Apparent delocalisation of the current flow in metallic wires observed with diamond nitrogen-vacancy magnetometry

TL;DR

This study uses diamond nitrogen-vacancy magnetometry to analyze magnetic fields in metallic micro-wires, revealing unexpected current flow patterns that suggest current spreads into the diamond substrate, challenging classical assumptions.

Contribution

The paper introduces a two-channel current model that explains anomalous magnetic field measurements, indicating current flow in the diamond substrate rather than solely in the metallic wire.

Findings

Measured magnetic fields deviate from predictions based on Ampere's law.

A two-channel current model explains the data and aligns with classical electrodynamics.

Most current appears to flow in the diamond substrate, not just in the metal wire.

Abstract

We report on a quantitative analysis of the magnetic field generated by a continuous current running in metallic micro-wires fabricated on an electrically insulating diamond substrate. A layer of nitrogen-vacancy (NV) centres engineered near the diamond surface is employed to obtain spatial maps of the vector magnetic field, by measuring Zeeman shifts through optically-detected magnetic resonance spectroscopy. The in-plane magnetic field (i.e. parallel to the diamond surface) is found to be significantly weaker than predicted, while the out-of-plane field also exhibits an unexpected modulation. We show that the measured magnetic field is incompatible with Ampere's circuital law or Gauss's law for magnetism when we assume that the current is confined to the metal, independent of the details of the current density. This result was reproduced in several diamond samples, with a measured deviation from Ampere's law by as much as 94(6)\%. To resolve this apparent magnetic anomaly, we introduce a generalised description whereby the current is allowed to flow both above the NV sensing layer (including in the metallic wire) and below the NV layer (i.e. in the diamond). Inversion of the Biot-Savart law within this two-channel description leads to a unique solution for the two current densities, which completely explains the data, is consistent with the laws of classical electrodynamics and indicates a total NV-measured current that closely matches the electrically-measured current. However, this description also leads to the surprising conclusion that in certain circumstances the majority of the current appears to flow in the diamond substrate rather than in the metallic wire, and to spread laterally in the diamond by several micrometres away from the wire. No electrical conduction was observed between nearby test wires, ruling out a conventional conductivity effect. [...]