# Diamond Sensor Technologies: From Multi Stimulus to Quantum

**Authors:** Pak San Yip, Tiqing Zhao, Kefan Guo, Wenjun Liang, Ruihan Xu, Yi Zhang, Yang Lu

PMC · DOI: 10.3390/mi17010118 · 2026-01-16

## TL;DR

This paper reviews diamond-based sensors, highlighting their unique properties and applications in mechanical, thermal, magnetic, and quantum sensing.

## Contribution

The paper provides a comprehensive overview of recent advancements and challenges in diamond sensor technologies for diverse and extreme applications.

## Key findings

- Diamond resonators operate at high frequencies with excellent quality factors due to CVD growth and etching techniques.
- Boron-doped diamond and NV centers enable high-performance thermal and magnetic sensing.
- Persistent challenges like grain boundary losses and surface stability are being addressed through surface chemistry and scalable CVD methods.

## Abstract

This review explores the variety of diamond-based sensing applications, emphasizing their material properties, such as high Young’s modulus, thermal conductivity, wide bandgap, chemical stability, and radiation hardness. These diamond properties give excellent performance in mechanical, pressure, thermal, magnetic, optoelectronic, radiation, biosensing, quantum, and other applications. In vibration sensing, nano/poly/single-crystal diamond resonators operate from MHz to GHz frequencies, with high quality factor via CVD growth, diamond-on-insulator techniques, and ICP etching. Pressure sensing uses boron-doped piezoresistive, as well as capacitive and Fabry–Pérot readouts. Thermal sensing merges NV nanothermometry, single-crystal resonant thermometers, and resistive/diode sensors. Magnetic detection offers FeGa/Ti/diamond heterostructures, complementing NV. Optoelectronic applications utilize DUV photodiodes and color centers. Radiation detectors benefit from diamond’s neutron conversion capability. Biosensing leverages boron-doped diamond and hydrogen-terminated SGFETs, as well as gas targets such as NO2/NH3/H2 via surface transfer doping and Pd Schottky/MIS. Imaging uses AFM/NV probes and boron-doped diamond tips. Persistent challenges, such as grain boundary losses in nanocrystalline diamond, limited diamond-on-insulator bonding yield, high temperature interface degradation, humidity-dependent gas transduction, stabilization of hydrogen termination, near-surface nitrogen-vacancy noise, and the cost of high-quality single-crystal diamond, are being addressed through interface and surface chemistry control, catalytic/dielectric stack engineering, photonic integration, and scalable chemical vapor deposition routes. These advances are enabling integrated, high-reliability diamond sensors for extreme and quantum-enhanced applications.

## Linked entities

- **Chemicals:** boron (PubChem CID 5462311), NO2 (PubChem CID 946), NH3 (PubChem CID 222), H2 (PubChem CID 783), Pd (PubChem CID 6956)

## Full-text entities

- **Chemicals:** boron (MESH:D001895), NH3 (MESH:D000641), FeGa (-), NO2 (MESH:D009585), Diamond (MESH:D018130), nitrogen (MESH:D009584), H2 (MESH:D006859), Ti (MESH:D014025), Pd (MESH:D010165)

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12844166/full.md

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Source: https://tomesphere.com/paper/PMC12844166