Multi-Component Oxide Thin Films and Heterostructures for Electronics: Growth Principles

Kazuhiro Endo; Noriaki Ikenaga; P. Badica

doi:10.4028/www.scientific.net/AST.77.209

Paper Titles

Influence of Hydrochloric Acid Concentrations on the Formation of AgCl-Doped Iron Oxide-Silica Coreshell Structures
p.184

Lectinhistochemistry Evaluation of Bone after Implantation with Macroporous Titanium Samples
p.190

Inorganic Nanoparticles for either Charge Storage or Memristance Modulation
p.196

Memory Effect of a Different Materials as Charge Storage Elements for Memory Applications
p.205

Multi-Component Oxide Thin Films and Heterostructures for Electronics: Growth Principles
p.209

Magnetoelectric Properties in Nickel Ferrite – Niobate Relaxor Bulk Composites
p.215

Magnetic Properties of the Bi₇Fe₃Ti₃O₂₁ Aurivillius Phase Doped with Samarium
p.220

Reflection of Electromagnetic Waves from Multiferroic TbMnO₃
p.225

Design and Optimization of Microwave Triangular Meta-Material Resonators in Coplanar Configuration
p.231

HomeAdvances in Science and TechnologyAdvances in Science and Technology Vol. 77Multi-Component Oxide Thin Films and...

Multi-Component Oxide Thin Films and Heterostructures for Electronics: Growth Principles

Abstract:

In the last years oxide materials for electronics show significant progress. However, many details regarding technology control of the properties have to be solved. For electronics, thin films and heterestructures are important taking advantage of integration and synergetic concepts leading to new types of devices and functionalities. It is notable that, while fabrication of new devices and materials showing new phenomena are booming, the growth principles and concepts are somehow developing slowly within this general trend. This is because in many cases, growth of materials is very personalized. Understanding of the bi-directional relationship between the general and particular principles deserves attention. The immediate benefit is that knowledge on growth for one material can be transferred to another one. In our work we have analyzed such relationships for some oxide multicomponent perovskites. Materials used in our examples are Bi-Sr-Ca-Cu-O and YBa₂Cu₃O₇, (Ca, Sr)CuO₂, (Ca, Ba)CuO₂ and Bi₄Ti₃O₁₂. Presented thin films or heterostructures are with c-axis and non-c-axis orientations and based on these examples we discuss some of the growth principles.