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China Builds the First Space-Ground Integrated Quantum Communication Network

Using Micius for a quantum-safe intercontinental video conference between China and Austria

Figure 1 (Image by the China Academy of Sciences)

Private and secure communications are fundamental human needs. In particular, with the exponential growth of Internet use and e-commerce, it is of paramount importance to establish a secure network with global protection of data. Traditional public key cryptography usually relies on the perceived computational intractability of certain mathematical functions. In contrast, quantum key distribution (QKD) uses individual light quanta (single photon) in quantum superposition states to guarantee unconditional security between distant parties. Previously, the quantum communication distance had been limited to a few hundred kilometers, due to the channel loss of fibers or terrestrial free space. A promising solution to this problem is exploiting satellite and space-based link, which can conveniently connect two remote points on the Earth with greatly reduced channel loss because most of the photons’ propagation path is in empty space with negligible loss and decoherence.

A cross-disciplinary multi-institutional team of scientists from the Chinese Academy of Sciences, led by Professor PAN Jianwei, has spent more than ten years in developing a sophisticated satellite, named Micius, dedicated for quantum science experiments (for the project timeline, see Appendix), which was successfully launched on 16th August 2016, from Jiuquan, China, orbiting at an altitude of ~500 km . The satellite is equipped with three payloads: a decoy-state QKD transmitter, an entangled-photon source, and a quantum teleportation receiver and analyzer. Five ground stations are built in China to cooperate with the Micius satellite, located in Xinglong (near Beijing, 40°23’45.12’’N, 117°34’38.85’’E, altitude 890m), Nanshan (near Urumqi, 43°28’31.66’’N, 87°10’36.07’’E, altitude 2028m), Delingha (37°22’44.43’’N, 97°43’37.01”E, altitude 3153m), Lijiang (26°41’38.15’’N, 100°1’45.55’’E, altitude 3233m), and Ngari in Tibet (32°19’30.07’’N, 80°1’34.18’’E, altitude 5047m).

Figure 3 (Image by the China Academy of Sciences)

Within a year after the launch, three key milestones that will be central to a global-scale quantum internet have been achieved: satellite-to-ground decoy-state QKD with kHz rate over a distance of ~1200 km (Liao et al. 2017, Nature 549, 43); satellite-based entanglement distribution to two locations on the Earth separated by ~1200 km and Bell test (Yin et al. 2017, Science 356, 1140), and ground-to-satellite quantum teleportation (Ren et al. 2017, Nature549, 70). The effective link efficiencies in the satellite-based QKD were measured to be ~20 orders of magnitudes larger than direct transmission through optical fibers at the same length at 1200 km.

The satellite-based QKD has now been combined with metropolitan quantum networks, in which fibers are used to efficiently and conveniently to connect many users inside a city with a distance scale of ~100 km. For example, the Xinglong station has now been connected to the metropolitan multi-node quantum network in Beijing via optical fibers. Very recently, the largest fiber-based quantum communication backbone has been built in China by Professor Pan’s team, linking Beijing to Shanghai (going through Jinan and Hefei, and 32 trustful relays) with a fiber length of 2000 km. The backbone uses decoy-state protocol QKD and achieves an all-pass secure key rate of 20 kbps. It is on trial for real-world applications by government, banks, securities and insurance companies.

The Micius satellite can be further exploited as a trustful relay to conveniently connect any two points on the earth for high-security key exchange. Early this year, the Chinese team has implemented satellite-to-ground QKD in Xinglong. After that, the secure keys were stored in the satellite for 2 hours until it reached Nanshan station near Urumqi, by a distance of ~2500 km from Beijing. By performing another QKD between the satellite and Nanshan station, and using one-time-pad encoding, secure key between Xinglong and Nanshan were then established. To test the robustness and versatility of the Micius, QKD from the satellite to Graz ground station near Vienna has also been carried out successfully this June, as a collaboration between Professor Pan and Professor Anton Zeilinger’s group. Upon request, future similar experiments is also planned between China and Singapore, Italy, Germany, and Russia.

Exploiting the space–ground integrated quantum network, on 29th September, the first quantum-safe video conference is held between President BAI Chunli of the Chinese Academy of Sciences in Beijing and President Anton Zeilinger of the Austria Academy of Sciences in Vienna, as the first real-world demonstration of intercontinental quantum communication.

Figure 2 (Image by the China Academy of Sciences)

Figure 4 (Image by the China Academy of Sciences)



China’s Micius Project: timeline and details

2003: a pre-study project “free-space quantum communications” was assigned by the Chinese Academy of Sciences (CAS) to test the feasibility of satellite-based quantum communications.

2004: Distribution of entangled photons over 13 km through noisy ground atmosphere over Hefei city was achieved, reaching a distance beyond the effective thickness of the aerosphere for the first time.

2007: The “Quantum Experiments at Space Scale” project aiming at developing key techniques for performing quantum experiments at the space scale was supported by CAS.

2007: Quantum teleportation over the Great Wall in Beijing with a distance of 16 km.

2010: Direct and full-scale experimental verifications towards ground-satellite QKD were implemented near Qinghai Lake in West China, on a moving platform (using a turntable), on a floating platform (using a hot-air balloon), and with a high-loss channel (96 km, ~50dB).

2011: Quantum teleportation and bidirectional entanglement distribution over ~100 km free-space channel were achieved over the Qinghai Lake4. The work showed the technical ability of handling the high-loss ground-to-satellite uplink channel and satellite-to-ground two-downlink channel.

2011: The “Quantum Science Satellite” project was officially approved by CAS.

2012: The construction of the first prototype satellite started.

2014: The first prototype satellite was completed.

2015: The flight model of the satellite was completed.

2016: The satellite passed through a series of environmental test, including, thermal vacuum, thermal cycling, shock, vibration, electro-magnetic compatibility.

2016: The Micius satellite, weighted 635 kg was launched at 1:40AM Beijing time, 16th August 2016, by a Long March-2D rocket, from the Jiuquan Satellite Launch Centre, China.


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