隧穿进入单个磁性原子：近藤共振的光谱学证据。

Tunneling into a single magnetic atom: spectroscopic evidence of the kondo resonance.

作者信息

Madhavan V, Chen W, Jamneala T, Crommie MF, Wingreen NS

机构信息

V. Madhavan, W. Chen, T. Jamneala, M. F. Crommie, Department of Physics, Boston University, 590 Commonwealth Avenue, Boston, MA 02215, USA. N. S. Wingreen, NEC Research Institute, 4 Independence Way, Princeton, NJ 08540, USA.

出版信息

Science. 1998 Apr 24;280(5363):567-9. doi: 10.1126/science.280.5363.567.

DOI:10.1126/science.280.5363.567

PMID:9554843

Abstract

The Kondo effect arises from the quantum mechanical interplay between the electrons of a host metal and a magnetic impurity and is predicted to result in local charge and spin variations around the magnetic impurity. A cryogenic scanning tunneling microscope was used to spatially resolve the electronic properties of individual magnetic atoms displaying the Kondo effect. Spectroscopic measurements performed on individual cobalt atoms on the surface of gold show an energetically narrow feature that is identified as the Kondo resonance-the predicted response of a Kondo impurity. Unexpected structure in the Kondo resonance is shown to arise from quantum mechanical interference between the d orbital and conduction electron channels for an electron tunneling into a magnetic atom in a metallic host.

摘要

近藤效应源于主体金属电子与磁性杂质之间的量子力学相互作用，预计会导致磁性杂质周围的局部电荷和自旋变化。使用低温扫描隧道显微镜在空间上解析显示近藤效应的单个磁性原子的电子特性。对金表面的单个钴原子进行的光谱测量显示出一个能量上狭窄的特征，该特征被确定为近藤共振——近藤杂质的预测响应。近藤共振中的意外结构被证明是由于电子隧穿进入金属主体中的磁性原子时，d轨道和传导电子通道之间的量子力学干涉而产生的。

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隧穿进入单个磁性原子：近藤共振的光谱学证据。

Tunneling into a single magnetic atom: spectroscopic evidence of the kondo resonance.

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