Pulsed magnetic field gradient on a tip for nanoscale imaging of spins

TL;DR

This paper introduces a switchable nanoscale magnetic field gradient device using a current-carrying tip to enable high-resolution magnetic resonance imaging of single spins with potential for 1 nm electron spin mapping.

Contribution

It presents a novel, controllable magnetic field gradient device integrated with a diamond NV center sensor for enhanced nanoMRI capabilities.

Findings

Achieved magnetic field gradients up to 1 μT/nm.

Demonstrated high-precision positioning and switching of the gradient device.

Showed spatially dependent Rabi power modification near the metallic tip.

Abstract

Nanoscale magnetic resonance imaging (nanoMRI) aims at obtaining structure at the single molecule level. Most of the techniques for effecting a nanoMRI gradient use small permanent magnets. Here, we present a switchable magnetic field gradient on a tip, which is designed to provide a local and controllable magnetic field with a high gradient on the nanometer scale. We incorporate the gradient field with a nanoscale magnetic resonance sensor, a single nitrogen-vacancy (NV) center in diamond, to provide high-resolution magnetic resonance imaging. The device is a metal microwire deposited along a quartz tip, with the current flowing along the tip inducing a magnetic field around its apex. This field can be manipulated throughout a measurement by controlling the current along the wire. We achieved gradients as high as 1 $\mathrm{\mu}\text{T/nm}$ at fields weaker than 200 $\mathrm{\mu}\text{T}$. Such a gradient can facilitate electron spin mapping with 1 nm resolution using single NV sensors, allowing for nanoscale imaging of electrons. The ability to switch the current on and off and to position the device with high precision overcomes limitations such as limited emitter contrast and the flexibility in sample preparation. Moreover, we show that proximity of the metallic tip to the sensor modifies the Rabi power in a spatially dependent manner, providing regions with enhanced ($\times$3.5) and decreased Rabi power. This spatial gradient, induced by the tip, offers the opportunity for selective pulses on nearby spin species where the same microwave power will result in different spin manipulation characteristics.