Progress and Prospect of Experimental Research on High-Dimensional Quantum Key Distribution (Invited)

Dongxuan Li; Tao Zhao; Siyao Huang; Mengyao Yang; Zehong Chang; Pei Zhang

doi:10.3788/LOP250732

Laser & Optoelectronics Progress, Volume. 62, Issue 11, 1127015(2025)

Progress and Prospect of Experimental Research on High-Dimensional Quantum Key Distribution (Invited)

Dongxuan Li1...2, Tao Zhao1,2, Siyao Huang1,2, Mengyao Yang1,2, Zehong Chang1,2,**, and Pei Zhang12,* |Show fewer author(s)

Author Affiliations

¹Ministry of Education Key Laboratory for Nonequilibrium Synthesis and Modulation of Condensed Matter, School of Physics, Xi'an Jiaotong University, Xi'an 710049, Shaanxi , China

²Shaanxi Key Laboratory of Quantum Information and Quantum Optoelectronic Devices, Xi'an 710049, Shaanxi , China

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Figures & Tables(11)

Fig. 1. Two implementations of QKD protocol. (a) Schematic diagram of preparation-measurement-based scheme; (b) schematic diagram of entanglement-based scheme

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Fig. 2. Multiple potential degrees of freedom for constructing high-dimensional quantum states^[33]

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Fig. 3. Schematic diagrams of OAM intensity and phase distribution

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Fig. 4. HD-QKD experiments based on OAM. (a) Proof-of-principle demonstration of 7-dimensional QKD based on DMD^[49]; (b) 4-dimensional HD-QKD experiment in free-space link of 300 m over the city^[16];^{(c) HD-QKD experiment based on polarization-OAM mutual mapping^[31,52]; (d) MPUB-based HD-QKD protocol experiment^[56-57]}

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Fig. 5. Schematic diagram of preparation for high-dimensional Time-bin entangled state^[22]

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Fig. 6. Experiments based on Time-bin HD-QKD. (a) Preparation-measurement-based 4-dimensional Time-bin QKD scheme^[20]; (b) quantum measurement scheme based on two-photon interference^[65];^{(c) large-alphabet Time-bin QKD experimental device^[68]; (d) compact 4-dimensional measurement scheme^[66]; (e) Time-bin-path hybrid coding experiment using multi-core fiber^[70]; (f) high-dimensional Time-bin integrated photonic platform^[71]}

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Fig. 7. Preparation-measurement HD-QKD experiments based on path coding. (a) Decoy-state HD-QKD experiment based on multicore fiber^[17]; (b) path coding HD-QKD experiment implemented on integrated circuit^[78]; (c) high-dimensional MDI-QKD scheme^[79]; (d) HD-QKD experiment based on PLL^[80]

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Fig. 8. High-dimensional entanglement distribution experiments based on path coding. (a) 4-dimensional path-polarization super entanglement distribution experiment on 11 km multicore fiber^[81]; (b) 8-dimensional entanglement distribution experiment based on subspace coding^[82]; (c) 4-dimensional entanglement distribution experiment based on multi-chip quantum network^[83]

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Fig. 9. Experimental progresses of high-dimensional multi-degree of freedom quantum networks. (a) Conceptual diagram of composable quantum networks^[86]; (b) three-degree of freedom (Time-bin, polarization, and spatial mode) hybrid 8-dimensional QKD system^[86]; (c) experimental setup of simultaneous transmission for three-degree of freedom super entanglement in multicore fiber^[87]; (d) 2×N plug and play TF-QKD network scheme^[88]

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Table 1. Comparative analysis for degrees of freedom in HD-QKD: advantages, challenges, and application scenarios

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Table 1. Comparative analysis for degrees of freedom in HD-QKD: advantages, challenges, and application scenarios

Degree of freedom	Advantages	Challenges	Application scenarios
OAM	Theoretically mappable to infinite-dimensional Hilbert space； rotation-invariant properties eliminate the need for reference system alignment during measurement	Requires custom-designed specialty fibers for OAM transmission； susceptible to atmospheric turbulence and finite aperture effects in free space	Free-space QKD
Time-bin	Stable relative phase between temporal modes； high compatibility with existing classical fiber infrastructure	Increased dimensionality exacerbates timing errors and system complexity； fundamental trade-off between dimensionality and repetition frequency	Legacy fiber-optic networks， long-distance communication
Path	High distinguishability between quantum states in distinct paths， enabling efficient detection； ideal for on-chip photonic system development	Vulnerable to path-phase drifts caused by vibrations or temperature fluctuations； dimensional expansion amplifies losses from fiber/optical components	Integrated photonic platforms

Table 2. HD-QKD experimental indicators

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Table 2. HD-QKD experimental indicators

Degree of freedom	Channel	Year	Distance /km	Protocol	Dimension	Key rate
OAM	Free space	2015^［50］	—	HD-BB84	7	6.5 bit/s
		2017^［16］	0.3	HD-BB84	4	0.65 bit/sifted signal
		2017^［50］	—	HD-BB84	10	0.49 bit/photon
		2019^［31］	—	HD-BB84	4	1.849 bit/sifted signal
		2023^［57］	—	HD-BB84	6	1.4092 bit/photon
	Fiber	2019^［51］	1.2	HD-BB84	4	42.3 kbit/s
	Fiber	2021^［52］	25	HD-BB84	4	0.201 bit/pulse
Time-bin	Fiber	2015^［64］	20	HD-BBM92	1024	2.7 Mbit/s
		2017^［20］	20	HD-BB84	4	26.2 Mbit/s
		2019^［65］	20	HD-BB84	8	8.65 Mbit/s
		2019^［67］	20	HD-BBM92	4	151 kbit/s
		2020^［66］	145	HD-BB84	4	0.42 kbit/s
		2024^［68］	50	HD-BBM92	—	0.24 Mbit/s
		2024^［69］	242	DO-QKD	3	0.22 bit/s
		2024^［70］	52	HD-BB84	4	51.5 kbit/s
		2025^［71］	60	HD-BBM92	6	37 bit/s
		2025^［72］	40	HD-COW	8	0.14 Mbit/s
Path	Free space	2021^［82］	—	HD subspace coding	8	8.3 kbit/s
	Fiber	2017^［17］	25	HD-BB84	4	4.31×10^-3 bit/s
		2017^［78］	20	HD-MDI-QKD	4	12.5 bit/s
		2020^［81］	11	HD-BBM92	4	0.54 kbit/s
		2020^［18］	2	HD-BB84	4	29.8 kbit/s
		2021^［80］	2	HD-BB84	4	6.3 Mbit/s
		2023^［83］	—	HD-BBM92	3	0.346 bit/count

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Dongxuan Li, Tao Zhao, Siyao Huang, Mengyao Yang, Zehong Chang, Pei Zhang. Progress and Prospect of Experimental Research on High-Dimensional Quantum Key Distribution (Invited)[J]. Laser & Optoelectronics Progress, 2025, 62(11): 1127015

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