Arunava Gupta spends much of his time researching Condensed matter physics, Nanotechnology, Band gap, Raman spectroscopy and Nanocrystal. His Condensed matter physics research includes themes of Magnetoresistance, Nuclear magnetic resonance and Epitaxy. Arunava Gupta usually deals with Nanotechnology and limits it to topics linked to Ferroelectricity and Nanostructure, Hydrothermal circulation and Polarization density.
Arunava Gupta interconnects Colloid, Electronic structure, Wurtzite crystal structure and Copper in the investigation of issues within Band gap. His Raman spectroscopy research is multidisciplinary, incorporating elements of Tetragonal crystal system, Octahedron, Crystallography and Lattice constant. In his research on the topic of Nanocrystal, Thin film solar cell is strongly related with Crystal.
Arunava Gupta focuses on Condensed matter physics, Thin film, Nanotechnology, Epitaxy and Ferromagnetism. As a member of one scientific family, Arunava Gupta mostly works in the field of Condensed matter physics, focusing on Ferromagnetic resonance and, on occasion, Crystal structure. His studies deal with areas such as Crystallography, Optoelectronics, Substrate and Analytical chemistry as well as Thin film.
His research on Nanotechnology often connects related topics like Electrode. His study focuses on the intersection of Epitaxy and fields such as Nuclear magnetic resonance with connections in the field of Magnetic moment. Arunava Gupta works mostly in the field of Nanocrystal, limiting it down to topics relating to Band gap and, in certain cases, Wurtzite crystal structure and Spinel.
The scientist’s investigation covers issues in Thin film, Condensed matter physics, Crystallography, Nanotechnology and Nanocrystal. His research integrates issues of Photocatalysis, Yttrium iron garnet, Epitaxy, Optoelectronics and Spinel in his study of Thin film. Arunava Gupta studies Condensed matter physics, namely Conductance.
His study in Crystallography is interdisciplinary in nature, drawing from both Alloy and Hydrogen bond. His Nanotechnology study combines topics in areas such as Electrode and Electric double-layer capacitor. His Nanocrystal study combines topics from a wide range of disciplines, such as Reducing agent, Chalcogenide, Band gap and Nucleation.
His main research concerns Thin film, Nanotechnology, Crystallography, Condensed matter physics and Coordination polymer. The study incorporates disciplines such as Photocatalysis, Conductivity, Optoelectronics and Epitaxy in addition to Thin film. His biological study spans a wide range of topics, including Single crystal, Lattice constant, Crystal structure, Pulsed laser deposition and Ferromagnetic resonance.
His study in the fields of CZTS and Substrate under the domain of Nanotechnology overlaps with other disciplines such as Flexibility and Energy storage. His Crystallography research integrates issues from Chelation and Stereochemistry. Arunava Gupta combines subjects such as Excited state and Spinel with his study of Condensed matter physics.
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A spin triplet supercurrent through the half-metallic ferromagnet CrO2.
R. S. Keizer;S. T. B. Goennenwein;T. M. Klapwijk;G. Miao;G. Miao.
Quantitative study of the spin Hall magnetoresistance in ferromagnetic insulator/normal metal hybrids
Matthias Althammer;Sibylle Meyer;Hiroyasu Nakayama;Michael Schreier.
Physical Review B (2013)
Spin polarization in half-metals probed by femtosecond spin excitation.
Georg M. Müller;Jakob Walowski;Marija Djordjevic;Gou-Xing Miao.
Nature Materials (2009)
Synthesis of shape-controlled monodisperse wurtzite CuIn(x)Ga(1-x)S2 semiconductor nanocrystals with tunable band gap.
Yu-Hsiang A. Wang;Xiaoyan Zhang;Xiaoyan Zhang;Ningzhong Bao;Ningzhong Bao;Baoping Lin.
Journal of the American Chemical Society (2011)
Colossal magnetoresistance of 1 000 000‐fold magnitude achieved in the antiferromagnetic phase of La1−xCaxMnO3
Guo‐Qiang Gong;Chadwick Canedy;Gang Xiao;Jonathan Z. Sun.
Applied Physics Letters (1995)
Design scheme of new tetragonal Heusler compounds for spin-transfer torque applications and its experimental realization.
Jürgen Winterlik;Stanislav Chadov;Arunava Gupta;Vajiheh Alijani.
Advanced Materials (2012)
Raman spectroscopy of ordered double perovskite La 2 Co Mn O 6 thin films
M. N. Iliev;M. V. Abrashev;A. P. Litvinchuk;V. G. Hadjiev.
Physical Review B (2007)
Chemical tuning of the optical band gap in spinel ferrites: CoFe2O4 vs NiFe2O4
B. S. Holinsworth;D. Mazumdar;H. Sims;Q.-C. Sun.
Applied Physics Letters (2013)
Crystal phase-controlled synthesis of Cu2FeSnS4 nanocrystals with a band gap of around 1.5 eV.
Xiaoyan Zhang;Xiaoyan Zhang;Ningzhong Bao;Karthik Ramasamy;Yu-Hsiang A. Wang.
Chemical Communications (2012)
Theory of magnetoelectric effects in ferrite piezoelectric nanocomposites
V. M. Petrov;G. Srinivasan;M. I. Bichurin;A. Gupta.
Physical Review B (2007)
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