Abstract
To advance the full potential of quantum networks one should be able to distribute quantum resources over long distances at appreciable rates. As a consequence, all components in such networks need to have large multimode capacity to manipulate photonic quantum states. Towards this end, a photonic quantum memory with a large multimode capacity, especially one operating at telecom wavelength, remains an important challenge. Here we optimize the preparation of atomic frequency combs and demonstrate a spectro-temporally multiplexed quantum memory in a 10-m-long cryogenically cooled erbium doped silica fibre. Our multiplexing storage has five spectral channels - each 10 GHz wide with 5 GHz separation - with up to 330 temporal modes in each, thus resulting in a simultaneous storage of 1,650 modes of heralded single photons with a 1000-fold increasing in coincidence detection rate with respect to single mode storage. Our results could pave the way for high speed quantum networks compatible with the infrastructure of fibre optical communication.
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Introduction
Multimode capacity of communication channel is an essential requirement for high data rates in modern communication networks. Towards future quantum networks1,2,3,4 compatible with existing telecom infrastructures, this requirement must also be applied5,6. One challenge in pursuing such a quantum network is to develop a multimode quantum memory7,8,9,10,11, which is able to simultaneously store and process multiple modes of single photons in various degrees of freedom, such as in temporal degree12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27, spectral degree28,29,30, spatial degree31,32,33,34,35,36,37,38,39, or any combination of these40,41. Overall the multimode capacity of a quantum memory is determined by the number of storage channels in spectral or spatial domain and the number of storage temporal modes in each storage channel.
To realize a large multimode quantum storage capacity, the use of multiple spatial channels has yielded a good performance, with a channel number up to 665 realized in gaseous atomic ensembles36 based on Duan-Lukin-Cirac-Zoller (DLCZ) protocol42. Further improvement on the multimode capacity of such memory could be achieved via increasing the number of stored temporal modes in each of these channels. However, the storage of multiple temporal modes remains challenging in atomic gas ensembles due to limitations of the applied storage protocols42,43,44. Specifically, the number of temporal modes that can be stored is related to the optical depth (OD) of the storage media45. Fortunately, the atomic frequency comb (AFC) quantum memory with rare-earth ion-doped (REID) materials does not feature this constraint in terms of OD for the storage of multiple temporal modes46, where the multimode capacity is proportional to the total number of teeth of the prepared AFCs26, i.e., the product of channel number, storage time and the per bandwidth of AFC. Notable efforts have been devoted to improving the storage mode number of the AFC memory, such as increasing the ratio between storage time and temporal mode size27, preparing multiple AFC channels by spectral multiplexing28,29,30, and storing multiple degrees of freedom of single photons41. While an AFC quantum memory with 2500 teeth has been prepared27, it is still challenging to demonstrate a quantum memory with an even larger multimode capacity.
Towards this end, we optimize the preparation of AFCs in five spectral channels with a total number of more than 10,000 teeth, and demonstrate a multimode storage of 1650 spectro-temporal modes of single photon at telecom wavelength with a piece of erbium doped silica fibre (EDF). Compared to single mode storage, we achieve a 1,000-fold increasing in coincidence detection rate. Our result could pave the way towards developing future quantum internet by utilizing multimode quantum memory compatible with the infrastructure of fibre optical communication system.
Results
Multimode quantum storage scheme
Based on the inhomogeneous broadening in REID materials, an Sn × Tn multimode quantum memory can be realized by using Sn spectral channels and Tn temporal modes in each spectral channel (see Fig. 1a). Through spectral tailoring of the inhomogeneous broadened absorption line of REID materials, AFC channels with a number of Sn in the spectral domain are prepared. In each spectral channel, a train of single photons in Tn temporal modes are stored, with the maximum value of Tn determined by the time-bandwidth product of the AFC memory. By doing so, a total number of Sn × Tn modes of single photons are stored, simultaneously. To develop such a quantum memory with multimode capacity at telecom wavelength, a promising REID material is low doping concentration EDF, which has a telecom-band transition wavelength and THz-wide inhomogeneous broadening (see Fig. 1b, c).
Experimental setup
The experimental setup is composed of an EDF based AFC quantum memory with five spectral channels, a heralded single photon source at telecom wavelength, and a coincidence detection system, as illustrated in Fig. 2a. The experimental time sequences are also shown in Fig. 2b (see Methods).
We prepare an AFC quantum memory with five spectral channels in a 10-m-long EDF cooled to a temperature of 10 mK and exposed to a magnetic field of 2000 Gauss (see Fig. 2a(I) and Methods for details). More precisely, we propose and apply an approach - optical frequency comb combined with frequency chirping - to prepare five individual AFCs, each with a bandwidth of 10 GHz, at central wavelengths of 1532.11 nm, 1532.00 nm, 1531.88 nm, 1531.76 nm and 1531.65 nm, labeled as channels of 1, 2, 3, 4, and 5 (see Supplementary Note 1 for more details on preparing five AFCs by using optical frequency comb combined with frequency chirping method). Figure 1d depicts a typical AFC (channel 2) in our experiment, and all the five AFCs are shown in Supplementary Note 1. Note that different from using multiple individual lasers in parallel to prepare spectrally multiplexed AFC quantum memory29, our method not only prepares such an AFC quantum memory by using a single laser, but also guarantees each channel with large bandwidth. Moreover, the scheme applies spectral isolation among channels, thus making the crosstalk among different storage channels to be negligible. When a single photon, matched with one of the AFCs, is absorbed by the AFC memory, the prepared Dicke state can be expressed as47:
where W is the number of AFC tooth within the bandwidth of the single photon. Each tooth can be treated as a two-level system with collective states \(\left\vert 0\right\rangle\) and \(\left\vert 1\right\rangle\), in which \(\left\vert 0\right\rangle\) represents all atoms in the tooth are in the ground state, \(\left\vert 1\right\rangle\) represents that a single atom in the tooth is excited by the single photon. After the creation of the Dicke state, different terms in Eq. (1), begin to accumulate different phases, \({e}^{i{\delta }_{j}t}\), where δj = (j − 1)Δ (j = 1, 2, …, W) represents the relative detuning of the jth tooth to the first tooth, and Δ is the teeth spacing of AFC). At the time of t = 1/Δ, the phases of all terms in the state are equal to an integer multiple of 2π, i.e., equivalent to 0. This process of rephasing leads to the re-emission of input photon in its original quantum state. In our scheme, we utilize spectro-temporally multiplexed storage to improve the stored mode number. For the temporal multiplexing quantum storage, the larger temporal mode number in each AFC channel corresponds to the Dicke state with more absorbers, i.e., the larger number of AFC teeth W, which would increase the fragility of the prepared Dicke state47, resulting in the decreasing of storage efficiency. While for spectral multiplexing, different Dicke states are prepared at different detuning in inhomogeneous broadening of rare-earth ions, in which the number of absorbers for each state remains constant, preventing an increase in the fragility of the states.
To characterize the five spectral channels of quantum memory, we generate heralded single photons at telecom wavelength in a fibre pig-tailed periodically poled lithium niobate (PPLN) module48,49,50, as shown in Fig. 2a(II). The light from a continuous-wave (CW) laser (PPCL300, PURE Photonics) operating at 1540.60 nm is modulated to light pulses and subsequently sent into the PPLN module. The cascaded second-harmonic generation (SHG) and spontaneous parametric down conversion (SPDC) processes result in correlated photon-pairs centred at 1540.60 nm with a bandwidth of ~60 nm. After efficient filtering, the central wavelengths of signal and idler photons are 1531.88 nm and 1549.32 nm with a bandwidth of ~100 GHz. The signal photons are sent into the five AFC spectral channels. It is worth noting that AFC itself is both a memory and a quantum information processor, which can also realize pulse sequencing, splitting, manipulating, filtering51, etc. In our experiment, the spectral modes that do not match the storage bandwidth will be either absorbed and re-emitted spontaneously (with a decay time of ~10 ms) or pass through the memory, in which case they can be discriminated by their arrival time. Then, recalled signal photons from different AFCs are selected by a tunable fibre Bragg grating (FBG). The idler photons corresponding to different recalled signal photons are further selected by another FBG. The two FBGs enable the selective detection of different frequency modes employed in spectral multiplexing. In other words, each spectral channel can be individually discriminated and treated as an independent light-matter interface owing to the distinguishable signal photons and idler photons with different frequency, which is crucial for the development of spectral multiplexing quantum repeaters. It is worth noting that the transmission efficiency of FBG with the idler (signal) channel is 93% (89%). The bandwidth of the FBG is 0.06 nm for idler channel and 0.05 nm for signal channel. And the tuning speed of the FBG for each channel is around 20 s (see Supplementary Note 2 for more details of heralded single photon source).
Finally, we establish a coincidence detection system consisting of superconducting nanowire single photon detectors (SNSPDs, P-CS-6, PHOTEC Corp.) and a time-to-digital converter (TDC, quTAG, qutools), as shown in Fig. 2a(III) (see Methods for details of the SNSPDs). All SNSPD detection signals are delivered to the TDC to perform coincidence measurements. The system storage efficiency can be calculated by the ratio of the counts of recalled heralded photons to that of the input heralded photons. The second-order cross-correlation function (\({g}_{s,i}^{(2)}(0)\)) between signal and idler photons after/before storage is calculated as:
where psi is the probability of 3-fold coincidence detections of trigger signal, idler photons, and signal photons, ps (pi) is the probability of coincidence detections of trigger signal and signal (idler) photons, respectively. Note that the coincidence detection in our experiment with trigger signal enables us to select the recalled photons by their arrival time, thus reducing the noise photon from the residual spontaneous emission. According to the Cauchy-Schwarz inequality52, a non-classical field satisfies \({g}_{s,i}^{(2)}(0) > 2\). More details of measuring \({g}_{s,i}^{(2)}(0)\) through coincidence counts are given in Methods.
Measurement
First, we investigate the performance of the five AFC spectral channels. To this end, we vary the storage time from 5 ns to 230 ns by programming by programming the AFC tooth number from 50 to 2300 in each channel. For each case, we map heralded single photons onto each of the five spectral channels, and subsequently collect coincidence statistics of the recalled photons to gauge storage performance in terms of storage time, efficiency, and preservation of quantum properties manifested in the \({g}_{s,i}^{(2)}(0)\) values. According to the measured results, the system storage efficiency of each channel with different storage times ranges from 0.1% to 1%. The \({g}_{s,i}^{(2)}(0)\) still remains above 25 for the maximum storage time of 230 ns (see Table 1), demonstrating strong non-classical properties for all storage times (see Supplementary Note 3, 4 and 5 for more analysis of the storage efficiency and \({g}_{s,i}^{(2)}(0)\) for five individual AFCs). Furthermore, these measurements demonstrate that our memory, in principle, is able to perform quantum storage of 920 temporal modes of telecom-band single photons in each spectral channel. The temporal mode number is calculated by 10 GHz × 230 ns/2.5, where the factor of 2.5 is from the Nyquist-Shannon sampling theorem26. With five parallel channels, the total multimode capacity reaches 4600 in our demonstration.
Second, to examine the effect of crosstalk between different spectral channels, we measure the \({g}_{s,i}^{(2)}(0)\) between recalled signal photons and heralding idler photons corresponding to different spectral channels37. If there is no crosstalk between different spectral channels, the measured \({g}_{s,i}^{(2)}(0)\) between uncorrelated channels should be around 1. On the other hand, with increasing crosstalk, the value of \({g}_{s,i}^{(2)}(0)\) would also increase (the relationship between crosstalk and \({g}_{s,i}^{(2)}(0)\) is shown in Supplementary Note 6). To eliminate the crosstalk between spectral channels, a sufficiently large separation between adjacent AFCs is required28 - in our case we choose 5 GHz separation. We first assess the crosstalk resulting from the source and detection system without the quantum memory. For the crosstalk characterization, we label the signal photons corresponding to channels 1 to 5 as S1, S2, …, S5, and similarly, the idler photons as I1, I2, …, I5. The choice of which signal and idler channels to detect is determined by the tunable FBG filter settings. Measuring coincidences between Sm and In, where m, n ∈ {1, 2, 3, 4, 5}, we calculate a 5 × 5 matrix of \({g}_{s,i}^{(2)}(0)\). The measured average \({g}_{s,i}^{(2)}(0)\) is 27.90 ± 0.18 for 5 pairs of correlated spectral modes (m = n) and 1.07 ± 0.02 for the 20 pairs of uncorrelated spectral modes (m ≠ n), where error bars are acquired through Monte Carlo simulation. The detailed values are shown in Supplementary Note 7. The results indicate that the crosstalk between different spectral channels is negligible. Next, we evaluate whether the multimode memory induces additional crosstalk. To that end, we send the signal photons into the five AFC spectral channels with the storage time of 200 ns. The recalled signal photons from different channels are indexed as R1, R2, …, R5. Measuring coincidences between Rm and In, we obtain the recalled signal photons from five channels (see Fig. 3a). The measured coincidences detection rates of idler photon and recalled signal photons after storage are 0.19 ± 0.01 Hz, 0.36 ± 0.02 Hz, 0.29 ± 0.02 Hz, 0.21 ± 0.01 Hz, and 0.20 ± 0.01 Hz, respectively. The transmitted photons output from the EDF indicate the optical delay of the fibre, and the time delay between the transmitted photons and the recalled photons shows the storage time of the AFC memory. We again calculate the 5 × 5 array of \({g}_{s,i}^{(2)}(0)\) values as shown in Fig. 3b. The measured average \({g}_{s,i}^{(2)}(0)\) between recalled photons and idler photons is 25.48 ± 1.05 for five correlated spectral modes and 1.01 ± 0.10 for 20 pairs of uncorrelated spectral modes. The results confirm that the crosstalk between different spectral channels is negligible in our quantum memory.
Third, to quantify the storage mode number of our quantum memory, we create a train of heralded single photons - with pulse durations of and spaced by 300 ps - for simultaneous storage in all five spectral channels. With the storage time of 200 ns, 330 temporal modes are simultaneously stored in each spectral channel (see Fig. 3c). The measured coincidence detection rates of idler photon and signal photons after storage are 37.18 ± 6.10 Hz, 67.52 ± 8.22 Hz, 69.31 ± 8.33 Hz, 44.13 ± 6.64 Hz, and 39.16 ± 06.26 Hz, respectively. Compared to single mode storage, it is around 200-fold increasing in coincidence detection rate for each spectral channel. Noting that the detection rate of temporal multimode storage should be 330 times higher than that of single-mode storage, but due to the effect of the dead time of SNSPDs (~50 ns), the coincidence rate of the multimode storage drops with the mode number. The total stored mode number is, thus, up to 1650. Furthermore, to assess the crosstalk between different temporal modes, we obtain 1650 × 1650 values of \({g}_{s,i}^{(2)}(0)\) through measuring cross-correlation function between different idler photons and recalled signal photons. Figure 3d presents parts of \({g}_{s,i}^{(2)}(0)\) corresponding to different temporal modes in channel 2 (the full 1650 × 1650 array of \({g}_{s,i}^{(2)}(0)\) is shown in Supplementary Note 8). The average \({g}_{s,i}^{(2)}(0)\) between correlated signal and idler photonic modes (1650 pairs) is 22.92 ± 0.07, verifying that the non-classical correlations are intact. For uncorrelated modes the \({g}_{s,i}^{(2)}(0)\) is 1.01 ± 0.01 on average with error bar from Monte Carlo simulation, confirming the negligible crosstalk between different temporal modes. In addition, we conclude the key metrics of our multimode quantum memory in Table 2, which also includes the state-of-the-art of multimode quantum storage of non-classical light based on REID materials.
Discussion
An important feature of our demonstration is the large multimode capacity of quantum memory for the storage of single photons at telecom wavelength. Towards a memory with much larger multimode capacity in the future, it is necessary to further increasing the number of storage channel and its storage time18. In our demonstration, one could make using of entire THz-wide inhomogeneous broadening of the EDF to prepare more individual AFCs by using a broader optical frequency comb53. The storage time of AFC quantum memory could be increased by reducing its teeth spacing Δ, which is currently limited by our laser system - with a frequency drift of several MHz - for the AFC preparation. Furthermore, Δ will be limited by the linewidth AFC tooth, which is mainly determined by the spectral diffusion and the superhyperfine broadening of Er3+ ions. This needs to be further optimized by modifying the doping concentration of Er3+ ions and the co-dopant Al3+ ions in fibre54,55. Besides, full multimode operation is crucial for multiplexed quantum repeaters, which necessitates multimode heralding, storage, and detection. In our proof of principle demonstration, the heralding and detection are performed for each mode separately which is selected and characterized with FBGs and SNSPDs. A full multimode operation could be achieved by using more FBGs and SNSPDs.
Other upgrades could be applied to the EDF based quantum memories towards quantum networks. It is also possible to develop an on-demand quantum memory with spin-wave storage with a long-lived hyperfine level in a piece of EDF. However, it stays a challenge to discriminate the hyperfine levels in erbium ions without nuclear spin56. Fortunately, hyperfine levels with a coherence time of 380 microseconds with zero magnetic field57 and 1.3 s with 7 T magnetic field58 have been observed with 167Er3+ ions doped in yttrium orthosilicate. An AFC-based quantum storage of entangled photons has also been implemented in 167Er3+:Y2SiO559. These results show a great potential for an on-demand spin-wave quantum storage with 167Er3+ ions. Therefore, it could be a promising avenue to develop spin-wave storage by using 167Er3+ ions doped fibre. In the on-demand configuration, the small spin-level splitting would limit the bandwidth of AFC channel, thus reducing the multimode capacity. However, spectro-temporal multiplexing can also ensure the on-demand storage with large multimode capacity. Applying spectral multiplexing can increase the number of AFC channels at different atomic detuning in large inhomogeneous broadening, in which each AFC can achieve spin-wave storage independently, thus increasing the spectral multimode capacity. Combined with the intrinsic temporal multimode capacity of AFC protocol, it is promising to achieve on-demand storage with large multimode capacity at telecom wavelength. With regards to the storage efficiency, the non-zero background absorption (d0) of the prepared AFC is one of main limits. The d0 is caused by the limited ratio of the lifetime of Zeeman sublevels (~300 ms) to the waiting time following the AFC preparation (200 ms). The lifetime of Zeeman sublevels could be extended by optimizing the doping concentration6. The trade-off between the waiting time and the signal-to-noise ratio (SNR) of the memory can be further investigated. It is also worth to note that an impedance-matched optical cavity could be applied to improve the storage efficiency60,61. Towards a high-performance AFC quantum memory in the EDF, we propose a promising scheme to realize an impedance-matched quantum memory in a piece of optimized EDF (more details see Supplementary Note 9).
In summary, we have demonstrated a multimode quantum memory that is suitable for storage of spectro-temporal modes of single photons at telecom band. Our quantum memory with five 10-GHz wide AFCs channels allows for the storage of 1650 modes of heralded single photons - a 1000-fold increasing in coincidence detection rate compared to the single mode. Our results show that with the promising improvements on storage time and storage efficiency, the EDF based AFC quantum memory will pave the way for constructing quantum internet with the installed infrastructures of optical communication system.
Methods
Erbium doped silica fibre
The experiment utilizes a 10-m-long, single-mode, commercial EDF with Er3+ ions doping concentration of 200 ppm, co-doped with Al, Ge, and P. The fibre is spooled to a home-made copper cylinder with a diameter of 4 cm and fixed in the dilution refrigerator (LD400, Bluefors), in which the temperature can be cooled below 10 mK. The measured absorption at 1532 nm is 0.35 dB/m at T = 10 mK. The EDF is fused with single-mode fibres for each end, and is exposed to 2000 Gauss magnetic field, the strength of which is optimized by observing the lifetime of Zeeman sublevels of 4I15/2 level. With a magnetic field of 0.2 T, the lifetime reaches 0.278 ± 0.035 s, which ensures the persistent time of AFC (see Supplementary Note 10 for details). On the other hand, the applied magnetic field can eliminate a part of magnetic two-level systems, thus increasing the optical coherence time of erbium ions62. The loss of the whole fibre sample is about 2.5 dB, including bending, splicing, and transmission loss.
Experimental time sequences and procedures
The time sequences are shown in Fig. 2b. During the preparation time of 300 ms, the pump light from a CW-laser operating at 1531.88 nm is prepared into an optical frequency comb with frequency spacing of 15 GHz by an IM and a PM, both of which are driven by 15 GHz microwave signals. The optical frequency comb is sent to another PM, which is driven by an arbitrary waveform generator (AWG) to continuously generate frequency chirping light on each comb ranging from −5 GHz to 5 GHz (total span of 10 GHz). Then the prepared pump light is modulated into 300-ms-long light pulses by an OS, and sent into the EDF to prepare quantum memory with five spectral channels. The setting 200 ms waiting time is to decrease the influence of spontaneously emitted photons from excited ions on the recalled photons from the AFC (see Supplementary Note 11 for more details). During the storage time of 500 ms, another OS turns on. The light from a CW-laser operating at 1540.60 nm is modulated into a light pulse with pulse duration of 300 ps and the repetition rate of 1 MHz (for multiple temporal modes storage, the laser is modulated to 330 light pulses within one cycle of 1 μs, i.e., Tperiod = 1 μs) and sent to PPLN module for the generation of correlated photon-pairs with a bandwidth of ~60 nm. By utilizing DWDMs, signal photons at 1531.88 nm and idler photons at 1549.32 nm with a bandwidth of 100 GHz are filtered out. The signal photons are sent into five-channel quantum memory to filter and to store. After the storage time of Tstorage, the signal photons are recalled from AFCs. Finally, the idler photons and recalled signal photons corresponding to different channels are selected by FBGs and detected by SNSPDs, subsequently performed coincidence analysis in the TDC.
Superconducting nanowire single photon detectors
All detections of single photons are carried out by a set of SNSPDs system provided by PHOTEC Corp. The system consists of SNSPD devices, cryostat system, and electronic control system. The niobium nitride (NbN) SNSPDs, manufactured by Shanghai Institute of Microsystem and Information Technology (SIMIT), operate at ~2.2 K in the cryostat system with a dark counting rate of ~100 Hz and a time jitter of ~100 ps. All detectors have a dead time of less than 50 ns and a detection efficiency of ~60%.
Calculation of cross-correlation function \({g}_{s,i}^{(2)}(0)\)
Considering the counting effective events in m experimental trials, we record the total 3-fold coincidence counts Csi of the trigger signal, idler and signal photons, the coincidence counts Cs (Ci) between signal (idler) photons and trigger signals. With the photon detected probability in each trial calculated as psi = Csi/m, ps = Cs/m, pi = Ci/m, the second-order cross-correlation function \({g}_{s,i}^{(2)}(0)\) is calculated by
It is a strong indication of quantum correlations for photons-pairs if \({g}_{s,i}^{(2)}(0)\gg 2\). According to Cauchy-Schwarz inequality, it also indicates that the auto-correlation function of heralded signal photons is ≪ 1, i.e., these signal photons are denoted as single photons63. For all the coincidence measurements in this paper, the width of coincidence window is 600 ps.
Data availability
The data that support the findings of this study are available from the corresponding author on reasonable request.
References
Kimble, H. J. The quantum internet. Nature 453, 1023–1030 (2008).
Simon, C. Towards a global quantum network. Nat. Photonics 11, 678–680 (2017).
Wehner, S., Elkouss, D. & Hanson, R. Quantum internet: a vision for the road ahead. Science 362, eaam9288 (2018).
Wei, S.-H. et al. Towards real-world quantum networks: a review. Laser Photonics Rev. 16, 2100219 (2022).
Jin, J. et al. Telecom-wavelength atomic quantum memory in optical fiber for heralded polarization qubits. Phys. Rev. Lett. 115, 140501 (2015).
Saglamyurek, E. et al. Quantum storage of entangled telecom-wavelength photons in an erbium-doped optical fibre. Nat. Photonics 9, 83–87 (2015).
Collins, O., Jenkins, S., Kuzmich, A. & Kennedy, T. Multiplexed memory-insensitive quantum repeaters. Phys. Rev. Lett. 98, 060502 (2007).
Simon, C. et al. Quantum repeaters with photon pair sources and multimode memories. Phys. Rev. Lett. 98, 190503 (2007).
Lvovsky, A. I., Sanders, B. C. & Tittel, W. Optical quantum memory. Nat. Photonics 3, 706–714 (2009).
Simon, C. et al. Quantum memories. Eur. Phys. J. D 58, 1–22 (2010).
Heshami, K. et al. Quantum memories: emerging applications and recent advances. J. Mod. Optic. 63, 2005–2028 (2016).
De Riedmatten, H., Afzelius, M., Staudt, M. U., Simon, C. & Gisin, N. A solid-state light–matter interface at the single-photon level. Nature 456, 773–777 (2008).
Usmani, I., Afzelius, M., De Riedmatten, H. & Gisin, N. Mapping multiple photonic qubits into and out of one solid-state atomic ensemble. Nat. Commun. 1, 12 (2010).
Bonarota, M., Le Gouët, J. & Chaneliere, T. Highly multimode storage in a crystal. New J. Phys. 13, 013013 (2011).
Hosseini, M., Sparkes, B. M., Campbell, G., Lam, P. K. & Buchler, B. C. High efficiency coherent optical memory with warm rubidium vapour. Nat. Commun. 2, 174 (2011).
Gündoğan, M., Mazzera, M., Ledingham, P. M., Cristiani, M. & de Riedmatten, H. Coherent storage of temporally multimode light using a spin-wave atomic frequency comb memory. New J. Phys. 15, 045012 (2013).
Tang, J.-S. et al. Storage of multiple single-photon pulses emitted from a quantum dot in a solid-state quantum memory. Nat. Commun. 6, 8652 (2015).
Jobez, P. et al. Towards highly multimode optical quantum memory for quantum repeaters. Phys. Rev. A 93, 032327 (2016).
Tiranov, A. et al. Temporal multimode storage of entangled photon pairs. Phys. Rev. Lett. 117, 240506 (2016).
Laplane, C., Jobez, P., Etesse, J., Gisin, N. & Afzelius, M. Multimode and long-lived quantum correlations between photons and spins in a crystal. Phys. Rev. Lett. 118, 210501 (2017).
Wen, Y. et al. Multiplexed spin-wave–photon entanglement source using temporal multimode memories and feedforward-controlled readout. Phys. Rev. A 100, 012342 (2019).
Heller, L., Farrera, P., Heinze, G. & de Riedmatten, H. Cold-atom temporally multiplexed quantum memory with cavity-enhanced noise suppression. Phys. Rev. Lett. 124, 210504 (2020).
Liu, X. et al. Heralded entanglement distribution between two absorptive quantum memories. Nature 594, 41–45 (2021).
Lago-Rivera, D., Grandi, S., Rakonjac, J. V., Seri, A. & de Riedmatten, H. Telecom-heralded entanglement between multimode solid-state quantum memories. Nature 594, 37–40 (2021).
Su, M.-X. et al. On-demand multimode optical storage in a laser-written on-chip waveguide. Phys. Rev. A 105, 052432 (2022).
Ortu, A. et al. Multimode capacity of atomic-frequency comb quantum memories. Quantum Sci. Technol. 7, 035024 (2022).
Businger, M. et al. Non-classical correlations over 1250 modes between telecom photons and 979-nm photons stored in 171yb3+: Y2sio5. Nat. Commun. 13, 1–8 (2022).
Sinclair, N. et al. Spectral multiplexing for scalable quantum photonics using an atomic frequency comb quantum memory and feed-forward control. Phys. Rev. Lett. 113, 053603 (2014).
Saglamyurek, E. et al. A multiplexed light-matter interface for fibre-based quantum networks. Nat. Commun. 7, 11202 (2016).
Askarani, M. F. et al. Long-lived solid-state optical memory for high-rate quantum repeaters. Phys. Rev. Lett. 127, 220502 (2021).
Lan, S.-Y. et al. A multiplexed quantum memory. Opt. Express 17, 13639–13645 (2009).
Grodecka-Grad, A., Zeuthen, E. & Sørensen, A. S. High-capacity spatial multimode quantum memories based on atomic ensembles. Phys. Rev. Lett. 109, 133601 (2012).
Nicolas, A. et al. A quantum memory for orbital angular momentum photonic qubits. Nat. Photonics 8, 234–238 (2014).
Ding, D.-S. et al. Quantum storage of orbital angular momentum entanglement in an atomic ensemble. Phys. Rev. Lett. 114, 050502 (2015).
Zhou, Z.-Q. et al. Quantum storage of three-dimensional orbital-angular-momentum entanglement in a crystal. Phys. Rev. Lett. 115, 070502 (2015).
Parniak, M. et al. Wavevector multiplexed atomic quantum memory via spatially-resolved single-photon detection. Nat. Commun. 8, 2140 (2017).
Pu, Y. et al. Experimental realization of a multiplexed quantum memory with 225 individually accessible memory cells. Nat. Commun. 8, 15359 (2017).
Chrapkiewicz, R., Dabrowski, M. & Wasilewski, W. High-capacity angularly multiplexed holographic memory operating at the single-photon level. Phys. Rev. Lett. 118, 063603 (2017).
Tian, L. et al. Spatial multiplexing of atom-photon entanglement sources using feedforward control and switching networks. Phys. Rev. Lett. 119, 130505 (2017).
Yang, T.-S. et al. Multiplexed storage and real-time manipulation based on a multiple degree-of-freedom quantum memory. Nat. Commun. 9, 3407 (2018).
Seri, A. et al. Quantum storage of frequency-multiplexed heralded single photons. Phys. Rev. Lett. 123, 080502 (2019).
Duan, L.-M., Lukin, M. D., Cirac, J. I. & Zoller, P. Long-distance quantum communication with atomic ensembles and linear optics. Nature 414, 413–418 (2001).
Turukhin, A. et al. Observation of ultraslow and stored light pulses in a solid. Phys. Rev. Lett. 88, 023602 (2001).
Reim, K. et al. Towards high-speed optical quantum memories. Nat. Photonics 4, 218–221 (2010).
Nunn, J. et al. Multimode memories in atomic ensembles. Phys. Rev. Lett. 101, 260502 (2008).
Afzelius, M., Simon, C., De Riedmatten, H. & Gisin, N. Multimode quantum memory based on atomic frequency combs. Phys. Rev. A 79, 052329 (2009).
Zarkeshian, P. et al. Entanglement between more than two hundred macroscopic atomic ensembles in a solid. Nat. Commun. 8, 906 (2017).
Lefebvre, P. et al. Compact energy–time entanglement source using cascaded nonlinear interactions. J. Opt. Soc. Am. B 38, 1380–1385 (2021).
Zhang, Z. et al. High-performance quantum entanglement generation via cascaded second-order nonlinear processes. npj Quantum Inform. 7, 123 (2021).
Yu, H. et al. Spectrally multiplexed indistinguishable single-photon generation at telecom-band. Photonics Res. 10, 1417–1429 (2022).
Saglamyurek, E. et al. An integrated processor for photonic quantum states using a broadband light–matter interface. New J. Phys. 16, 065019 (2014).
Chou, C., Polyakov, S., Kuzmich, A. & Kimble, H. Single-photon generation from stored excitation in an atomic ensemble. Phys. Rev. Lett. 92, 213601 (2004).
Fortier, T. & Baumann, E. 20 years of developments in optical frequency comb technology and applications. Commun. Phys. 2, 153 (2019).
Veissier, L. et al. Optical decoherence and spectral diffusion in an erbium-doped silica glass fiber featuring long-lived spin sublevels. Phys. Rev. B 94, 195138 (2016).
Staudt, M. U. et al. Investigations of optical coherence properties in an erbium-doped silicate fiber for quantum state storage. Opt. Commun. 266, 720–726 (2006).
Baldit, E. et al. Identification of Λ-like systems in Er3+:Y2SiO5 and observation of electromagnetically induced transparency. Phys. Rev. B 81, 144303 (2010).
Rakonjac, J. V. et al. Entanglement between a telecom photon and an on-demand multimode solid-state quantum memory. Phys. Rev. Lett. 127, 210502 (2021).
Rančić, M., Hedges, M. P., Ahlefeldt, R. L. & Sellars, M. J. Coherence time of over a second in a telecom-compatible quantum memory storage material. Nat. Phys. 14, 50–54 (2018).
Jiang, M.-H. et al. Quantum storage of entangled photons at telecom wavelengths in a crystal. Nat. Commun. 14, 6995 (2023).
Afzelius, M. & Simon, C. Impedance-matched cavity quantum memory. Phys. Rev. A 82, 022310 (2010).
Moiseev, S. A., Andrianov, S. N. & Gubaidullin, F. F. Efficient multimode quantum memory based on photon echo in an optimal qed cavity. Phys. Rev. A 82, 022311 (2010).
Macfarlane, R., Sun, Y., Sellin, P. & Cone, R. Optical decoherence in Er3+-doped silicate fiber: evidence for coupled spin-elastic tunneling systems. Phys. Rev. Lett. 96, 033602 (2006).
Bashkansky, M., Vurgaftman, I., Pipino, A. C. & Reintjes, J. Significance of heralding in spontaneous parametric down-conversion. Phys. Rev. A 90, 053825 (2014).
Saglamyurek, E. et al. Broadband waveguide quantum memory for entangled photons. Nature 469, 512–515 (2011).
Davidson, J. H., Lefebvre, P., Zhang, J., Oblak, D. & Tittel, W. Improved light-matter interaction for storage of quantum states of light in a thulium-doped crystal cavity. Phys. Rev. A 101, 042333 (2020).
Clausen, C. et al. Quantum storage of photonic entanglement in a crystal. Nature 469, 508–511 (2011).
Askarani, M. F. et al. Storage and reemission of heralded telecommunication-wavelength photons using a crystal waveguide. Phys. Rev. Appl. 11, 054056 (2019).
Zhang, X.-Y. et al. Storage of 147 temporal modes of telecom-band single photon with fiber-pigtailed Er3+:LiNbO3 waveguide. In CLEO: Science and Innovations, JTh6A–9 (Optica Publishing Group, 2022).
Acknowledgements
This work was supported by the National Key Research and Development Program of China (Nos. 2018YFA0307400, 2018YFA0306102), National Natural Science Foundation of China (Nos. 61775025, 91836102, U19A2076, 12004068), Innovation Program for Quantum Science and Technology (No. 2021ZD0301702), Sichuan Science and Technology Program (Nos. 2021YFSY0062, 2021YFSY0063, 2021YFSY0064, 2022YFSY0061, 2022YFSY0063, 2023YFSY0058, 2023YFSY0060), China Postdoctoral Science Foundation (Nos. 2020M683275, 2021T140093).
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D.O., G.G., and Q.Z. conceived and supervised the project. S.W. and B.J. mainly carried out the experiment and collected the experimental data with help of other authors. H.L., L.Y. and Z.W. developed and maintained the SNSPDs used in the experiment. S.W., B.J. and Q.Z. analyzed the data. S.W., B.J., D.O. and Q.Z. wrote the manuscript with inputs from all other authors. All authors have given approval for the final version of the manuscript.
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Wei, SH., Jing, B., Zhang, XY. et al. Quantum storage of 1650 modes of single photons at telecom wavelength. npj Quantum Inf 10, 19 (2024). https://doi.org/10.1038/s41534-024-00812-1
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DOI: https://doi.org/10.1038/s41534-024-00812-1
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