锰钢导线中新出现的输运行为

2008 9th International Conference on Solid-State and Integrated-Circuit Technology Pub Date : 2008-12-30 DOI:10.1109/ICSICT.2008.4734602

T. Ward, Jian Shen

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引用次数: 0

摘要

凝聚态物理中两个最热门的研究领域是复杂性和纳米尺度物理。有趣的是，这两个领域几乎没有重叠，因为大多数纳米物理研究工作都是使用金属或半导体等“简单”材料进行的，而不是使用过渡金属氧化物等复杂材料。然而，由于强烈的电子相关性，正是过渡金属氧化物最有可能导致在空间限制下观察到惊人的新现象。我们将使用钙钛矿锰矿作为模型系统来演示空间约束如何显著影响其输运和磁性能。新出现的磁性和输运行为可能与局限几何条件下的电子相分离有关。一些新的性质，如磁电阻的超锐跳变和可重入金属-绝缘体跃迁，可能对基于氧化物的新型器件的制造产生重大影响。

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Emerging transport behavior in manganites wires

The two hottest areas of research in condensed matter physics are complexity and nanoscale physics. Interestingly, these two areas have little overlap as most of the nanophysics research work is conducted using ¿simple¿ materials of metals or semiconductors instead of complex materials such as transition metal oxides. However, due to the strong electronic correlation, it is exactly the transition metal oxides that will most likely lead to observations of striking new phenomena under spatial confinement. We will use perovskite manganites as model systems to demonstrate how spatial confinement can dramatically affect their transport and magnetic properties. The emerging magnetic and transport behavior is likely associated with the electronic phase separation under confined geometry in the manganites. Some of the new properties such as ultrasharp jumps of magnetoresistance and reentrant metal-insulator transition may have significant impact on fabricating oxides-based novel devices.

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2008 9th International Conference on Solid-State and Integrated-Circuit Technology

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