What does this research mean for the field?

Solid-state, room-temperature quantum random number generation (QRNG) can be successfully implemented using nitrogen-vacancy (NV) centers in diamond, achieving high entropy rates above 0.98 bits through both ensemble fluorescence and nanopillar-isolated single-photon emission. Novelty: ClaimNovelty.METHODOLOGICAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This work aims to demonstrate two QRNG methods using NV centers in diamonds, emphasizing unpredictability from quantum processes.

March 29, 2026Open Access

Quantum Random Number Generation Using Nanodiamonds and Nanopillar-Isolated Single NV Centers

Key Points

This work aims to demonstrate two QRNG methods using NV centers in diamonds, emphasizing unpredictability from quantum processes.
Developed two QRNG implementations based on NV centers in diamond: ensemble fluorescence and single-photon emission.
Used nanodiamonds and diamonds with nanopillar structures to improve light collection and reduce crosstalk.
Compared entropy rates and statistical performance of each QRNG approach under room-temperature conditions.
Both implementations showed high entropy rates above 0.98 bits, indicating strong randomness.
Single NV centers at nanopillars provided enhanced performance and robustness compared to ensemble fluorescence.

Abstract

Quantum random number generation (QRNG) provides fundamentally unpredictable randomness derived from intrinsic quantum processes. In this work we demonstrate two solid-state, room-temperature QRNG implementations based on nitrogen-vacancy (NV) centers in diamond, i.e., ensemble fluorescence from nanodiamonds and single-photon emission from single NV centers located at the tips of fabricated diamond nanopillars for enhanced light collection efficiency, spatial isolation and minimized crosstalk. We compare entropy rates (above 0.98 bits), statistical performance, and robustness of both approaches in our experimental setup, the results contribute to establishing diamond-based QRNG as a scalable solution for quantum-secure randomness generation.

Quantum Random Number Generation Using Nanodiamonds and Nanopillar-Isolated Single NV Centers

Key Points

Abstract

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