Abstract
Nonreciprocal devices, such as isolators, are of great importance for optical communication and optical information processing. To bypass the limitation of a strong magnetic field imposed by the traditional Faraday magneto-optic effect, many alternative mechanisms have been proposed to demonstrate magnetic-free nonreciprocity. However, limited by the drive-induced noise, the noiseless isolator capable of working in the quantum regime has yet to be realized in the experiment. Here, we show a noiseless all-optical isolator with genuine single photons in hot atoms. We experimentally study this mechanism using an open V-type level scheme and demonstrate a low insertion loss of 0.6 dB and high isolation of 30.3 dB with bandwidth up to hundreds of megahertz. Furthermore, the nonreciprocal direction can be truly reversed only by tuning the frequency of the pump laser with the same setup. Our scheme relies on widely used optical technology and is thus universal and robust.
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Introduction
Reciprocity, deriving from time-reversal symmetry, is a fundamental physical principle in the fields of electromagnetism, optics, and acoustics. In many practical applications, nonreciprocal devices, such as diodes in electronic circuits, are essential and powerful. In optics, the optical nonreciprocal devices, such as isolators, also play an irreplaceable role in both classical optical communications and quantum applications1,2. Optical nonreciprocity (ONR) is intrinsically difficult because of the time-reversal symmetry of light-matter interactions3. The traditional way of breaking the time-reversal symmetry of light is built on the magneto-optic effect4. It requires bulky magneto-optical materials and an external magnetic field and thus has limitations for on-chip or magnetic-sensitive quantum applications.
To bypass this limitation, considerable theoretical and experimental efforts have been made to explore the magnetic-free ONRs by using various physical mechanisms, including nonlinear effects5,6,7,8, spatiotemporal modulation of permittivity9,10,11,12,13,14, optomechanical interactions15,16,17,18, moving Bragg lattices in atoms19,20,21, chiral quantum systems22,23,24, and random thermal-motion of atoms25,26,27,28,29,30,31. As we know, most of the reported schemes work in the classical region with weak coherent light. However, when it comes to quantum applications, where the information is encoded in individual photons, one basic requirement is that the ONR must be extended to genuine single photons. For single-photon isolators, it is not only required to have unidirectional transmittance but also more importantly, to maintain the quantum characteristics of input single photons from the selected direction. That is, the system should not introduce much additional noise, including the classical background noise31 and quantum noise32.
Many theoretical schemes have been proposed to realize single-photon ONRs22,33,34,35,36,37,38. Nonetheless, to date, only one experimental realization of an ONR with genuine single photons in ladder-type electromagnetically induced transparency39 has been reported. To overcome the rapid dephasing of hot atoms, a strong drive field is necessary, which inevitably brings background noise photons to the signal due to nonlinear parametric processes. In addition, for such a coherent interaction, the amplitude and phase noise from the strong drive field will also induce nonnegligible quantum noise40,41. This deleterious noise induced by the strong drive field can damage the quantum characteristics of single photons. Recently, Hu et al. proposed a noiseless isolator via the incoherent population transfer process with a relatively low laser intensity, which can efficiently reduce the drive-induced noise31. However, they only demonstrated the quantum statistic properties of the scheme via the weak coherent laser and pseudothermal light source in their experiment. Until now, there has been no experimental demonstration of a noiseless ONR with genuine single photons, for the most part, because of the difficulty in filtering drive-induced background noise photons from extremely weak single-photon signals.
Here, we demonstrate a noiseless nonreciprocal proposal with genuine single photons based on incoherent optical pumping. Nonreciprocity is achieved utilizing velocity-selection-based incoherent population transfer. For hot atoms, when considering the Doppler effect, the optical pump process is dependent on the velocity of the atoms and the frequency of the pump field. If the pump field has proper detuning, it will induce an asymmetrical atomic population of the ground state which then leads to nonreciprocal absorption. Single-photon signals from one direction can pass through the atoms with negligible loss, while signals in the opposite direction will be absorbed. Due to the low intensity of the pump field and the great difference in frequency between the signal photons and the pump field, it is relatively easier to eliminate the pump-induced classical background noises in the experiment. More importantly, since the pump field only induces the incoherent population transfer, no quantum noise from the pump laser and atoms will be brought to the signal photons. In experiment, we demonstrate the noiseless properties by measuring the quantum-statistic conservation of the input genuine single photons and achieve an ultralow insertion loss of approximately 0.6 dB and high isolation of 30.3 dB with just a 40 mW pump field. Furthermore, the nonreciprocal bandwidth can be hundreds of megahertz, and the nonreciprocal direction can be reversed by simply reversing the detuning sign of the pump field.
Results and discussion
Basic principles
The mechanism and experimental setup of the optical isolator are shown in Fig. 1 which includes the single-photons generation system and ONR system. For the single-photons generation system, the photons are generated through the spontaneous four-wave mixing process42. In the presence of two counterpropagate coupling lasers, a pair of correlated photons (Stokes and Anti-Stokes) is generated in a paraffin-coated hot 87Rb vapour cell, as shown in Fig. 1a. The relevant energy-level structure is shown in Fig. 1b. The generated photon pairs are collected by two opposing single-mode fibres with efficiencies of approximately 78% and 75%. The Stokes photons are detected by a single-photon counting module, and the heralded Anti-Stokes photons are collected to demonstrate the ONR in the forward and backward direction, as shown in Fig. 1c, and then detected by another single-photon counting module. For the ONR system, we use an open V-type atomic system consisting of a ground state \(\vert {5}^{2}{S}_{1/2},F=1\rangle (\vert 1\rangle )\) and two excited states \(\vert {5}^{2}{P}_{3/2},F=2\rangle (\vert 2\rangle )\) and \(\vert {5}^{2}{P}_{1/2},F=2\rangle (\vert 3\rangle )\), see in Fig. 1d. A pump field, which propagates along + x in the lab frame, couples the atomic transition of \(\left\vert 1\right\rangle\) and \(\left\vert 2\right\rangle\) with a detuning Δp. The Anti-Stokes photons, which propagate along the forward ( + x) or backward ( − x) direction, couple the atomic transition of \(\left\vert 1\right\rangle\) and \(\left\vert 3\right\rangle\) with a detuning Δs. For hot atoms, the random thermal-motion can create a Doppler shift. If an atom is moving toward or away from a laser source, it receives radiation that is blueshifted or redshifted. In the absence of the pump field, the forward- and backward-propagating signal photons are resonantly absorbed by the group of atoms with velocities v = − Δs/k and v = Δs/k, respectively, where k is the wave vector and v is the atomic velocity. Since the velocity of atoms satisfies Maxwell’s velocity distribution and is perfectly symmetrical, the population of the ground state is also symmetrical. Hence, the absorption of the atomic system is independent of the propagation direction of signal photons. That is, the atomic system is reciprocal to the signal photons. To achieve ONR, one needs to break the symmetry of the ground state population.
Then, we would like to understand what happens when a pump field propagates through the vapour cell. The pump field is applied to resonate with the transition of \(\vert {5}^{2}{S}_{1/2},F=1\rangle \to \vert {5}^{2}{P}_{3/2},F=1\rangle\) and thus red detuned from the transition \(\vert {5}^{2}{S}_{1/2},F=1\rangle \to \vert {5}^{2}{P}_{3/2},F=2\rangle\) by Δp = 2π × 157 MHz. It resonantly interacts with the group of atoms with a velocity of v = − Δp/k and leads to an incoherent population transfer from the ground state \(\left\vert 1\right\rangle\) to another metastable state \(\vert {5}^{2}{S}_{1/2},F=2\rangle\). However, for this group of atoms with a velocity of v = Δp/k, the incoherent pumping effect is ignorable. Therefore, the population of the atoms with v = − Δp/k and v = Δp/k in the ground state becomes different. When Δs = Δp, for the forward signal photons, the population it ’feels’ is empty, as shown in Fig. 1e. In contrast, the backward one ’feels’ a full population. As a result, the forward signal photons can pass the atoms with ignorable absorption, while, the backward signal photons are strongly absorbed.
Optical pumping, in physics, is the use of light energy to elevate the atoms of the system from one energy level to another. The velocity selection of optical pumping has been used for the saturated absorption spectrum43 and laser cooling44. Their objective is to overcome the Doppler-broadening limit by providing for a two-photon interaction that only occurs for atoms with a lab frame velocity very near zero. Although the basic principles are straightforward, we will only be able to unleash the full power of optical pumping by carefully attending to many details. In our scheme, the velocity-selection feature is used to break the symmetry of the ground state population and control the transmission of single photons. That is, the propagation direction of the signal photons is selected by the optical pumping process. The tremendous impact of the velocity-selective optical population effects suggests that our approach to ONR can be powerful as well. In addition, the nonreciprocal direction of our scheme is truly reversible, which can be achieved by simply tuning the frequency detuning of the pump field with the same frequency of the single photons.
Optical isolation
We first use a weak coherent probe field to scan the forward- and backward-propagation transmission spectra with varying pump field intensity, as shown in Fig. 2a. For the forward case, the transmission spectra show a high peak at a detuning of Δs = 2π × 157 MHz. As the intensity of the pump field increases, both the transmittance and bandwidth gradually increase. In contrast, the backward one always has nearly zero transmission. For the genuine single-photon experiment. We characterize the single-photon transmission by measuring the coincidence counts for the input Anti-Stokes photons, as shown in Fig. 2b. Additionally, we can see that as the pump field intensity increases the forward coincidence counts significantly increase. In contrast, the backward coincidence counts approach zero, revealing a strong single-photon ONR.
We define the single-photon transmission as Tf(b) = CCf(b)/CCin, with CCin and CCf(b) representing the total integral coincidence counts for the initial input signal field and that after the forward (backward) propagation. Figure 3a shows the measured forward and backward single-photon transmissions as a function of the pump field Intensity. As the pump field intensity increases from 5 mW to 40 mW, the forward-propagation transmission increases from 45.3% to 87.1%, whereas the backward-propagation transmission always vanishingly small. Under the condition of pump field intensity to 40 mW, we obtain an ultralow insertion loss of − 10log(Tf) = 0.6 dB and a strong isolation of − 10log(Tb) = 30.3 dB. For single-photon ONR, to obtain the best transmission, the bandwidth of the transmission peak should be much larger than the linewidth of the single photon itself. Figure 3b shows the measured bandwidth of the transmission peak for different pump field intensities. As the intensity increases, the bandwidth increases from 2π × 43 MHz to 2π × 175 MHz.
Noise performance
The quantum characteristics of signal photons can be characterized by the second-order cross-correlation function \({g}_{a,as}^{(2)}(\tau )\). Figure 4a shows the measured \({g}_{a,as}^{(2)}(\tau )\) of the transmitted photons at a pump field intensity of 40 mW. The \({g}_{a,as}^{(2)}(\tau )\) of the input signal photons is shown in Fig. 4b. We can see that the maximum value of \({g}_{a,as}^{(2)}(\tau )\) for the forward signal photon is slightly larger than the input value. This is because the transmission spectra have limited bandwidth, and it can be seen as a narrowband filter that can filter the uncorrelated background photons. From the Fourier transform of \(\sqrt{{g}_{a,as}^{(2)}(\tau )-1}\)45, the calculated linewidth of the input single photons is approximately 2π × 7.3 MHz. We can see that the maximum bandwidth of the transmission peak is approximately 24 times the linewidth of the input single photons. Hence, it can ensure that the single-photon signal passes through the atomic medium. Expectedly, for the forward signal photon, its property is well preserved. In contrast, in the backward case, \({g}_{a,as}^{(2)}(\tau )\) is near 1, which means that the quantum characteristics is strongly broken. Moreover, we also measured the classical noise by blocking the signal while keeping the pump field on, see the blue line in Fig. 4b. The accidental coincidence from noise is measured to be below 0.1%.
To further evaluate the quantum characteristics of the single photons, we can use the heralded autocorrelation parameter α to benchmark the single-photon property46. When α < 0.5, it indicates a near-single-photon character. In our experiment, the input single photons have α = 0.091 ± 0.004. After passing the nonreciprocal system in the forward direction, it becomes α = 0.093 ± 0.007. The result indicates perfect single-photon property preservation. In addition, we measure the Cauchy-Schwarz inequality R, which can be used to characterize the nonclassical correlation of the single photons. If R > 1, the photons are nonclassically correlated. In the absence of the nonreciprocal system, the measured parameter is 127. After the photons pass through the atomic system in the forward direction, we obtain R = 129. In contrast, we have R = 0.27 in the backward case, indicating the strongly broken nonclassical correlation. All the above results prove that our system does not introduce additional quantum noise.
Reversed ONR
Reversible ONRs have important applications in reconfigurable nonreciprocal information processing. A practical reversible isolator needs to be able to work with the same input signals with the same performance index. In the work of Dong et al.39, the nonreciprocal direction of the signals can be reversed by tuning the frequency of the control field. As reported, when the interaction varies from the electromagnetically induced transparency regime to the Raman regime, the frequency of the signal photons also needs to be tuned. In addition, the nonreciprocal bandwidth of the Raman process is almost the same order of magnitude as that of the single-photon signal generated from the atomic system. Thus, for genuine single photons, the isolation will be very poor. Thus, the reversible nonreciprocity may not be suitable for practical applications. In contrast, in our scheme, the nonreciprocal direction can be reversed by slightly tuning the frequency of the pump field but with the same frequency of the single photons. Figure 5 shows the measured forward and backward transmission with Δp = 157 MHz (a) and Δp = − 157 MHz (b), respectively. Here, the pump field intensity is 40 mW and the temperature is 80 °C. For the two nonreciprocities, the frequency difference is just a few hundred megahertz and can be easily achieved using an acousto-optic modulator. Moreover, the two different nonreciprocal directions are based on the same physical mechanism, and they have the same transmission and isolation.
Conclusion
In summary, we have experimentally demonstrated a noiseless single-photon isolator at room temperature. We exploit an incoherent pumping-induced asymmetric ground state population to realize the ONR. Our approach is motivated by clear physical insights, and it is robust and easy to implement. A low insertion loss of approximately 0.6 dB and high isolation of 30.3 dB with a bandwidth of a few hundred megahertz are achieved in the experiment. Different from previous experiments, our scheme can operate in the quantum regime without additional quantum noise. The quantum characteristics of the single photons can be well maintained in one direction, and be strongly broken in the opposite direction. The nonreciprocity is reconfigurable, and its direction can be reversed by simply tuning the frequency of the pump field without changing the frequency of the signal photons. The demonstration of a magnetic-free, noiseless, and reconfigurable single-photon isolator at room temperature may have potential applications in quantum networks and integrable quantum information processing since hot atoms can be miniaturized47, integrated onto chips using one-dimensional waveguide structures48, and mass-produced.
Methods
Experimental setup
For the four-wave mixing process, the two coupling lasers are supplied by two narrow-linewidth tunable diode lasers with wavelengths of 780 nm (Coupling 1) and 795 nm (Coupling 2). The coupling intensities are 10 mW and 40 mW, respectively. The two coupling fields have the same 1/e2 beam diameter of 2.4 mm. The coupling field 1 is red detuned by 2π × 2.7 GHz from the transition \(\vert {5}^{2}{S}_{1/2},F=1\rangle \to \vert {5}^{2}{P}_{3/2},F=2\rangle\). The coupling field 2 is red detuned from the transition \(\vert {5}^{2}{S}_{1/2},F=2\rangle \to \vert {5}^{2}{P}_{1/2},F=2\rangle\) by 2π × 157 MHz. The photon pairs are collected with a small angle of 0.5°. The Rb vapour cell has a length of 7.5 cm and is heated to 40 °C in the experiment. Before the Stokes photons enter the single-photon counting module (Excelitas SPCM-AQRH-16-APC), a 780 nm narrowband filter and a Fabry-Perot etalon (85% transmittance and 60 MHz bandwidth) are used to filter the stray coupling fields. The Anti-Stokes photons are focused by a lens with a focal length of 250 mm onto another 87Rb vapour cell, which also has a length of 7.5 cm and is heated to 80 °C, for the demonstration of the ONR. The pump laser is supplied by another narrow-linewidth tunable diode laser with a wavelength of 780 nm. It is vertically polarized and can be reflected by the polarization beam splitter with an extinction ratio of approximately 35 dB. The Anti-Stokes photons are then collected by another single-mode fibre with an efficiency of 85%. To further filter the pump field, a 795 nm narrowband filter and another Fabry-Perot etalon (90% transmittance and 60 MHz bandwidth) are inserted before Anti-Stokes photons enter the single-photon counting module. This combination of polarization control, single-mode fibre, narrowband filter and Fabry-Perot etalon suppresses the pump field up to 120 dB, which makes the genuine single-photon experiment possible.
Characterization of the heralded single-photon
The second-order cross-correlation function of single photons is defined as \({g}_{s,as}^{(2)}(\tau )=\langle {\hat{a}}_{s}^{{{{\dagger}}} }(t){\hat{a}}_{as}^{{{{\dagger}}} }(t+\tau ){\hat{a}}_{as}(t+\tau ){\hat{a}}_{s}(t)\rangle /[\langle {\hat{a}}_{s}^{{{{\dagger}}} }(t){\hat{a}}_{s}(t)\rangle \langle {\hat{a}}_{as}^{{{{\dagger}}} }(t+\tau ){\hat{a}}_{as}(t+\tau )\rangle ]\), where \({\hat{a}}_{s}^{{{{\dagger}}} }(t)({\hat{a}}_{as}^{{{{\dagger}}} }(t+\tau ))\) and \({\hat{a}}_{s}(t)({\hat{a}}_{as}(t+\tau ))\) denote the photon creation and annihilation operators for the Stokes (Anti-Stokes) photon at time t(t + τ). The heralded autocorrelation parameter α is defined as α = P1P123/P12P13. We define that the generated Stokes photons are collected by the port 1. The Anti-Stokes photons passed through the nonreciprocal system are separated into two equal parts via a fiber beam splitter and then collected by the port 2 and 3. Thus, P1 is the count of port 1, P12(P13) and is the twofold coincidence count between port 1 and 2(3), and P123 is the threefold coincidence count between the port 1, 2, and 3. The Cauchy-Schwarz inequality is defined as \(R={[{g}_{s,as}^{(2)}(\tau )]}^{2}/{g}_{s,s}^{(2)}(0){g}_{as,as}^{(2)}(0)\), with \({g}_{s,s}^{(2)}\) and \({g}_{as,as}^{(2)}\) being the autocorrelation functions of Stokes and Anti-Stokes photons, respectively.
Data availability
The data that support the plots within this paper and other findings of this study are available from the corresponding authors upon reasonable request.
Change history
21 December 2023
A Correction to this paper has been published: https://doi.org/10.1038/s42005-023-01505-5
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Acknowledgements
We acknowledge the support of the National Natural Science Foundation of China (Grants No. 12004112, 12034007, and 11974109), Shanghai Natural Science Foundation (Grant No. 17ZR1442700) and Shanghai Sailing Program (Grant No. 20YF1410800). The work is also sponsored by “Chenguang Program” supported by Shanghai Education Development Foundation and Shanghai Municipal Education Commission (Grant No. 20CG35).
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S.Z. and Y.N. contributed to the original idea, and supervised the experiment. S.Z. and Y.Z. built the experimental setup and carried out the measurements. They contributed equally to this work. S.G. supervised the whole project. All authors contributed to discussions of the results and writing of the manuscript.
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Zhang, S., Zhan, Y., Gong, S. et al. Noiseless single-photon isolator at room temperature. Commun Phys 6, 33 (2023). https://doi.org/10.1038/s42005-023-01141-z
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DOI: https://doi.org/10.1038/s42005-023-01141-z
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