Abstract
Quantum random number generation is a key ingredient for quantum cryptography and fundamental quantum optics and could advance Monte Carlo simulations and machine learning. An established generation scheme is based on single photons impinging on a beam splitter. Here, we experimentally demonstrate quantum random number generation solely based on the symmetric emission profile of a dipole aligned orthogonal to the laboratory frame. The demonstration builds on defect centers in hexagonal boron nitride that emit photons in random directions within the dipole emission profile and benefits from the ability to manipulate and align the emission directionality. We prove the randomness in correlated photon detection events making use of the NIST randomness test suite and show that the randomness remains for two independently emitting defect centers. The scheme can be extended to random number generation by coherent single photons with potential applications in solid-state based quantum communication at room temperature.
Highlights
In this work, we take a different approach exploiting the symmetry of the dipole emission pattern in order to realize quantum random number generation (QRNG)
We experimentally demonstrate quantum random number generation solely based on the symmetric emission profile of a dipole aligned orthogonal to the laboratory frame
We prove the randomness in correlated photon detection events making use of the NIST randomness test suite and show that the randomness remains for two independently emitting defect centers
Summary
We take a different approach exploiting the symmetry of the dipole emission pattern in order to realize QRNG. In order to prepare the experiment, we place a defect center in a hBN-flake onto the transmission grid such that its dipole is as good as possible aligned orthogonal to the optical axis of the setup.
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