Xiaoli Tan

What is he best known for?

The fields of study he is best known for:

• Composite material
• Ceramic
• Thermodynamics

His primary areas of study are Condensed matter physics, Ferroelectricity, Piezoelectricity, Phase transition and Electric field. His study in Condensed matter physics is interdisciplinary in nature, drawing from both Tetragonal crystal system, Crystallography, Phase boundary and Phase diagram. In his study, which falls under the umbrella issue of Phase boundary, Relative permittivity and Lead zirconate titanate is strongly linked to Solid solution.

The various areas that Xiaoli Tan examines in his Ferroelectricity study include Mineralogy and Permittivity. His Piezoelectricity study incorporates themes from Transmission electron microscopy and Poling. As a part of the same scientific family, he mostly works in the field of Dielectric, focusing on Ceramic and, on occasion, Doping, Strain and Nanocomposite.

His most cited work include:

• Evolving morphotropic phase boundary in lead-free (Bi1/2Na1/2)TiO3–BaTiO3 piezoceramics (312 citations)
• Giant Strains in Non-Textured (Bi1/2Na1/2)TiO3-Based Lead-Free Ceramics (270 citations)
• Creation and Destruction of Morphotropic Phase Boundaries through Electrical Poling: A Case Study of Lead-Free (Bi1/2Na1/2)TiO3-BaTiO3 Piezoelectrics (257 citations)

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

The scientist’s investigation covers issues in Ferroelectricity, Condensed matter physics, Ceramic, Dielectric and Electric field. His Ferroelectricity research is multidisciplinary, relying on both Phase transition, Solid solution, Crystallography, Mineralogy and Piezoelectricity. His Piezoelectricity research incorporates elements of Coercivity and Poling.

His Condensed matter physics research also works with subjects such as

• Tetragonal crystal system and related Phase boundary,
• Nuclear magnetic resonance most often made with reference to Polarization. His Ceramic study combines topics from a wide range of disciplines, such as Polarization, Transmission electron microscopy, Ferroelectric ceramics and Analytical chemistry. The concepts of his Dielectric study are interwoven with issues in Perovskite, Nanocomposite and Atmospheric temperature range.

He most often published in these fields:

• Ferroelectricity (51.74%)
• Condensed matter physics (41.86%)
• Ceramic (37.21%)

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

• Condensed matter physics (41.86%)
• Ceramic (37.21%)
• Ferroelectricity (51.74%)

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

Xiaoli Tan mainly investigates Condensed matter physics, Ceramic, Ferroelectricity, Transmission electron microscopy and Electric field. Particularly relevant to Phase transition is his body of work in Condensed matter physics. His Phase transition study integrates concerns from other disciplines, such as Piezoelectricity, Synchrotron, Lattice, Tetragonal crystal system and Phase boundary.

His studies in Ceramic integrate themes in fields like Primitive cell, Ferroelectric ceramics and Dissipation. His Ferroelectricity study is focused on Dielectric in general. His Transmission electron microscopy research is multidisciplinary, incorporating perspectives in Electron diffraction, Diffraction and Lamellar structure.

Between 2018 and 2021, his most popular works were:

• Ultrahigh energy storage density lead-free multilayers by controlled electrical homogeneity (152 citations)
• Origin of the large electrostrain in BiFeO3-BaTiO3 based lead-free ceramics (35 citations)
• Ultrahigh piezoelectricity in lead-free piezoceramics by synergistic design (17 citations)

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

• Composite material
• Ceramic
• Thermodynamics

Xiaoli Tan focuses on Ceramic, Transmission electron microscopy, Condensed matter physics, Polarization and Ferroelectricity. In his study, Dissipation is inextricably linked to Dielectric, which falls within the broad field of Ceramic. In Transmission electron microscopy, he works on issues like Diffraction, which are connected to Doping, Homogeneity and Analytical chemistry.

His Polarization research integrates issues from Neutron diffraction and Electrocaloric effect. His work is dedicated to discovering how Neutron diffraction, Hysteresis are connected with Optoelectronics, Capacitor, Work and Antiferroelectricity and other disciplines. His work on Bismuth ferrite is typically connected to Electric field and Transition temperature as part of general Ferroelectricity study, connecting several disciplines of science.

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