December 2023 – December 2027

Projet ANR-23-QUAC-0006 (ANR)


The ambition of SINFONIA is to develop a sovereign value chain of novel NV-sensor, from the growth of quantum grade diamond layers, to their shaping into flat or nanostructured membranes with high NV- center concentration, and to their integration into industrial-grade non-destructive testing magnetometer and into a neuronal electrical activity imaging sensor.

Context

While advances in the quantum manipulation of cold atoms have already been translated into sensors with high industrial impacts (e.g. gravimeter applied to hydrology or civil engineering, already commercialized; or inertial sensors, in advanced stage of development), solid-state quantum systems-based sensors are still in their infancy, despite remarkable assets. Among these systems, the NV- center in diamond has emerged as a highly polyvalent sensor of physical parameters including magnetic and electric fields, voltage, temperature…at scales ranging from nano- to millimeters, then offering imaging capabilities, with outstanding sensitivity performances. The rapid development of NV-diamond-based sensors stems from their room temperature operation, optical preparation and interrogation of the quantum state, and the robustness of the diamond material. However, beside commercial scanning magnetometers and sensitive device for bioanalytical assays, technological transfers of other NV-sensing modalities are still hampered by sub-optimal micro- and nano-processing of quantum grade diamond.

Goals

The ambition of SINFONIA is to develop a sovereign value chain of novel NV-sensor, from the growth of quantum grade diamond layers, to their shaping into flat or nanostructured membranes with high NV- center concentration, and to their integration into industrial-grade non-destructive testing magnetometer and into a neuronal electrical activity imaging sensor. An original microwave-free sensing method, very recently introduced by one partner, will also be implemented for all optical magnetic field stabilization at zero-field. The project relies on cutting edge facilities recently upgraded through the Equipex+ e-Diamant, and internationally recognized know-how in quantum grade diamond fabrication. The consortium gathers all required expertise in nanotechnologies, NV-fundamental physics, applied metrology and neuron electrophysiology to address the groundbreaking applications envisioned. The participation of two industrial partners will ensure rapid commercialization of viable products, and academic laboratory partners will benefit from quantum-grade processed material to test novel sensing concepts and devices, with mutual benefit for both parties, as these fundamental researches pave the way to the next-generation of NV-diamond sensors.

Scientific production

11 documents

Journal articles

  • Baptiste Vindolet, Benjamin Ducharne, Hoai Nam Nguyen, Xavier Mougenot, Christophe Gallais, et al.. High-resolution non-destructive detection of grinding burns with NV diamond quantum magnetometer. NDT & E International, 2025, 155, pp.103439. ⟨10.1016/j.ndteint.2025.103439⟩. ⟨hal-05594193⟩

Conference papers

  • Thiziri Ben Yahia, Avishek Ghosh, Vianney Mille, Walid Mnasri, Aboulaye Traoré, et al.. Development of nanopillars on mm² area of quantum-grade diamond membranes. 35th International Conference on Diamond and Carbon Materials, Elsevier, Aug 2025, Glasgow, United Kingdom. ⟨hal-05246825⟩
  • Roumli Nourzat, Léonard Desvignes, Riadh Issaoui, Ovidiu Brinza, Paul de Boiry, et al.. Reducing strain in CVD diamond films for quantum applications through substrate engineering and surface treatment. 35th International Conference on Diamond and Carbon Materials, Elsevier, Aug 2025, Glasgow, United Kingdom. ⟨hal-05246836⟩
  • Rahul Chembra, Paul Huillery. Photonic integration of diamond materials for quantum sensing applications with spin ensembles. 35th International Conference on Diamond and Carbon Materials (ICDMC 2025), Aug 2025, Glasgow, United Kingdom. ⟨hal-05694142⟩
  • Jocelyn Achard, Alexandre Tallaire, Ovidiu Brinza, Vianney Mille, Fabien J Bénédic. Engineering of diamond growth for high-end application: challenges and perspectives.. 75th UK Diamond Research Conference, Jul 2025, Warwick, United Kingdom. ⟨hal-05164913⟩
  • Ovidiu Brinza, Vianney Mille, Alexandre Tallaire, N. Girodon - Boulandet, Jocelyn Achard, et al.. Processing and shaping of large diamonds using a laser microjet technology. 18th international conference on new diamond and nano carbons - NDNC 2025, May 2025, Beppu, Japan. ⟨hal-05164870⟩
  • Ovidiu Brinza, Vianney Mille, Alexandre Tallaire, Jocelyn Achard, Fabien Bénédic. Laser MicroJet Technology for diamond processing and shaping. 8th French-Japanese Workshop on diamond power devices, Jun 2024, Agay, France. ⟨hal-04722905⟩

Poster communications

  • Issaoui Riadh, Mehmel Lahcene, Alzetto Florent, Tallaire Alexandre, Bénédic Fabien, et al.. Advancements in dislocation reduction for large area diamond substrates: toward scalable high performance materials. 18th international conference on new diamond and nano carbons - NDNC 2025, May 2025, Beppu, Japan. ⟨hal-05164759⟩
  • Léonard Desvignes, Ovidiu Brinza, Alexandre Tallaire, Roumli Nourzat, Fabien J Bénédic, et al.. Quantum properties of NV centers in diamond: towards optimized industrial protocols. Hasselt Diamond Workshop 2025 SBDD XXIX, Mar 2025, Hasselt, Belgium. ⟨hal-05025579⟩
  • Roumli Nourzat, Paul de Boiry, Ovidiu Brinza, Riadh Issaoui, Alexandre Tallaire, et al.. Investigation of crystallites in CVD diamond films and their impact on stress distribution. Hasselt Diamond Workshop 2025 SBDD XXIX, Mar 2025, Hasselt, Belgium. ⟨hal-05025502⟩
  • Rahul Chembra, Paul Huillery. Photonic integration of diamond materials for quantum sensing applications with spin ensembles. 34th International Conference on Diamond and Carbon Materials (ICDCM 2024), Sep 2024, Dresden, Germany. ⟨hal-05694135⟩

Partners

LSPM Laboratoire des Sciences des Procédés et des Matériaux
LUMIN Laboratoire Lumière-Matière aux Interfaces
HiQuTe HiQuTe Diamond
LPENS Laboratoire de Physique de L’Ecole Normale Supérieure
Inst.FOTON Institut Fonctions Optiques pour les Technologies de l’informatiON
KWAN-TEK KWAN-TEK

Coordinator

Jocelyn ACHARD (Laboratoire des Sciences des Procédés et des Matériaux)

Coordinator iFOTON: Paul HUILLERY (Foton-OHM)

Fundings

ANR (796 306€)

See online

SINFONIA: diamond ShapIng for membraNe Fabrication and integratiOn into high end quaNtum sensIng Applications
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