His primary scientific interests are in Transmission electron microscopy, Condensed matter physics, Thin film, Optics and High-resolution transmission electron microscopy. His Transmission electron microscopy research entails a greater understanding of Nanotechnology. His biological study spans a wide range of topics, including Crystallography, Chemical vapor deposition, Epitaxy and Ferroelectricity.
His research integrates issues of Microstructure, Grain boundary, Silicon and Dislocation in his study of Epitaxy. His research investigates the connection between Ferroelectricity and topics such as Heterojunction that intersect with problems in Electrical resistance and conductance. His studies in Thin film integrate themes in fields like Oxide, Optoelectronics, Dielectric, Analytical chemistry and Thermal stability.
Chun-Lin Jia mainly focuses on Thin film, Condensed matter physics, Epitaxy, Transmission electron microscopy and Optoelectronics. The concepts of his Thin film study are interwoven with issues in Crystallography, Microstructure, Substrate and Analytical chemistry. His work in Condensed matter physics addresses subjects such as Ferroelectricity, which are connected to disciplines such as Electrostriction.
His Epitaxy research incorporates themes from Electron microscope, Perovskite, Heterojunction and Sputter deposition. The study incorporates disciplines such as Nanoscopic scale, Spherical aberration and Strontium titanate in addition to Transmission electron microscopy. His Optoelectronics research incorporates elements of Bending, Superconductivity and Nanopillar.
His main research concerns Condensed matter physics, Optoelectronics, Thin film, Ferroelectricity and Epitaxy. His work deals with themes such as Photonics, Antiferroelectricity and Density functional theory, which intersect with Condensed matter physics. His Optoelectronics research includes elements of Bending, Nanopillar and Transmission electron microscopy.
His Thin film study integrates concerns from other disciplines, such as Composite material, Dielectric and Capacitor. His Ferroelectricity research is multidisciplinary, relying on both Polarization, Superconductivity and Doping. Chun-Lin Jia interconnects Electron microscope, Spinel, Substrate and Lithium ferrite in the investigation of issues within Epitaxy.
Chun-Lin Jia focuses on Dielectric, Ferroelectricity, Optoelectronics, Thin film and Energy storage. His Ferroelectricity study combines topics from a wide range of disciplines, such as Phase and Dopant. His studies deal with areas such as Ferromagnetism, Nanopillar, Isotropic etching and Saturation as well as Optoelectronics.
The Thin film study combines topics in areas such as Power electronics and Engineering physics. His study in Thermal stability is interdisciplinary in nature, drawing from both Film capacitor and Composite material. As part of his studies on Capacitor, he often connects relevant areas like Condensed matter physics.
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Atomic-resolution imaging of oxygen in perovskite ceramics.
C. L. Jia;M. Lentzen;K. Urban.
Atomic-scale study of electric dipoles near charged and uncharged domain walls in ferroelectric films
Chun-Lin Jia;Shao-Bo Mi;Knut Urban;Ionela Vrejoiu.
Nature Materials (2008)
Direct observation of continuous electric dipole rotation in flux-closure domains in ferroelectric pb(zr,ti)o3
Chun-Lin Jia;Knut W. Urban;Marin Alexe;Dietrich Hesse.
Unit-cell scale mapping of ferroelectricity and tetragonality in epitaxial ultrathin ferroelectric films
Chun-Lin Jia;Valanoor Nagarajan;Jia-Qing He;Lothar Houben.
Nature Materials (2007)
Atomic-resolution measurement of oxygen concentration in oxide materials.
C. L. Jia;K. Urban.
High-resolution imaging with an aberration-corrected transmission electron microscope.
M. Lentzen;B. Jahnen;C.L. Jia;A. Thust.
Oxygen octahedron reconstruction in the SrTiO 3 /LaAlO 3 heterointerfaces investigated using aberration-corrected ultrahigh-resolution transmission electron microscopy
C. L. Jia;S. B. Mi;M. Faley;U. Poppe.
Physical Review B (2009)
Ultrahigh Energy Storage Performance of Lead-Free Oxide Multilayer Film Capacitors via Interface Engineering.
Zixiong Sun;Chunrui Ma;Ming Liu;Jin Cui.
Advanced Materials (2017)
Microstructure of epitaxial YBa2Cu3O7 films on step-edge SrTiO3 substrates
C.L. Jia;B. Kabius;K. Urban;K. Herrman.
Physica C-superconductivity and Its Applications (1991)
Twinning-like lattice reorientation without a crystallographic twinning plane
Bo-Yu Liu;Jian Wang;Bin Li;Lu-De Lu.
Nature Communications (2014)
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