Jan Seidel

What is he best known for?

The fields of study he is best known for:

• Semiconductor
• Condensed matter physics
• Optics

His primary areas of study are Ferroelectricity, Condensed matter physics, Nanotechnology, Multiferroics and Domain wall. His studies in Ferroelectricity integrate themes in fields like Piezoelectricity, Energy transformation, Thermoelectric effect and Band gap. The concepts of his Band gap study are interwoven with issues in Photovoltaics, Anomalous photovoltaic effect, Photovoltaic effect, Semiconductor and Voltage.

His studies deal with areas such as Magnet and Electrical resistivity and conductivity as well as Condensed matter physics. His Magnet research is multidisciplinary, incorporating elements of Magnetic domain, Ferromagnetism, Microelectronics, Nanoelectronics and Electron holography. His research in Nanotechnology intersects with topics in Tetragonal crystal system and Optoelectronics, Doping.

His most cited work include:

• Above-bandgap voltages from ferroelectric photovoltaic devices (980 citations)
• Above-bandgap voltages from ferroelectric photovoltaic devices (980 citations)
• Conduction at domain walls in oxide multiferroics (907 citations)

What are the main themes of his work throughout his whole career to date?

Condensed matter physics, Ferroelectricity, Nanotechnology, Multiferroics and Thin film are his primary areas of study. Jan Seidel combines subjects such as Bismuth ferrite and Anisotropy with his study of Condensed matter physics. His Ferroelectricity research is multidisciplinary, incorporating perspectives in Domain wall, Superconductivity, Nanoelectronics and Piezoelectricity.

His Nanotechnology study incorporates themes from Thermal conduction and Conductive atomic force microscopy. As a member of one scientific family, Jan Seidel mostly works in the field of Multiferroics, focusing on Raman spectroscopy and, on occasion, Phonon and Néel temperature. His study explores the link between Thin film and topics such as Epitaxy that cross with problems in Electronic properties.

He most often published in these fields:

• Condensed matter physics (61.97%)
• Ferroelectricity (46.01%)
• Nanotechnology (37.56%)

What were the highlights of his more recent work (between 2018-2021)?

• Optoelectronics (19.25%)
• Ferroelectricity (46.01%)
• Perovskite (11.27%)

In recent papers he was focusing on the following fields of study:

Jan Seidel focuses on Optoelectronics, Ferroelectricity, Perovskite, Chemical engineering and Thin film. His study in Optoelectronics is interdisciplinary in nature, drawing from both Halide and Grain boundary. His work deals with themes such as Nanoelectronics, Scanning probe microscopy and Current, which intersect with Ferroelectricity.

The various areas that Jan Seidel examines in his Nanoelectronics study include Domain wall, Topological defect and Multiferroics. Jan Seidel combines subjects such as Magnetic domain, Magnetism, Condensed matter physics, Stoichiometry and Oxygen transport with his study of Thin film. Spin-½ is the focus of his Condensed matter physics research.

Between 2018 and 2021, his most popular works were:

• Mutual Insight on Ferroelectrics and Hybrid Halide Perovskites: A Platform for Future Multifunctional Energy Conversion. (559 citations)
• A room-temperature ferroelectric semimetal. (36 citations)
• Cd-Free Cu2ZnSnS4 solar cell with an efficiency greater than 10% enabled by Al2O3 passivation layers (25 citations)

In his most recent research, the most cited papers focused on:

• Semiconductor
• Condensed matter physics
• Optics

Jan Seidel mostly deals with Ferroelectricity, Perovskite, Nanoelectronics, Multiferroics and Kelvin probe force microscope. His study in the field of Pyroelectricity is also linked to topics like Energy storage. Jan Seidel interconnects Chemical physics, Solution process and Light intensity in the investigation of issues within Perovskite.

Nanoelectronics is closely attributed to Condensed matter physics in his work. The concepts of his Condensed matter physics study are interwoven with issues in Domain wall, Conformational change and Piezoresponse force microscopy. His Multiferroics study incorporates themes from Thin film, Neutron diffraction and Topological defect.

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