1.0× 1.1k 0.6× 122 0.3× 323 2.4× 81 0.9× 37 2.1k
Clay DeHart United States 19 3.2k 1.6× 3.1k 1.7× 536 1.3× 48 0.4× 168 1.8× 52 3.4k
Juliane Borchert Germany 17 1.3k 0.6× 908 0.5× 119 0.3× 281 2.1× 63 0.7× 33 1.3k
Hossein Mirhosseini Germany 21 867 0.4× 897 0.5× 515 1.3× 71 0.5× 207 2.2× 58 1.5k

Countries citing papers authored by Paul Pistor

Since Specialization
Citations

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

Fields of papers citing papers by Paul Pistor

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

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

Co-authorship network of co-authors of Paul Pistor

This figure shows the co-authorship network connecting the top 25 collaborators of Paul Pistor. A scholar is included among the top collaborators of Paul Pistor 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 Paul Pistor. Paul Pistor 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.
Aranda, Clara, Wenhui Li, Eugenia Martínez‐Ferrero, et al.. (2025). Insights from Impedance Spectroscopy in Perovskite Solar Cells with Self-Assembled Monolayers: Decoding SAM’s Tricks. The Journal of Physical Chemistry Letters. 16(9). 2301–2308. 3 indexed citations
2.
Rodríguez‐Gattorno, Geonel, et al.. (2025). Improving the Performance of Carbon-Based Perovskite Solar Cells by the Incorporation of a Screen-Printed NiCo 2 O 4 Interlayer. ACS Applied Energy Materials. 8(3). 1446–1457. 1 indexed citations
3.
Aranda, Clara, Antonio J. Riquelme, Renaud Demadrille, et al.. (2024). Competition between Transport and Recombination in Dye Solar Cells at Low Light Intensity. Solar RRL. 8(10). 4 indexed citations
4.
Anta, Juan A., Gerko Oskam, & Paul Pistor. (2024). The dual nature of metal halide perovskites. The Journal of Chemical Physics. 160(15). 4 indexed citations
5.
Schulz, Tobias, et al.. (2023). Structural Evolution of Sequentially Evaporated (Cs,FA)Pb(I,Br)3 Perovskite Thin Films via In Situ X‐Ray Diffraction. physica status solidi (a). 221(3). 6 indexed citations
6.
7.
Scheer, Roland, et al.. (2022). Stoichiometry dependent phase evolution of co-evaporated formamidinium and cesium lead halide thin films. Materials Advances. 3(23). 8695–8704. 5 indexed citations
8.
Pistor, Paul, et al.. (2022). Thermal decomposition kinetics of FAPbI3 thin films. Physical Review Materials. 6(6). 11 indexed citations
9.
Giraldo, Sergio, Xavier Alcobé, Ignacio Becerril‐Romero, et al.. (2022). Kinetics and phase analysis of kesterite compounds: Influence of chalcogen availability in the reaction pathway. Materialia. 24. 101509–101509. 3 indexed citations
10.
Sánchez, Yudania, Marcel Placidi, Víctor Izquierdo‐Roca, et al.. (2022). A new approach for alkali incorporation in Cu 2 ZnSnS 4 solar cells. Journal of Physics Energy. 4(4). 44008–44008. 5 indexed citations
11.
Pistor, Paul, et al.. (2021). Reaction kinetics of the thermal decomposition of MAPbI3 thin films. Physical Review Materials. 5(6). 9 indexed citations
12.
Pistor, Paul, Michaela Meyns, Maxim Guc, et al.. (2020). Advanced Raman spectroscopy of Cs2AgBiBr6 double perovskites and identification of Cs3Bi2Br9 secondary phases. Scripta Materialia. 184. 24–29. 67 indexed citations
13.
Becerril‐Romero, Ignacio, Diouldé Sylla, Marcel Placidi, et al.. (2020). Transition-Metal Oxides for Kesterite Solar Cells Developed on Transparent Substrates. ACS Applied Materials & Interfaces. 12(30). 33656–33669. 39 indexed citations
14.
Guc, Maxim, et al.. (2020). Synthesis and Crystal Structure Evolution of Co-Evaporated Cs2AgBiBr6 Thin Films upon Thermal Treatment. The Journal of Physical Chemistry C. 124(17). 9249–9255. 27 indexed citations
15.
Romanyuk, Yaroslav E., Stefan G. Haass, Sergio Giraldo, et al.. (2019). Doping and alloying of kesterites. Journal of Physics Energy. 1(4). 44004–44004. 140 indexed citations
16.
Pistor, Paul, et al.. (2018). Thermal stability and miscibility of co-evaporated methyl ammonium lead halide (MAPbX3, X = I, Br, Cl) thin films analysed by in situ X-ray diffraction. Journal of Materials Chemistry A. 6(24). 11496–11506. 49 indexed citations
17.
Fränzel, Wolfgang, et al.. (2018). Crystal Phases and Thermal Stability of Co-evaporated CsPbX3 (X = I, Br) Thin Films. The Journal of Physical Chemistry Letters. 9(16). 4808–4813. 107 indexed citations
18.
Giraldo, Sergio, Edgardo Saucedo, Markus Neuschitzer, et al.. (2017). How small amounts of Ge modify the formation pathways and crystallization of kesterites. Energy & Environmental Science. 11(3). 582–593. 186 indexed citations
19.
Guc, Maxim, Dimitrios Hariskos, L. Calvo‐Barrio, et al.. (2017). Resonant Raman scattering based approaches for the quantitative assessment of nanometric ZnMgO layers in high efficiency chalcogenide solar cells. Scientific Reports. 7(1). 1144–1144. 11 indexed citations
20.
Körbel, Sabine, et al.. (2016). Research Update: Stable single-phase Zn-rich Cu2ZnSnSe4 through In doping. APL Materials. 4(7). 11 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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