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Autori principali: Jiang, Yang-Fan, Kent, Adrian, Pitalúa-García, Damián, Yao, Xiaochen, Chen, Xiaohan, Huang, Jia, Cowperthwaite, George, Zheng, Qibin, Li, Hao, You, Lixing, Liu, Yang, Zhang, Qiang, Pan, Jian-Wei
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2408.13063
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author Jiang, Yang-Fan
Kent, Adrian
Pitalúa-García, Damián
Yao, Xiaochen
Chen, Xiaohan
Huang, Jia
Cowperthwaite, George
Zheng, Qibin
Li, Hao
You, Lixing
Liu, Yang
Zhang, Qiang
Pan, Jian-Wei
author_facet Jiang, Yang-Fan
Kent, Adrian
Pitalúa-García, Damián
Yao, Xiaochen
Chen, Xiaohan
Huang, Jia
Cowperthwaite, George
Zheng, Qibin
Li, Hao
You, Lixing
Liu, Yang
Zhang, Qiang
Pan, Jian-Wei
contents Quantum money is the first invention in quantum information science, promising advantages over classical money by simultaneously achieving unforgeability, user privacy, and instant validation. However, standard quantum money relies on quantum memories and long-distance quantum communication, which are technologically extremely challenging. Quantum "S-money" tokens eliminate these technological requirements while preserving unforgeability, user privacy, and instant validation. Here, we report the first full experimental demonstration of quantum S-tokens, proven secure despite errors, losses and experimental imperfections. The heralded single-photon source with a high system efficiency of 88.24% protects against arbitrary multi-photon attacks arising from losses in the quantum token generation. Following short-range quantum communication, the token is stored, transacted, and verified using classical bits. We demonstrate a transaction time advantage over intra-city 2.77 km and inter-city 60.54 km optical fibre networks, compared with optimal classical cross-checking schemes. Our implementation demonstrates the practicality of quantum S-tokens for applications requiring high security, privacy and minimal transaction times, like financial trading and network control. It is also the first demonstration of a quantitative quantum time advantage in relativistic cryptography, showing the enhanced cryptographic power of simultaneously considering quantum and relativistic physics.
format Preprint
id arxiv_https___arxiv_org_abs_2408_13063
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Experimental practical quantum tokens with transaction time advantage
Jiang, Yang-Fan
Kent, Adrian
Pitalúa-García, Damián
Yao, Xiaochen
Chen, Xiaohan
Huang, Jia
Cowperthwaite, George
Zheng, Qibin
Li, Hao
You, Lixing
Liu, Yang
Zhang, Qiang
Pan, Jian-Wei
Quantum Physics
Quantum money is the first invention in quantum information science, promising advantages over classical money by simultaneously achieving unforgeability, user privacy, and instant validation. However, standard quantum money relies on quantum memories and long-distance quantum communication, which are technologically extremely challenging. Quantum "S-money" tokens eliminate these technological requirements while preserving unforgeability, user privacy, and instant validation. Here, we report the first full experimental demonstration of quantum S-tokens, proven secure despite errors, losses and experimental imperfections. The heralded single-photon source with a high system efficiency of 88.24% protects against arbitrary multi-photon attacks arising from losses in the quantum token generation. Following short-range quantum communication, the token is stored, transacted, and verified using classical bits. We demonstrate a transaction time advantage over intra-city 2.77 km and inter-city 60.54 km optical fibre networks, compared with optimal classical cross-checking schemes. Our implementation demonstrates the practicality of quantum S-tokens for applications requiring high security, privacy and minimal transaction times, like financial trading and network control. It is also the first demonstration of a quantitative quantum time advantage in relativistic cryptography, showing the enhanced cryptographic power of simultaneously considering quantum and relativistic physics.
title Experimental practical quantum tokens with transaction time advantage
topic Quantum Physics
url https://arxiv.org/abs/2408.13063