Pavel A. Troshin mainly focuses on Fullerene, Organic chemistry, Organic solar cell, Photovoltaic system and Nanotechnology. The concepts of his Fullerene study are interwoven with issues in Reactivity, Chemical engineering, Polymer chemistry and Solubility. His Organic solar cell study is concerned with the field of Polymer as a whole.
As part of his studies on Photovoltaic system, Pavel A. Troshin often connects relevant areas like Perovskite. In his study, Hybrid material, Energy conversion efficiency and Solar cell is inextricably linked to Halide, which falls within the broad field of Perovskite. His Nanotechnology study combines topics from a wide range of disciplines, such as Field-effect transistor, Transistor, Organic electronics and Optical memory.
Pavel A. Troshin mainly focuses on Fullerene, Organic solar cell, Chemical engineering, Photochemistry and Polymer. His research on Fullerene concerns the broader Organic chemistry. The Organic solar cell study combines topics in areas such as Conjugated system, Acceptor and Polymer solar cell.
He works mostly in the field of Chemical engineering, limiting it down to topics relating to Cathode and, in certain cases, Lithium and Ion. His research in Photochemistry intersects with topics in Spectroscopy and Molecule. Pavel A. Troshin combines subjects such as Thiophene, Optoelectronics and Carbazole with his study of Polymer.
Pavel A. Troshin mostly deals with Chemical engineering, Perovskite, Polymer, Organic solar cell and Conjugated system. Pavel A. Troshin has researched Chemical engineering in several fields, including Polyimide, Electrolyte, Cathode, Anode and Lithium. His Perovskite research incorporates themes from Oxide, Thin film, Layer, Halide and Coating.
His Polymer research includes themes of Optoelectronics and Energy conversion efficiency. Pavel A. Troshin interconnects Thiophene, Photochemistry, Nanotechnology and Polymer solar cell in the investigation of issues within Organic solar cell. His Photochemistry study incorporates themes from Fullerene, Quenching, Fluorescence, Singlet oxygen and Molecule.
Pavel A. Troshin mainly investigates Perovskite, Chemical engineering, Polymer, Lithium and Organic solar cell. His work carried out in the field of Perovskite brings together such families of science as Halide, Photovoltaic system, Passivation and X-ray photoelectron spectroscopy. His studies in Chemical engineering integrate themes in fields like Microscopy, Electrochemical degradation, Metal, Electrochemical decomposition and Coating.
His Optoelectronics research extends to the thematically linked field of Polymer. His Organic solar cell research focuses on subjects like Conjugated system, which are linked to Nanotechnology. His work deals with themes such as Thin film and Fullerene, which intersect with Naphthalene.
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Material Solubility-Photovoltaic Performance Relationship in the Design of Novel Fullerene Derivatives for Bulk Heterojunction Solar Cells
Pavel A. Troshin;Harald Hoppe;Joachim Renz;Martin Egginger.
Advanced Functional Materials (2009)
Indigo - a natural pigment for high performance ambipolar organic field effect transistors and circuits
Mihai Irimia-Vladu;Eric D. Glowacki;Pavel A. Troshin;Guenther Schwabegger.
Advanced Materials (2012)
Biocompatible and Biodegradable Materials for Organic Field‐Effect Transistors
Mihai Irimia-Vladu;Pavel A. Troshin;Melanie Reisinger;Lyuba Shmygleva.
Advanced Functional Materials (2010)
C60F18, a Flattened Fullerene: Alias a Hexa-Substituted Benzene
Ivan S. Neretin;Konstantin A. Lyssenko;Mikhail Yu. Antipin;Yuri L. Slovokhotov.
Angewandte Chemie (2000)
Highly Efficient All-Inorganic Planar Heterojunction Perovskite Solar Cells Produced by Thermal Coevaporation of CsI and PbI2.
Lyubov A. Frolova;Denis V. Anokhin;Alexey A. Piryazev;Sergey Yu. Luchkin.
Journal of Physical Chemistry Letters (2017)
Consensus statement for stability assessment and reporting for perovskite photovoltaics based on ISOS procedures
Mark V. Khenkin;Mark V. Khenkin;Eugene A. Katz;Antonio Abate;Giorgio Bardizza.
Nature Energy (2020)
Isolation of two seven-membered ring C58 fullerene derivatives: C58F17CF3 and C58F18.
Pavel A. Troshin;Pavel A. Troshin;Pavel A. Troshin;Anthony G. Avent;Anthony G. Avent;Anthony G. Avent;Adam D. Darwish;Adam D. Darwish;Adam D. Darwish;Natalia Martsinovich;Natalia Martsinovich;Natalia Martsinovich.
Synthesis and Structure of the Highly Chlorinated Fullerene C60Cl30 with a Drum‐Shaped Carbon Cage
Pavel A. Troshin;Rimma N. Lyubovskaya;Ilya N. Ioffe;Natalia B. Shustova.
Angewandte Chemie (2005)
Probing the Intrinsic Thermal and Photochemical Stability of Hybrid and Inorganic Lead Halide Perovskites
Azat F. Akbulatov;Sergey Yu. Luchkin;Lyubov A. Frolova;Nadezhda N. Dremova.
Journal of Physical Chemistry Letters (2017)
The chemical origin of the p-type and n-type doping effects in the hybrid methylammonium–lead iodide (MAPbI3) perovskite solar cells
Lyubov A. Frolova;Nadezhda N. Dremova;Pavel A. Troshin.
Chemical Communications (2015)
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