Electrically driven spin resonance of 4f electrons in a single atom on a surface

Stefano Reale; Jiyoon Hwang; Jeongmin Oh; Harald Brune; Andreas J. Heinrich; Fabio Donati; Yujeong Bae

doi:10.1038/s41467-024-49447-y

Electrically driven spin resonance of 4f electrons in a single atom on a surface

Stefano Reale, Jiyoon Hwang, Jeongmin Oh, Harald Brune, Andreas J. Heinrich, Fabio Donati, Yujeong Bae

Department of Physics

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

A pivotal challenge in quantum technologies lies in reconciling long coherence times with efficient manipulation of the quantum states of a system. Lanthanide atoms, with their well-localized 4f electrons, emerge as a promising solution to this dilemma if provided with a rational design for manipulation and detection. Here we construct tailored spin structures to perform electron spin resonance on a single lanthanide atom using a scanning tunneling microscope. A magnetically coupled structure made of an erbium and a titanium atom enables us to both drive the erbium’s 4f electron spins and indirectly probe them through the titanium’s 3d electrons. The erbium spin states exhibit an extended spin relaxation time and a higher driving efficiency compared to 3d atoms with spin ½ in similarly coupled structures. Our work provides a new approach to accessing highly protected spin states, enabling their coherent control in an all-electric fashion.

Original language	English
Article number	5289
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-49447-y
State	Published - Dec 2024

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© The Author(s) 2024.

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Cite this

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abstract = "A pivotal challenge in quantum technologies lies in reconciling long coherence times with efficient manipulation of the quantum states of a system. Lanthanide atoms, with their well-localized 4f electrons, emerge as a promising solution to this dilemma if provided with a rational design for manipulation and detection. Here we construct tailored spin structures to perform electron spin resonance on a single lanthanide atom using a scanning tunneling microscope. A magnetically coupled structure made of an erbium and a titanium atom enables us to both drive the erbium{\textquoteright}s 4f electron spins and indirectly probe them through the titanium{\textquoteright}s 3d electrons. The erbium spin states exhibit an extended spin relaxation time and a higher driving efficiency compared to 3d atoms with spin ½ in similarly coupled structures. Our work provides a new approach to accessing highly protected spin states, enabling their coherent control in an all-electric fashion.",

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AU - Reale, Stefano

AU - Hwang, Jiyoon

AU - Oh, Jeongmin

AU - Brune, Harald

AU - Heinrich, Andreas J.

AU - Donati, Fabio

AU - Bae, Yujeong

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Electrically driven spin resonance of 4f electrons in a single atom on a surface

Abstract

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