2020 - IEEE Fellow For development of X-ray scattering methods to understand electromechanical properties of ferroelectrics
Jacob L. Jones mainly investigates Ferroelectricity, Condensed matter physics, Piezoelectricity, Crystallography and Tetragonal crystal system. His Ferroelectricity research incorporates elements of Orthorhombic crystal system, Nanotechnology, Perovskite and Texture. His biological study spans a wide range of topics, including Ferroelasticity, Phase boundary, Ferroelectric ceramics and Dielectric.
His research integrates issues of Ceramic and Crystallite in his study of Piezoelectricity. His Crystallography research integrates issues from X-ray crystallography, Diffraction, Phase transition and Volume fraction. His study in Tetragonal crystal system is interdisciplinary in nature, drawing from both Optics and Monoclinic crystal system.
His primary areas of study are Ferroelectricity, Condensed matter physics, Piezoelectricity, Diffraction and Crystallography. He combines subjects such as Thin film and Composite material, Texture with his study of Ferroelectricity. His studies in Condensed matter physics integrate themes in fields like Tetragonal crystal system, Phase boundary, Ferroelectric ceramics and Crystallite.
His studies deal with areas such as Barium titanate, Ceramic and Mineralogy as well as Piezoelectricity. Jacob L. Jones does research in Diffraction, focusing on Neutron diffraction specifically. Analytical chemistry is closely connected to X-ray crystallography in his research, which is encompassed under the umbrella topic of Crystallography.
Jacob L. Jones mostly deals with Ferroelectricity, Condensed matter physics, Thin film, Composite material and Piezoelectricity. To a larger extent, he studies Dielectric with the aim of understanding Ferroelectricity. The study incorporates disciplines such as Tetragonal crystal system, Polarization and Diffraction in addition to Condensed matter physics.
His Thin film study integrates concerns from other disciplines, such as Optoelectronics, Annealing and Texture. His Composite material research is multidisciplinary, incorporating elements of Amorphous solid and Electrode. The Piezoelectricity study combines topics in areas such as Phase boundary and Ceramic.
His primary areas of investigation include Ferroelectricity, Condensed matter physics, Piezoelectricity, Dielectric and Phase transition. His Ferroelectricity study combines topics from a wide range of disciplines, such as Orthorhombic crystal system, Solid solution, Thin film, Ceramic and Hafnia. His research in Condensed matter physics intersects with topics in Tetragonal crystal system, Relaxor ferroelectric and Diffraction.
His Piezoelectricity research is under the purview of Composite material. The concepts of his Dielectric study are interwoven with issues in Layer and Single crystal. As a part of the same scientific family, Jacob L. Jones mostly works in the field of Phase transition, focusing on Phase boundary and, on occasion, Crystal structure, Crystallite, Scattering and Monoclinic crystal system.
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Christina M. Rost;Edward Sachet;Trent Borman;Ali Moballegh.
Nature Communications (2015)
Electric-field-induced phase transformation at a lead-free morphotropic phase boundary: Case study in a 93%(Bi0.5Na0.5)TiO3–7% BaTiO3 piezoelectric ceramic
John E. Daniels;Wook Jo;Jürgen Rödel;Jacob L. Jones.
Applied Physics Letters (2009)
Evolving morphotropic phase boundary in lead-free (Bi1/2Na1/2)TiO3–BaTiO3 piezoceramics
Wook Jo;John E. Daniels;Jacob L. Jones;Xiaoli Tan.
Journal of Applied Physics (2011)
Advances in Lead-Free Piezoelectric Materials for Sensors and Actuators
Elena Aksel;Jacob L. Jones.
Monoclinic crystal structure of polycrystalline Na0.5Bi0.5TiO3
Elena Aksel;Jennifer S. Forrester;Jacob L. Jones;Pam A. Thomas.
Applied Physics Letters (2011)
Origins of Electro‐Mechanical Coupling in Polycrystalline Ferroelectrics During Subcoercive Electrical Loading
Abhijit Pramanick;Abhijit Pramanick;Dragan Damjanovic;John E. Daniels;John E. Daniels;Juan C. Nino.
Journal of the American Ceramic Society (2011)
A comprehensive study on the structural evolution of HfO2 thin films doped with various dopants
M. H. Park;T. Schenk;C. M. Fancher;E. D. Grimley.
Journal of Materials Chemistry C (2017)
BiFeO3 Ceramics: Processing, Electrical, and Electromechanical Properties
Tadej Rojac;Andreja Bencan;Barbara Malic;Goknur Tutuncu.
Journal of the American Ceramic Society (2014)
Electric-field-induced phase-change behavior in (Bi0.5Na0.5)TiO3-BaTiO3-(K0.5Na0.5)NbO3: A combinatorial investigation
John E. Daniels;Wook Jo;Jürgen Rödel;Veijo Honkimäki.
Acta Materialia (2010)
Correlation Between Oxygen Vacancy, Microstrain, and Cation Distribution in Lithium-Excess Layered Oxides During the First Electrochemical Cycle
Christopher R. Fell;Danna Qian;Kyler J. Carroll;Miaofang Chi.
Chemistry of Materials (2013)
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