Experimental realization of device-independent quantum randomness expansion

Randomness is of paramount importance to human activities, from election to drug design and to digital cryptography. The origin of randomness and its applications are under active investigations. The recent realizations of device-independent quantum random number generation provide intrinsically unpredictable random numbers without trusting the inner working of devices, where a great deal of input randomness was used to generate a small output randomness. Randomness expansion$-$generating a longer sequence of random numbers from a short one, is viable in quantum mechanics but not allowed classically since all classical algorithms are essentially deterministic. Quantum randomness expansion is not only a fundamental question in science but also of practical interest. Here we report the first experimental realization of device-independent quantum randomness expansion by employing the quantum probability estimation framework. We demonstrate to generate output randomness exceeding the input randomness unpredictably by 512 bits at a latency of less than 8 mins, and to achieve an asymptotic rate of $\approx0.08$ bit per trial, the largest for unpredictable random bits generation to date, with a failure probability $2^{-64}\approx5.4\times10^{-20}$. Device-independent quantum randomness expansion harvesting quantum advantage not only furthers our understanding of randomness but also is resource-efficient in the generation of quantum-certifiable random bits for practical applications.