<p>Quantum two-way time transfer (Q-TWTT) leveraging energy-time entangled biphotons has achieved sub-picosecond stability but faces fundamental distance limitations due to the no-cloning theorem’s restriction on quantum amplification. To overcome this challenge, we propose a cascaded Q-TWTT architecture employing relay stations that generate and distribute new energy-time entangled biphotons after each transmission segment. Theoretical modeling reveals sublinear standard deviation growth (merely <InlineEquation ID="IEq1"> <EquationSource Format="TEX">\(\sqrt{N}\times\)</EquationSource> <EquationSource Format="MATHML"><math display="block"> <msqrt> <mi>N</mi> </msqrt> <mo>×</mo> </math></EquationSource> </InlineEquation> increase for <i>N</i> × equidistant segments), enabling preservation of sub-picosecond stability over extended distances. We experimentally validate this approach using a three-station cascaded configuration over 2×100 km fiber segments, demonstrating strong agreement with theory. Utilizing independent Rb clocks at end and relay stations with online frequency skew correction, we achieve time stabilities of 3.82 ps at 10 s and 0.39 ps at 5120 s. The consistency in long-term stability between cascaded and single-segment configurations confirms high-precision preservation across modular quantum networks. This work establishes a framework for long-distance quantum time transfer that bypasses the no-cloning barrier, providing a foundation for future quantum-network timing infrastructure.</p>

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Cascaded quantum time transfer bypassing the no-cloning barrier

  • Huibo Hong,
  • Xiao Xiang,
  • Runai Quan,
  • Bingke Shi,
  • Yuting Liu,
  • Zhiguang Xia,
  • Tao Liu,
  • Xinghua Li,
  • Mingtao Cao,
  • Shougang Zhang,
  • Kai Guo,
  • Ruifang Dong

摘要

Quantum two-way time transfer (Q-TWTT) leveraging energy-time entangled biphotons has achieved sub-picosecond stability but faces fundamental distance limitations due to the no-cloning theorem’s restriction on quantum amplification. To overcome this challenge, we propose a cascaded Q-TWTT architecture employing relay stations that generate and distribute new energy-time entangled biphotons after each transmission segment. Theoretical modeling reveals sublinear standard deviation growth (merely \(\sqrt{N}\times\) N × increase for N × equidistant segments), enabling preservation of sub-picosecond stability over extended distances. We experimentally validate this approach using a three-station cascaded configuration over 2×100 km fiber segments, demonstrating strong agreement with theory. Utilizing independent Rb clocks at end and relay stations with online frequency skew correction, we achieve time stabilities of 3.82 ps at 10 s and 0.39 ps at 5120 s. The consistency in long-term stability between cascaded and single-segment configurations confirms high-precision preservation across modular quantum networks. This work establishes a framework for long-distance quantum time transfer that bypasses the no-cloning barrier, providing a foundation for future quantum-network timing infrastructure.