金属-绝缘体复合材料巨霍尔效应的起源

J. Sonntag
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引用次数: 3

摘要

在金属-绝缘子过渡附近,金属-绝缘子复合材料(M-I复合材料)的霍尔系数R可达纯金属的104倍,称为巨人霍尔效应。利用[1]-[2]中形成的相分离合金的物理模型,我们得出巨人霍尔效应是由电子从金属相转移到占据表面态的绝缘相引起的。这些表面状态是M-I复合材料典型的颗粒结构的原因。这种电子转移可以用[1][2]来描述,前提是在成膜过程中不发生远距离扩散(n是A相中的电子密度)。uA和uB是A相(金属相)和B相(绝缘体相)的体积分数。推导了复合材料R的计算公式,并将其应用于Cu1-y(SiO2)y和Ni1-y(SiO2)y颗粒膜的实验数据。
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The Origin of the Giant Hall Effect in Metal-Insulator Composites
Near the metal-insulator transition, the Hall coefficient R of metal-insulator composites (M-I composite) can be up to 104 times larger than that in the pure metal called Giant Hall effect. Applying the physical model for alloys with phase separation developed in [1] [2], we conclude that the Giant Hall effect is caused by an electron transfer away from the metallic phase to the insulating phase occupying surface states. These surface states are the reason for the granular structure typical for M-I composites. This electron transfer can be described by [1] [2], provided that long-range diffusion does not happen during film production (n is the electron density in the phase A. uA and uB are the volume fractions of the phase A (metallic phase) and phase B (insulator phase). β is a measure for the average potential difference between the phases A and B). A formula for calculation of R of composites is derived and applied to experimental data of granular Cu1-y(SiO2)y and Ni1-y(SiO2)y films.
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来源期刊
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