Diamond quantum sensing at record high pressure up to 240 GPa

TL;DR

This paper demonstrates advanced diamond-based quantum sensing at pressures up to 240 GPa, enabling new insights into high-pressure phenomena like superconductivity and magnetic transitions in extreme conditions.

Contribution

It introduces a novel fabrication method for shallow NV centers that withstands ultra-high pressures, surpassing previous pressure limits for quantum sensing.

Findings

Record high pressure sensing up to 240 GPa

Detection of Meissner effect in titanium at 180 GPa

Enhanced NV center coherence and density under high pressure

Abstract

Quantum sensing utilizing nitrogen-vacancy (NV) centers in diamond has emerged as a transformative technology for probing magnetic phase transition1-4, evidencing Meissner effect of superconductors1,5-9, and visualizing stress distribution3,9 under extreme conditions. Recent development in NV configurations and hydrostatic environments have raised the operational pressures of NV centers to 140 GPa2,6,10,11, but substantial challenges remain in extending sensing capabilities into multi-megabar range, critical for research in hydrogen-rich superconductors like La-Sc-H ($T_{\text{c}}$ of 271-298 K at 195-266 GPa)12 and evolution of minerals near Earth's core13. Here we report the fabrication of shallow NV centers through ion implantation followed by high-pressure and high-temperature (HPHT) annealing, leading to increased density, improved coherence, and mitigated internal stresses, a pre-requisite for reducing their degradation under compression. This NV magnetometry enable breakthrough of pressure capabilities exceeding 240 GPa, constrained by structural integrity of the 50 um diamond anvils, suggesting that the untapped pressure limit may enable further advancements with smaller cutlets or more robust diamonds. We present compelling evidence of the Meissner effect and trapped flux at record-high pressure of 180 GPa for superconducting transition in elemental titanium (Ti) as benchmark, establishing a solid foundation for high-pressure magnetometry in exploring complex quantum phenomena at previously unreachable pressures.