Author
Listed:
- Peter Bierhorst
(National Institute of Standards and Technology
University of Colorado)
- Emanuel Knill
(National Institute of Standards and Technology
University of Colorado)
- Scott Glancy
(National Institute of Standards and Technology)
- Yanbao Zhang
(National Institute of Standards and Technology
NTT Basic Research Laboratories and NTT Research Center for Theoretical Quantum Physics, NTT Corporation)
- Alan Mink
(National Institute of Standards and Technology
Theiss Research)
- Stephen Jordan
(National Institute of Standards and Technology)
- Andrea Rommal
(Muhlenberg College)
- Yi-Kai Liu
(National Institute of Standards and Technology)
- Bradley Christensen
(University of Wisconsin)
- Sae Woo Nam
(National Institute of Standards and Technology)
- Martin J. Stevens
(National Institute of Standards and Technology)
- Lynden K. Shalm
(National Institute of Standards and Technology
University of Colorado)
Abstract
From dice to modern electronic circuits, there have been many attempts to build better devices to generate random numbers. Randomness is fundamental to security and cryptographic systems and to safeguarding privacy. A key challenge with random-number generators is that it is hard to ensure that their outputs are unpredictable1–3. For a random-number generator based on a physical process, such as a noisy classical system or an elementary quantum measurement, a detailed model that describes the underlying physics is necessary to assert unpredictability. Imperfections in the model compromise the integrity of the device. However, it is possible to exploit the phenomenon of quantum non-locality with a loophole-free Bell test to build a random-number generator that can produce output that is unpredictable to any adversary that is limited only by general physical principles, such as special relativity1–11. With recent technological developments, it is now possible to carry out such a loophole-free Bell test12–14,22. Here we present certified randomness obtained from a photonic Bell experiment and extract 1,024 random bits that are uniformly distributed to within 10−12. These random bits could not have been predicted according to any physical theory that prohibits faster-than-light (superluminal) signalling and that allows independent measurement choices. To certify and quantify the randomness, we describe a protocol that is optimized for devices that are characterized by a low per-trial violation of Bell inequalities. Future random-number generators based on loophole-free Bell tests may have a role in increasing the security and trust of our cryptographic systems and infrastructure.
Suggested Citation
Peter Bierhorst & Emanuel Knill & Scott Glancy & Yanbao Zhang & Alan Mink & Stephen Jordan & Andrea Rommal & Yi-Kai Liu & Bradley Christensen & Sae Woo Nam & Martin J. Stevens & Lynden K. Shalm, 2018.
"Experimentally generated randomness certified by the impossibility of superluminal signals,"
Nature, Nature, vol. 556(7700), pages 223-226, April.
Handle:
RePEc:nat:nature:v:556:y:2018:i:7700:d:10.1038_s41586-018-0019-0
DOI: 10.1038/s41586-018-0019-0
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Cited by:
- Li, Runze & Li, Dandan & Huang, Wei & Xu, Bingjie & Gao, Fei, 2023.
"Tight bound on tilted CHSH inequality with measurement dependence,"
Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 626(C).
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