Jungbae Yoon scite author profile

Recent advances in nanorobotic manipulation of ferromagnetic nanowires bring new avenues for applications in the biomedical area, such as targeted drug delivery, diagnostics or localized surgery. However, probing a single nanowire and monitoring its dynamics remains a challenge since it demands high precision sensing, high-resolution imaging, and stable operations in fluidic environments. Here, we report on a novel method of imaging and sensing magnetic fields from a single ferromagnetic nanowire with an atomic-scale sensor in diamond, i.e. diamond nitrogen-vacancy (NV) defect center. The distribution of static magnetic fields around a single Co nanowire is mapped out by spatially distributed NV centers and the obtained image is further compared with numerical simulation for quantitative analysis. DC field measurements such as continuous-wave ODMR and Ramsey sequence are used in the paper and sub Gauss level of field sensing is demonstrated. By imaging magnetic fields at a single nanowire level, this work represents an important step toward tracking and probing of ferromagnetic nanowires in biomedical applications.

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Atomic Scale Magnetic Sensing and Imaging Based on Diamond NV Centers

Lee¹,

Yoon²,

Lee³

2020

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The development of magnetic sensors simultaneously satisfying high magnetic sensitivity and high spatial resolution becomes more important in a wide range of fields including solid-state physics and life science. The nitrogen-vacancy (NV) center in diamond is a promising candidate to realize nanometer-scale magnetometry due to its excellent spin coherence properties, magnetic field sensitivity, atomic-scale size and versatile operation condition. Recent experiments successfully demonstrate the use of NV center in various sensing and imaging applications. In this chapter, we review the basic sensing mechanisms of the NV center and introduce imaging applications based on scanning magnetometry and wide field-of-view optics.

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Characterization and correction of the pulse width effects on quantum sensing experiments using solid-state spin qubits

Yoon

Kim

Lee

2023

Current Applied Physics

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Field averaging effect and estimation of minimum sample size in wide-field diamond microscopy

Yoon

Jugyeong

Lee

2023

J. Korean Phys. Soc.

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Jungbae Yoon

Precise temperature sensing with nanoscale thermal sensors based on diamond NV centers

Magnetic imaging of a single ferromagnetic nanowire using diamond atomic sensors

Atomic Scale Magnetic Sensing and Imaging Based on Diamond NV Centers

Characterization and correction of the pulse width effects on quantum sensing experiments using solid-state spin qubits

Field averaging effect and estimation of minimum sample size in wide-field diamond microscopy

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