Epitaxial growth controlled tailoring of Metal-Insulator (MI) Transition properties of rare earth correlated oxides

The 9th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS) Pub Date : 2014-04-13 DOI:10.1109/NEMS.2014.6908783

Asif Iqbal, S. Khan, Nafiz Ur Rahman, T. Faraz

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Abstract

Strongly correlated electron devices using Metal Insulator Transition (MIT) Oxides are prospective alternatives along the new generation of high speed devices based on novel mechanisms. Taking the advantages of correlated electrons which are capable of forming a variety of electronic phases, MIT Oxides and Phase Change Materials (PCM) are treated as the frontiers of emergent device research. With the prospect of downsizing devices to the nanoscale regime, benefits over conventional semiconductor devices are attained. Aided by recent advances in fabrication technology, considerable improvements have been achieved to tailor the Metal-Insulator (MI) transition properties of MIT Oxides. In this study, the tailoring of MI transition properties for a particular group of MIT Oxides, namely the transition metal perovskite oxides of RNiO3 family are studied on the epitaxial platform. Finally, antiferromagnetism characteristics and anonymous resistivity inherent within those oxides are studied.

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稀土相关氧化物金属绝缘体(MI)跃迁特性的外延生长控制裁剪

利用金属绝缘体跃迁(MIT)氧化物的强相关电子器件是基于新机制的新一代高速器件的潜在替代品。利用相关电子能够形成多种电子相的优势，MIT氧化物和相变材料(PCM)被视为新兴器件研究的前沿。随着器件缩小到纳米级的前景，获得了优于传统半导体器件的优点。在最近制造技术进步的帮助下，已经取得了相当大的改进，以定制MIT氧化物的金属-绝缘体(MI)过渡特性。本研究在外延平台上研究了一类特殊的MIT氧化物，即RNiO3族过渡金属钙钛矿氧化物的MI跃迁特性。最后，研究了这些氧化物的反铁磁特性和匿名电阻率。

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The 9th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS)

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