Gerold A. Schneider bridges between several scientific fields such as Crystallite and Microstructure in his study of Metallurgy. His work in Crystallite is not limited to one particular discipline; it also encompasses Metallurgy. His work blends Microstructure and Ceramic studies together. His study deals with a combination of Ceramic and Thermal shock. His Nanotechnology research spans across into subjects like Nanoscopic scale and Nanoindentation. In his research, Gerold A. Schneider undertakes multidisciplinary study on Nanoscopic scale and Nanotechnology. Other disciplines of study, such as Piezoelectricity and Ferroelectricity, are mixed together with his Dielectric studies. He integrates Piezoelectricity and Dielectric in his research. Gerold A. Schneider combines topics linked to Scanning electron microscope with his work on Composite material.
His research is interdisciplinary, bridging the disciplines of Fracture mechanics and Composite material. Ceramic is closely attributed to Metallurgy in his research. His work in Metallurgy is not limited to one particular discipline; it also encompasses Ceramic. Optoelectronics and Optics are two areas of study in which Gerold A. Schneider engages in interdisciplinary research. In his work, Gerold A. Schneider performs multidisciplinary research in Optics and Optoelectronics. In his works, Gerold A. Schneider conducts interdisciplinary research on Nanotechnology and Nanoparticle. Gerold A. Schneider combines Nanoparticle and Nanotechnology in his research. As part of his studies on Organic chemistry, Gerold A. Schneider often connects relevant subjects like Phase (matter). Phase (matter) and Organic chemistry are commonly linked in his work.
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Nanoscale reconstruction of surface crystallography from three-dimensional polarization distribution in ferroelectric barium-titanate ceramics
L. M. Eng;H.-J. Güntherodt;G. A. Schneider;U. Köpke.
Applied Physics Letters (1999)
High-resolution characterization of piezoelectric ceramics by ultrasonic scanning force microscopy techniques
U Rabe;M Kopycinska;S Hirsekorn;J Muñoz Saldaña.
Journal of Physics D (2002)
The fracture behaviour of dental enamel.
Sabine Bechtle;Stefan Habelitz;Arndt Klocke;Theo Fett.
Modeling and measurement of surface displacements in BaTiO3 bulk material in piezoresponse force microscopy
F. Felten;G. A. Schneider;J. Muñoz Saldaña;S. V. Kalinin.
Journal of Applied Physics (2004)
On the mechanical properties of hierarchically structured biological materials
Sabine Bechtle;Siang Fung Ang;Gerold A. Schneider.
Influence of Electric Field and Mechanical Stresses on the Fracture of Ferroelectrics
Gerold A. Schneider.
Annual Review of Materials Research (2007)
Size-dependence of the dielectric breakdown strength from nano- to millimeter scale
Claudia Neusel;Gerold A. Schneider.
Journal of The Mechanics and Physics of Solids (2014)
Organically linked iron oxide nanoparticle supercrystals with exceptional isotropic mechanical properties
Axel Dreyer;Artur Feld;Andreas Kornowski;Ezgi D. Yilmaz.
Nature Materials (2016)
A Mechanical Aging Mechanism in Lithium-Ion Batteries
T. Waldmann;S. Gorse;T. Samtleben;G. Schneider.
Journal of The Electrochemical Society (2014)
Influence of the electric field on vickers indentation crack growth in BaTiO3
G.A. Schneider;V. Heyer.
Journal of The European Ceramic Society (1999)
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