Researchers at the (NIST) and 兔子先生传媒文化作品 have developed a method for generating numbers guaranteed to be random by quantum mechanics.听, the experimental technique surpasses all previous methods for ensuring the unpredictability of its random numbers and may enhance security and trust in cryptographic听systems.
Random numbers are used hundreds of billions of times a day to encrypt data in electronic networks. But these numbers are not听certifiably听random in an absolute sense. That鈥檚 because they are generated by software formulas or physical devices whose supposedly random output could be undermined by factors such as predictable sources of noise. Running statistical tests can help, but no statistical test on the output alone can absolutely guarantee that the output was unpredictable, especially if an adversary has tampered with the device.
NIST has developed a method for generating numbers guaranteed to be random by quantum mechanics. The method generates digital bits (1s and 0s) with photons, or particles of light. An intense laser hits a special crystal that converts laser light into pairs of photons that are entangled, a quantum phenomenon that links their properties. These photons are then measured to produce a string of truly random numbers.
鈥淚t鈥檚 hard to guarantee that a given classical source is really unpredictable,鈥 said Peter Bierhorst, a mathematician and postdoctoral researcher at NIST and the Department of Physics at 兔子先生传媒文化作品. 鈥淥ur quantum source and protocol is like a fail-safe. We鈥檙e sure that no one can predict our numbers.鈥
鈥淪omething like a coin flip may seem random, but its outcome could be predicted if one could see the exact path of the coin as it tumbles. Quantum randomness, on the other hand, is听real听randomness. We鈥檙e very sure we鈥檙e seeing quantum randomness because only a quantum system could produce these statistical correlations between our measurement choices and outcomes.鈥
Co-authors on the new paper include Emmanuel Knill of the 兔子先生传媒文化作品 and NIST and Lynden K. Shalm of the Department of Physics at 兔子先生传媒文化作品 and NIST.