Your search keyword '"Lodahl, P."' showing total 558 results

1. Resonant Energy Transfer and Collectively Driven Emitters in Waveguide QED

Author

van Diepen, Cornelis Jacobus, Angelopoulou, Vasiliki, Sandberg, Oliver August Dall'Alba, Tiranov, Alexey, Wang, Ying, Scholz, Sven, Ludwig, Arne, Sørensen, Anders Søndberg, and Lodahl, Peter

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Waveguide quantum electrodynamics (QED) has opened a new frontier in quantum optics, which enables the radiative coupling of distantly located emitters via the spatially extended waveguide mode. This coupling leads to modified emission dynamics and previous work has reported the observation of increased intensity correlations (an antidip) when probing the resonance response of multiple emitters. However, the interference between independent emitters has been shown to lead to a similar response. Here, we directly observe resonant energy transfer between two distant quantum emitters by recording an antidip in the intensity correlations, $g^{(2)}(\tau)$, while driving only one of the emitters. Under the condition that only a single emitter is driven, the antidip in photon coincidences is a distinctive signature of emitter-emitter coupling, which enables the transfer of energy from the driven to the undriven emitter. Interestingly, the observed mechanism is a long-range and waveguide-engineered version of resonant F\"orster transfer, which is responsible for the transport of energy between chlorophylls in the photosynthesis. Building on the established coupling, we demonstrate collective driving of the coupled emitter pair. Specifically, we control the relative driving phase and amplitude of the emitters and apply this collective excitation scheme to selectively populate the long-lived subradiant state. This results in suppressed emission, i.e. the peculiar situation where driving two emitters as opposed to one effectively reduces the probability of photon emission. Our work presents novel emission regimes and excitation schemes for a multi-emitter waveguide QED system. These can be exploited to deterministically generate emitter-emitter entanglement and advanced photonic states providing robustness against losses for photonic quantum computation and quantum communication., Comment: 12 pages, 9 figures, including appendices

Published

2025

2. Programmable Nonlinear Quantum Photonic Circuits

Author

Nielsen, Kasper H., Wang, Ying, Deacon, Edward, Sund, Patrik I., Liu, Zhe, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Sørensen, Anders S., Paesani, Stefano, and Lodahl, Peter

Subjects

Quantum Physics

Abstract

The lack of interactions between single photons prohibits direct nonlinear operations in quantum optical circuits, representing a central obstacle in photonic quantum technologies. Here, we demonstrate multi-mode nonlinear photonic circuits where both linear and direct nonlinear operations can be programmed with high precision at the single-photon level. Deterministic nonlinear interaction is realized with a tunable quantum dot embedded in a nanophotonic waveguide mediating interactions between individual photons within a temporal linear optical interferometer. We demonstrate the capability to reprogram the nonlinear photonic circuits and implement protocols where strong nonlinearities are required, in particular for quantum simulation of anharmonic molecular dynamics, thereby showcasing the new key functionalities enabled by our technology., Comment: 8 pages, 3 figures

Published

2024

3. Purifying photon indistinguishability through quantum interference

Author

Faurby, Carlos F. D., Carosini, Lorenzo, Cao, Huan, Sund, Patrik I., Hansen, Lena M., Giorgino, Francesco, Villadsen, Andrew B., Hoven, Stefan N. van den, Lodahl, Peter, Paesani, Stefano, Loredo, Juan C., and Walther, Philip

Subjects

Quantum Physics

Abstract

Indistinguishability between photons is a key requirement for scalable photonic quantum technologies. We experimentally demonstrate that partly distinguishable single photons can be purified to reach near-unity indistinguishability by the process of quantum interference with ancillary photons followed by heralded detection of a subset of them. We report on the indistinguishability of the purified photons by interfering two purified photons and show improvements in the photon indistinguishability of $2.774(3)$\% in the low-noise regime, and as high as $10.2(5)$ \% in the high-noise regime., Comment: 14 pages, 7 figures

Published

2024

4. Photonic fusion of entangled resource states from a quantum emitter

Author

Meng, Yijian, Faurby, Carlos F. D., Chan, Ming Lai, Sund, Patrik I., Liu, Zhe, Wang, Ying, Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Sørensen, Anders S., Paesani, Stefano, and Lodahl, Peter

Subjects

Quantum Physics

Abstract

Fusion-based photonic quantum computing architectures rely on two primitives: i) near-deterministic generation and control of constant-size entangled states and ii) probabilistic entangling measurements (photonic fusion gates) between entangled states. Here, we demonstrate these key functionalities by fusing resource states deterministically generated using a solid-state spin-photon interface. Repetitive operation of the source leads to sequential entanglement generation, whereby curiously entanglement is created between the quantum states of the same spin at two different instances in time. Such temporal multiplexing of photonic entanglement provides a resource-efficient route to scaling many-body entangled systems with photons.

Published

2023

5. A quantum dot coupled to a suspended-beam mechanical resonator: from the unresolved- to the resolved-sideband regime

Author

Spinnler, Clemens, Nguyen, Giang N., Wang, Ying, Erbe, Marcel, Javadi, Alisa, Zhai, Liang, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, Midolo, Leonardo, and Warburton, Richard J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

We present experiments in which self-assembled InAs quantum dots are coupled to a thin, suspended-beam GaAs resonator. The quantum dots are driven resonantly and the resonance fluorescence is detected. The narrow quantum-dot linewidths, just a factor of three larger than the transform limit, result in a high sensitivity to the mechanical motion. We show that one quantum dot couples to eight mechanical modes spanning a frequency range from $30$ to $600~\mathrm{MHz}$: one quantum dot provides an extensive characterisation of the mechanical resonator. The coupling spans the unresolved-sideband to the resolved-sideband regimes. Finally, we present the first detection of thermally-driven phonon sidebands (at $4.2~\mathrm{K}$) in the resonance-fluoresence spectrum.

Published

2023

6. A single-photon emitter coupled to a phononic-crystal resonator in the resolved-sideband regime

Author

Spinnler, Clemens, Nguyen, Giang N., Wang, Ying, Zhai, Liang, Javadi, Alisa, Erbe, Marcel, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, Midolo, Leonardo, and Warburton, Richard J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

A promising route towards the heralded creation and annihilation of single-phonons is to couple a single-photon emitter to a mechanical resonator. The challenge lies in reaching the resolved-sideband regime with a large coupling rate and a high mechanical quality factor. We achieve all of this by coupling self-assembled InAs quantum dots to a small-mode-volume phononic-crystal resonator with mechanical frequency $\Omega_\mathrm{m}/2\pi = 1.466~\mathrm{GHz}$ and quality factor $Q_\mathrm{m} = 2.1\times10^3$. Thanks to the high coupling rate of $g_\mathrm{ep}/2\pi = 2.9~\mathrm{MHz}$, and by exploiting a matching condition between the effective Rabi and mechanical frequencies, we are able to observe the interaction between the two systems. Our results represent a major step towards quantum control of the mechanical resonator via a single-photon emitter.

Published

2023

7. Deterministic photon source of genuine three-qubit entanglement

Author

Meng, Yijian, Chan, Ming Lai, Nielsen, Rasmus B., Appel, Martin H., Liu, Zhe, Wang, Ying, Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Tiranov, Alexey, Sørensen, Anders S., and Lodahl, Peter

Subjects

Quantum Physics

Abstract

Deterministic photon sources allow long-term advancements in quantum optics. A single quantum emitter embedded in a photonic resonator or waveguide may be triggered to emit one photon at a time into a desired optical mode. By coherently controlling a single spin in the emitter, multi-photon entanglement can be realized. We demonstrate a deterministic source of three-qubit entanglement based on a single electron spin trapped in a quantum dot embedded in a planar nanophotonic waveguide. We implement nuclear spin narrowing to increase the spin dephasing time to $T_2^* \simeq 33$ ns, which enables high-fidelity coherent optical spin rotations, and realize a spin-echo pulse sequence for sequential generation of high-fidelity spin-photon and spin-photon-photon entanglement. The emitted photons are highly indistinguishable, which is a key requirement for subsequent photon fusions to realize larger entangled states. This work presents a scalable deterministic source of multi-photon entanglement with a clear pathway for further improvements, offering promising applications in photonic quantum computing or quantum networks.

Published

2023

8. Hardware requirements for realizing a quantum advantage with deterministic single-photon sources

Author

Sund, Patrik I., Uppu, Ravitej, Paesani, Stefano, and Lodahl, Peter

Subjects

Quantum Physics

Abstract

Boson sampling is a specialised algorithm native to the quantum photonic platform developed for near-term demonstrations of quantum advantage over classical computers. While clear useful applications for such near-term pre-fault-tolerance devices are not currently known, reaching a quantum advantage regime serves as a useful benchmark for the hardware. Here, we analyse and detail hardware requirements needed to reach quantum advantage with deterministic quantum emitters, a promising platform for photonic quantum computing. We elucidate key steps that can be taken in experiments to overcome practical constraints and establish quantitative hardware-level requirements. We find that quantum advantage is within reach using quantum emitters with an efficiency of 60%-70% and interferometers constructed according to a hybrid-mode-encoding architecture, constituted of Mach-Zehnder interferometers with an insertion loss of 0.0035 (a transmittance of 99.92%) per component.

Published

2023

9. A single-photon emitter coupled to a phononic-crystal resonator in the resolved-sideband regime

Author

Spinnler, Clemens, Nguyen, Giang N., Wang, Ying, Zhai, Liang, Javadi, Alisa, Erbe, Marcel, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, Midolo, Leonardo, and Warburton, Richard J.

Published

2024

10. Direct observation of a few-photon phase shift induced by a single quantum emitter in a waveguide

Author

Staunstrup, Mathias J. R., Tiranov, Alexey, Wang, Ying, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Rotenberg, Nir, Lodahl, Peter, and Le Jeannic, Hanna

Published

2024

11. Quantum key distribution using deterministic single-photon sources over a field-installed fibre link

Author

Zahidy, Mujtaba, Mikkelsen, Mikkel T., Müller, Ronny, Da Lio, Beatrice, Krehbiel, Martin, Wang, Ying, Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Galili, Michael, Forchhammer, Søren, Lodahl, Peter, Oxenløwe, Leif K., Bacco, Davide, and Midolo, Leonardo

Published

2024

12. Violation of Bell inequality by photon scattering on a two-level emitter

Author

Liu, Shikai, Sandberg, Oliver August Dall'Alba, Chan, Ming Lai, Schrinski, Björn, Anyfantaki, Yiouli, Nielsen, Rasmus Bruhn, Larsen, Robert Garbecht, Skalkin, Andrei, Wang, Ying, Midolo, Leonardo, Scholz, Sven, Wieck, Andreas Dirk, Ludwig, Arne, Sørensen, Anders Søndberg, Tiranov, Alexey, and Lodahl, Peter

Subjects

Quantum Physics

Abstract

Entanglement, the non-local correlations present in multipartite quantum systems, is a curious feature of quantum mechanics and the fuel of quantum technology. It is therefore a major priority to develop energy-conserving and simple methods for generating high-fidelity entangled states. In the case of light, entanglement can be realized by interactions with matter, although the required nonlinear interaction is typically weak, thereby limiting its applicability. Here, we show how a single two-level emitter deterministically coupled to light in a nanophotonic waveguide is used to realize genuine photonic quantum entanglement for excitation at the single photon level. By virtue of the efficient optical coupling, two-photon interactions are strongly mediated by the emitter realizing a giant nonlinearity that leads to entanglement. We experimentally generate and verify energy-time entanglement by violating a Bell inequality (Clauder-Horne-Shimony-Holt Bell parameter of $S=2.67(16)>2$) in an interferometric measurement of the two-photon scattering response. As an attractive feature of this approach, the two-level emitter acts as a passive scatterer initially prepared in the ground state, i.e., no advanced spin control is required. This experiment is a fundamental advancement that may pave a new route for ultra-low energy-consuming synthesis of photonic entangled states for quantum simulators or metrology., Comment: the manuscript of 6 pages with 3 figures and a Supplementary Material file of 12 pages with 7 figures

Published

2023

13. Direct observation of non-linear optical phase shift induced by a single quantum emitter in a waveguide

Author

Staunstrup, Mathias J. R., Tiranov, Alexey, Wang, Ying, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Rotenberg, Nir, Lodahl, Peter, and Jeannic, Hanna Le

Subjects

Quantum Physics, Physics - Optics

Abstract

Realizing a sensitive photon-number-dependent phase shift on a light beam is required both in classical and quantum photonics. It may lead to new applications for classical and quantum photonics machine learning or pave the way for realizing photon-photon gate operations. Non-linear phase-shifts require efficient light-matter interaction, and recently quantum dots coupled to nanophotonic devices have enabled near-deterministic single-photon coupling. We experimentally realize an optical phase shift of $0.19 \pi \pm 0.03$ radians ($\approx 34$ degrees) using a weak coherent state interacting with a single quantum dot in a planar nanophotonic waveguide. The phase shift is probed by interferometric measurements of the light scattered from the quantum dot in the waveguide. The nonlinear process is sensitive at the single-photon level and can be made compatible with scalable photonic integrated circuitry. The work may open new prospects for realizing high-efficiency optical switching or be applied for proof-of-concept quantum machine learning or quantum simulation demonstrations.

Published

2023

14. Independent electrical control of two quantum dots coupled through a photonic-crystal waveguide

Author

Chu, Xiao-Liu, Papon, Camille, Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Rotenberg, Nir, and Lodahl, Peter

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Efficient light-matter interaction at the single-photon level is of fundamental importance in emerging photonic quantum technology. A fundamental challenge is addressing multiple quantum emitters at once, as intrinsic inhomogeneities of solid-state platforms require individual tuning of each emitter. We present the realization of two semiconductor quantum dot emitters that are efficiently coupled to a photonic-crystal waveguide and individually controllable by applying a local electric Stark field. We present resonant transmission and fluorescence spectra in order to probe the coupling of the two emitters to the waveguide. We exploit the single-photon stream from one quantum dot to perform spectroscopy on the second quantum dot positioned 16$\mu$m away in the waveguide. Furthermore, power-dependent resonant transmission measurements reveals signatures of coherent coupling between the emitters. Our work provides a scalable route to realizing multi-emitter collective coupling, which has inherently been missing for solid-state deterministic photon emitters., Comment: 6 pages, 3 figures

Published

2023

15. Deterministic photon source interfaced with a programmable silicon-nitride integrated circuit

Author

Wang, Ying, Faurby, Carlos F. D., Ruf, Fabian, Sund, Patrik I., Nielsen, Kasper H., Volet, Nicolas, Heck, Martijn J. R., Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Paesani, Stefano, and Lodahl, Peter

Subjects

Quantum Physics, Physics - Optics

Abstract

We develop a quantum photonic platform that interconnects a high-quality quantum dot single-photon source and a low-loss photonic integrated circuit made in silicon nitride. The platform is characterized and programmed to demonstrate various multiphoton applications, including bosonic suppression laws and photonic entanglement generation. The results show a promising technological route forward to scale-up photonic quantum hardware.

Published

2023

16. Quantum Key Distribution using Deterministic Single-Photon Sources over a Field-Installed Fibre Link

Author

Zahidy, Mujtaba, Mikkelsen, Mikkel T., Müller, Ronny, Da Lio, Beatrice, Krehbiel, Martin, Wang, Ying, Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Galili, Michael, Forchhammer, Søren, Lodahl, Peter, Oxenløwe, Leif K., Bacco, Davide, and Midolo, Leonardo

Subjects

Quantum Physics

Abstract

Quantum-dot-based single-photon sources are key assets for quantum information technology, supplying on-demand scalable quantum resources for computing and communication. However, longlasting issues such as limited long-term stability and source brightness have traditionally impeded their adoption in real-world applications. Here, we realize a quantum key distribution field trial using true single photons across an 18-km-long dark fibre, located in the Copenhagen metropolitan area, using an optimized, state-of-the-art, quantum-dot single-photon source frequency-converted to the telecom wavelength. A secret key generation rate of >2 kbits/s realized over a 9.6 dB channel loss is achieved with a polarization-encoded BB84 scheme, showing remarkable stability for more than 24 hours of continuous operation. Our results highlight the maturity of deterministic single-photon source technology while paving the way for advanced single-photon-based communication protocols, including fully device-independent quantum key distribution, towards the goal of a quantum internet., Comment: 9 pages, 4 figures. Minor edits

Published

2023

17. Entanglement properties of a quantum-dot biexciton cascade in a chiral nanophotonic waveguide

Author

González-Ruiz, Eva M., Østfeldt, Freja T., Uppu, Ravitej, Lodahl, Peter, and Sørensen, Anders S.

Subjects

Quantum Physics

Abstract

We analyse the entanglement properties of deterministic path-entangled photonic states generated by coupling the emission of a quantum-dot biexciton cascade to a chiral nanophotonic waveguide, as implemented by {\O}stfeldt et al. [PRX Quantum 3, 020363 (2022)]. We model the degree of entanglement through the concurrence of the two-photon entangled state in the presence of realistic experimental imperfections. The model accounts for imperfect chiral emitter-photon interactions in the waveguide and the asymmetric coupling of the exciton levels introduced by fine-structure splitting along with time-jitter in the detection of photons. The analysis shows that the approach offers a promising platform for deterministically generating entanglement in integrated nanophotonic systems in the presence of realistic experimental imperfections., Comment: 12 pages, 5 figures

Published

2023

18. High-speed thin-film lithium niobate quantum processor driven by a solid-state quantum emitter

Author

Sund, Patrik I., Lomonte, Emma, Paesani, Stefano, Wang, Ying, Carolan, Jacques, Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Pernice, Wolfram H. P., Lodahl, Peter, and Lenzini, Francesco

Subjects

Quantum Physics, Physics - Optics

Abstract

Scalable photonic quantum computing architectures pose stringent requirements on photonic processing devices. The need for low-loss high-speed reconfigurable circuits and near-deterministic resource state generators are some of the most challenging requirements. Here we develop an integrated photonic platform based on thin-film lithium niobate and interface it with deterministic solid-state single-photon sources based on quantum dots in nanophotonic waveguides. The generated photons are processed with low-loss circuits programmable at speeds of several GHz. We realize a variety of key photonic quantum information processing functionalities with the high-speed circuits, including on-chip quantum interference, photon demultiplexing, and reprogrammability of a four-mode universal photonic circuit. These results show a promising path forward for scalable photonic quantum technologies by merging integrated photonics with solid-state deterministic photon sources in a heterogeneous approach to scaling up.

Published

2022

19. Independent operation of two waveguide-integrated quantum emitters

Author

Papon, Camille, Wang, Ying, Uppu, Ravitej, Scholz, Sven, Wieck, Andreas Dirk, Ludwig, Arne, Lodahl, Peter, and Midolo, Leonardo

Subjects

Quantum Physics, Physics - Optics

Abstract

We demonstrate the resonant excitation of two quantum dots in a photonic integrated circuit for on-chip single-photon generation in multiple spatial modes. The two quantum dots are electrically tuned to the same emission wavelength using a pair of isolated $p$-$i$-$n$ junctions and excited by a resonant pump laser via dual-mode waveguides. We demonstrate two-photon quantum interference visibility of $(79\pm2)\%$ under continuous-wave excitation of narrow-linewidth quantum dots. Our work solves an outstanding challenge in quantum photonics by realizing the key enabling functionality of how to scale-up deterministic single-photon sources., Comment: 7 pages 3 figures, Supplementary materials 7 pages 9 figures

Published

2022

20. Collective super- and subradiant dynamics between distant optical quantum emitters

Author

Tiranov, Alexey, Angelopoulou, Vasiliki, van Diepen, Cornelis Jacobus, Schrinski, Björn, Sandberg, Oliver August Dall'Alba, Wang, Ying, Midolo, Leonardo, Scholz, Sven, Wieck, Andreas Dirk, Ludwig, Arne, Sørensen, Anders Søndberg, and Lodahl, Peter

Subjects

Quantum Physics, Physics - Optics

Abstract

Photon emission is the hallmark of light-matter interaction and the foundation of photonic quantum science, enabling advanced sources for quantum communication and computing. Although single-emitter radiation can be tailored by the photonic environment, the introduction of multiple emitters extends this picture. A fundamental challenge, however, is that the radiative dipole-dipole coupling rapidly decays with spatial separation, typically within a fraction of the optical wavelength. We realize distant dipole-dipole radiative coupling with pairs of solid-state optical quantum emitters embedded in a nanophotonic waveguide. We dynamically probe the collective response and identify both super- and subradiant emission as well as means to control the dynamics by proper excitation techniques. Our work constitutes a foundational step toward multiemitter applications for scalable quantum-information processing., Comment: 6 pages 3 figures, Supplementary materials 18 pages 18 figures

Published

2022

21. Sub-radiant states for imperfect quantum emitters coupled by a nanophotonic waveguide

Author

Chu, Xiao-Liu, Angelopoulou, Vasiliki, Lodahl, Peter, and Rotenberg, Nir

Subjects

Quantum Physics, Physics - Optics

Abstract

Coherent interactions between quantum emitters in tailored photonic structures is a fundamental building block for future quantum technologies, but remains challenging to observe in complex solid-state environments, where the role of decoherence must be considered. Here, we investigate the optical interaction between two quantum emitters mediated by one-dimensional waveguides in a realistic solid-state environment, focusing on the creation, population and detection of a sub-radiant state, in the presence of dephasing. We show that as dephasing increases, the signatures of sub-radiance quickly vanish in intensity measurements yet remain pronounced in photon correlation measurements, particularly when the two emitters are pumped separately so as to populate the sub-radiant state efficiently. The applied Green's tensor approach is used to model a photonic crystal waveguide, including the dependence on the spatial position of the integrated emitter. The work lays out a route to the experimental realization of sub-radiant states in nanophotonic waveguides containing solid-state emitters., Comment: 12 pages, 7 figures

Published

2022

22. On-chip spin-photon entanglement based on single-photon scattering

Author

Chan, Ming Lai, Tiranov, Alexey, Appel, Martin Hayhurst, Wang, Ying, Midolo, Leonardo, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Sørensen, Anders Søndberg, and Lodahl, Peter

Subjects

Quantum Physics

Abstract

The realization of on-chip quantum gates between photons and solid-state spins is a key building block for quantum-information processors, enabling, e.g., distributed quantum computing, where remote quantum registers are interconnected by flying photons. Self-assembled quantum dots integrated in nanostructures are one of the most promising systems for such an endeavor thanks to their near-unity photon-emitter coupling and fast spontaneous emission rate. Here we demonstrate an on-chip entangling gate between an incoming photon and a stationary quantum-dot spin qubit. The gate is based on sequential scattering of a time-bin encoded photon with a waveguide-embedded quantum dot and operates on sub-microsecond timescale; two orders of magnitude faster than other platforms. Heralding on detection of a reflected photon renders the gate fidelity fully immune to spectral wandering of the emitter. These results represent a major step in realizing a quantum node capable of both photonic entanglement generation and on-chip quantum logic, as demanded in quantum networks and quantum repeaters., Comment: Published version. Popular summary: https://physicscommunity.nature.com/posts/creating-light-matter-entanglement-on-a-chip

Published

2022

23. Quantum state transfer between a frequency-encoded photonic qubit and a quantum dot spin in a nanophotonic waveguide

Author

Chan, Ming Lai, Aqua, Ziv, Tiranov, Alexey, Dayan, Barak, Lodahl, Peter, and Sørensen, Anders S.

Subjects

Quantum Physics

Abstract

We propose a deterministic yet fully passive scheme to transfer the quantum state from a frequency-encoded photon to the spin of a quantum-dot mediated by a nanophotonic waveguide. We assess the quality of the state transfer by studying the effects of all relevant experimental imperfections on the state-transfer fidelity. We show that a transfer fidelity exceeding 95% is achievable for experimentally realistic parameters. Our work sets the stage for deterministic solid-state quantum networks tailored to frequency-encoded photonic qubits., Comment: 13 pages, 6 figures

Published

2022

24. Deterministic Photon Sorting in Waveguide QED Systems

Author

Yang, Fan, Lund, Mads M., Pohl, Thomas, Lodahl, Peter, and Mølmer, Klaus

Subjects

Quantum Physics, Physics - Optics

Abstract

Sorting quantum fields into different modes according to their Fock-space quantum numbers is a highly desirable quantum operation. In this Letter, we show that a pair of two-level emitters, chirally coupled to a waveguide, may scatter single- and two-photon components of an input pulse into orthogonal temporal modes with a fidelity $\gtrsim 0.9997$. We develop a general theory to characterize and optimize this process and observe an interesting dynamics in the two-photon scattering regime: while the first emitter gives rise to a complex multimode field, the second emitter recombines the field amplitudes and the net two-photon scattering induces a self-time reversal of the pulse mode. The presented scheme can be employed to construct logic elements for propagating photons, such as a deterministic nonlinear-sign gate with a fidelity $\gtrsim 0.9995$, Comment: 6+4 pages, 5+4 figures

Published

2022

25. A Pure and indistinguishable single-photon source at telecommunication wavelength

Author

Da Lio, Beatrice, Faurby, Carlos, Zhou, Xiaoyan, Chan, Ming Lai, Uppu, Ravitej, Thyrrestrup, Henri, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, and Midolo, Leonardo

Subjects

Quantum Physics

Abstract

On-demand single-photon sources emitting pure and indistinguishable photons at the telecommunication wavelength are a critical asset towards the deployment of fiber-based quantum networks. Indeed, single photons may serve as flying qubits, allowing communication of quantum information over long distances. Self-assembled InAs quantum dots embedded in GaAs constitute an excellent nearly deterministic source of high quality single photons, but the vast majority of sources operate in the 900-950 nm wavelength range, precluding their adoption in a quantum network. Here, we present a quantum frequency conversion scheme for converting single photons from quantum dots to the telecommunication C band, around 1550 nm, achieving 40.8% end-to-end efficiency, while maintaining both high purity and a high degree of indistinguishability during conversion with measured values of $g^{(2)}(0)=2.4\%$ and $V^{\text{corr}}=94.8\%$, respectively., Comment: 7 pages, 4 figures

Published

2022

26. Dynamical photon-photon interaction mediated by a quantum emitter

Author

Jeannic, Hanna Le, Tiranov, Alexey, Carolan, Jacques, Ramos, Tomás, Wang, Ying, Appel, Martin H., Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Rotenberg, Nir, Midolo, Leonardo, García-Ripoll, Juan José, Sørensen, Anders S., and Lodahl, Peter

Subjects

Quantum Physics, Physics - Optics

Abstract

Single photons constitute a main platform in quantum science and technology: they carry quantum information over extended distances in the future quantum internet and can be manipulated in advanced photonic circuits enabling scalable photonic quantum computing. The main challenge in quantum photonics is how to generate advanced entangled resource states and efficient light-matter interfaces. Here we utilize the efficient and coherent coupling of a single quantum emitter to a nanophotonic waveguide for realizing quantum nonlinear interaction between single-photon wavepackets. This inherently multimode quantum system constitutes a new research frontier in quantum optics. We demonstrate control of a photon with another photon and experimentally unravel the dynamical response of two-photon interactions mediated by a quantum emitter, and show that the induced quantum correlations are controlled by the pulse duration. The work will open new avenues for tailoring complex photonic quantum resource states.

Published

2021

27. In-plane resonant excitation of quantum dots in a dual-mode photonic-crystal waveguide with high $\beta$-factor

Author

Zhou, Xiaoyan, Lodahl, Peter, and Midolo, Leonardo

Subjects

Quantum Physics, Physics - Optics

Abstract

A high-quality quantum dot (QD) single-photon source is a key resource for quantum information processing. Exciting a QD emitter resonantly can greatly suppress decoherence processes and lead to highly indistinguishable single-photon generation. It has, however, remained a challenge to implement strict resonant excitation in a stable and scalable way, without compromising any of the key specs of the source (efficiency, purity, and indistinguishability). In this work, we propose a novel dual-mode photonic-crystal waveguide that realizes direct in-plane resonant excitation of the embedded QDs. The device relies on a two-mode waveguide design, which allows exploiting one mode for excitation of the QD and the other mode for collecting the emitted single photons with high efficiency. By proper engineering of the photonic bandstructure, we propose a design with single-photon collection efficiency of $\beta > 0.95$ together with a single-photon impurity of $\epsilon< 5 \times 10^{-3}$ over a broad spectral and spatial range. The device has a compact footprint of $\sim 50$ $\mu$m$^2$ and would enable stable and scalable excitation of multiple emitters for multi-photon quantum applications.

Published

2021

28. Entangling a Hole Spin with a Time-Bin Photon: A Waveguide Approach for Quantum Dot Sources of Multi-Photon Entanglement

Author

Appel, Martin Hayhurst, Tiranov, Alexey, Pabst, Simon, Chan, Ming Lai, Starup, Christian, Wang, Ying, Midolo, Leonardo, Tiurev, Konstantin, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Sørensen, Anders Søndberg, and Lodahl, Peter

Subjects

Quantum Physics

Abstract

Deterministic sources of multi-photon entanglement are highly attractive for quantum information processing but are challenging to realize experimentally. In this paper, we demonstrate a route towards a scaleable source of time-bin encoded Greenberger-Horne-Zeilinger and linear cluster states from a solid-state quantum dot embedded in a nanophotonic crystal waveguide. By utilizing a self-stabilizing double-pass interferometer, we measure a spin-photon Bell state with $(67.8\pm0.4)\%$ fidelity and devise steps for significant further improvements. By employing strict resonant excitation, we demonstrate a photon indistinguishability of $(95.7\pm0.8)\%$, which is conducive to fusion of multiple cluster states for scaling up the technology and producing more general graph states., Comment: Manuscript: 7 pages, 3 figures. Supplementary information: 23 pages, 12 figures

Published

2021

29. Chiral quantum optics in broken-symmetry and topological photonic crystal waveguides

Author

Hauff, Nils, Hughes, Stephen, Jeannic, Hanna Le, Lodahl, Peter, and Rotenberg, Nir

Subjects

Physics - Optics, Quantum Physics

Abstract

On-chip chiral quantum light-matter interfaces, which support directional interactions, provide a promising platform for efficient spin-photon coupling, non-reciprocal photonic elements, and quantum logic architectures. We present full-wave three-dimensional calculations to quantify the performance of conventional and topological photonic crystal waveguides as chiral emitter-photon interfaces. Specifically, the ability of these structures to support and enhance directional interactions while suppressing subsequent backscattering losses is quantified. Broken symmetry waveguides, such as the non-topological glide-plane waveguide and topological bearded interface waveguide are found to act as efficient chiral interfaces, with the topological waveguide modes allowing for operation at significantly higher Purcell enhancement factors. Finally, although all structures suffer from backscattering losses due to fabrication imperfections, these are found to be smaller at high enhancement factors for the topological waveguide. These reduced losses occur because the optical mode is pushed away from the air-dielectric interfaces where scattering occurs, and not because of any topological protection. These results are important to the understanding of light-matter interactions in topological photonic crystals and to the design of efficient, on-chip chiral quantum devices., Comment: 16 pages, 12 figures

Published

2021

30. Violation of Bell's inequality with quantum-dot single-photon sources

Author

González-Ruiz, Eva M., Das, Sumanta K., Lodahl, Peter, and Sørensen, Anders S.

Subjects

Quantum Physics

Abstract

We investigate the possibility of realizing a loophole-free violation of Bell's inequality using deterministic single-photon sources. We provide a detailed analysis of a scheme to achieve such violations over long distances with immediate extensions to device-independent quantum key distribution. We investigate the effect of key experimental imperfections that are unavoidable in real-world single-photon sources including the finite degree of photon indistinguishability, single-photon purity, and the overall source efficiency. We benchmark the performance requirements to state-of-the-art deterministic single-photon sources based on quantum dots in photonic nanostructures and find that experimental realizations appear to be within reach. We also evaluate the requirements for a post-selected version of the protocol, which relaxes the demanding requirements with respect to the source efficiency., Comment: 17 pages, 8 figures

Published

2021

31. On-demand source of dual-rail photon pairs based on chiral interaction in a nanophotonic waveguide

Author

Østfeldt, Freja T., González-Ruiz, Eva M., Hauff, Nils, Wang, Ying, Wieck, Andreas D., Ludwig, Arne, Schott, Rüdiger, Midolo, Leonardo, Sørensen, Anders S., Uppu, Ravitej, and Lodahl, Peter

Subjects

Quantum Physics, Physics - Optics

Abstract

Entanglement is the fuel of advanced quantum technology. It is for instance consumed in measurement-based quantum computing and allows loss-tolerant encoding of quantum information. In photonics, entanglement has traditionally been generated probabilistically, requiring massive multiplexing for scaling up to many photons. An alternative approach utilizes quantum emitters in nanophotonic devices for deterministic generation of single photons, which an be extended to two- and multi-photon generation on demand. The proposed polarization-entanglement sources are, however, incompatible with spatial dual-rail qubit encoding, which is preferred in photonic quantum computing realized in scalable integrated photonic circuits. Here we propose and experimentally realize an on-demand source of dual-rail photon pairs using a quantum dot in a planar nanophotonic waveguide. The source exploits the cascaded decay of a biexciton state and chiral light-matter coupling to achieve deterministic generation of spatial dual-rail Bell pairs with the amount of entanglement determined by the chirality. The operational principle can readily be extended to multi-photon entanglement generation, and such sources may be interfaced with advanced photonic-integrated circuits, e.g., for efficient preparation of entanglement resource states for photonic quantum computing., Comment: 15 pages, 3 main figures and 8 supplementary figures

Published

2021

32. An integrated whispering-gallery-mode resonator for solid-state coherent quantum photonics

Author

Brooks, Arianne, Chu, Xiao-Liu, Liu, Zhe, Schott, Rudiger, Ludwig, Arne, Wieck, Andreas D., Midolo, Leonardo, Lodahl, Peter, and Rotenberg, Nir

Subjects

Quantum Physics

Abstract

Tailored photonic cavities allow enhancing light-matter interaction ultimately to create a fully coherent quantum interface. Here, we report on an integrated microdisk cavity containing self-assembled quantum dots to coherently route photons between different access waveguides. We measure a Purcell factor of $F_{exp}=6.9\pm0.9$ for a cavity quality factor of about 10,000, allowing us to observe clear signatures of coherent scattering of photons by the quantum dots. We show how this integrated system can coherently re-route photons between the drop and bus ports, and how this routing is controlled by detuning the quantum dot and resonator, or through the strength of the excitation beam, where a critical photon number less than one photon per lifetime is required. We discuss the strengths and limitations of this approach, focusing on how the coherent scattering and single-photon nonlinearity can be used to increase the efficiency of quantum devices such as routers or Bell-state analyzers.

Published

2021

33. Single-photon quantum hardware: towards scalable photonic quantum technology with a quantum advantage

Author

Uppu, Ravitej, Midolo, Leonardo, Zhou, Xiaoyan, Carolan, Jacques, and Lodahl, Peter

Subjects

Quantum Physics, Physics - Optics

Abstract

The scaling up of quantum hardware is the fundamental challenge ahead in order to realize the disruptive potential of quantum technology in information science. Among the plethora of hardware platforms, photonics stands out by offering a modular approach, where the main challenge is to construct sufficiently high-quality building blocks and develop methods to efficiently interface them. Importantly, the subsequent scaling-up will make full use of the mature integrated photonic technology provided by photonic foundry infrastructure to produce small foot-print quantum processors of immense complexity. A fully coherent and deterministic photon-emitter interface is a key enabler of quantum photonics, and can today be realized with solid-state quantum emitters with specifications reaching the quantitative benchmark referred to as Quantum Advantage. This light-matter interaction primer realizes a range of quantum photonic resources and functionalities, including on-demand single-photon and multi-photon entanglement sources, and photon-photon nonlinear quantum gates. We will present the current state-of-the-art in single-photon quantum hardware and the main photonic building blocks required in order to scale up. Furthermore, we will point out specific promising applications of the hardware building blocks within quantum communication and photonic quantum computing, laying out the road ahead for quantum photonics applications that could offer a genuine quantum advantage., Comment: 15 pages, 6 figures

Published

2021

34. Electroabsorption in gated GaAs nanophotonic waveguides

Author

Wang, Ying, Uppu, Ravitej, Zhou, Xiaoyan, Papon, Camille, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, and Midolo, Leonardo

Subjects

Physics - Optics, Condensed Matter - Materials Science, Quantum Physics

Abstract

We report on the analysis of electroabsorption in thin GaAs/Al$_{0.3}$Ga$_{0.7}$As nanophotonic waveguides with an embedded $p$-$i$-$n$ junction. By measuring the transmission through waveguides of different lengths, we derive the propagation loss as a function of electric field, wavelength, and temperature. The results are in good agreement with the Franz-Keldysh model of electroabsorption extending over 200 meV below the GaAs bandgap, i.e. in the 910--970 nm wavelength range. We find a pronounced residual absorption in forward bias, which we attribute to Fermi-level pinning at the waveguide surface, producing over 20 dB/mm loss at room temperature. These results are essential for understanding the origin of loss in nanophotonic devices operating in the emission range of self-assembled InAs semiconductor quantum dots, towards the realization of scalable quantum photonic integrated circuits., Comment: 6 pages, 3 figures

Published

2021

35. Wafer-Scale Epitaxial Modulation of Quantum Dot Density

Author

Bart, N., Dangel, C., Zajac, P., Spitzer, N., Ritzmann, J., Schmidt, M., Babin, H. G., Schott, R., Valentin, S. R., Scholz, S., Wang, Y., Uppu, R., Najer, D., Löbl, M. C., Tomm, N., Javadi, A., Antoniadis, N. O., Midolo, L., Müller, K., Warburton, R. J., Lodahl, P., Wieck, A. D., Finley, J. J., and Ludwig, A.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics

Abstract

Precise control of the properties of semiconductor quantum dots (QDs) is vital for creating novel devices for quantum photonics and advanced opto-electronics. Suitable low QD-density for single QD devices and experiments are challenging to control during epitaxy and are typically found only in limited regions of the wafer. Here, we demonstrate how conventional molecular beam epitaxy (MBE) can be used to modulate the density of optically active QDs in one- and two- dimensional patterns, while still retaining excellent quality. We find that material thickness gradients during layer-by-layer growth result in surface roughness modulations across the whole wafer. Growth on such templates strongly influences the QD nucleation probability. We obtain density modulations between 1 and 10 QDs/${\mu}m^{2}$ and periods ranging from several millimeters down to at least a few hundred microns. This novel method is universal and expected to be applicable to a wide variety of different semiconductor material systems. We apply the method to enable growth of ultra-low noise QDs across an entire 3-inch semiconductor wafer.

Published

2020

36. Fidelity of time-bin entangled multi-photon states from a quantum emitter

Author

Tiurev, Konstantin, Mirambell, Pol Llopart, Lauritzen, Mikkel Bloch, Appel, Martin Hayhurst, Tiranov, Alexey, Lodahl, Peter, and Sørensen, Anders Søndberg

Subjects

Quantum Physics

Abstract

We devise a mathematical framework for assessing the fidelity of multi-photon entangled states generated by a single solid-state quantum emitter, such as a quantum dot or a nitrogen-vacancy center. Within this formalism, we theoretically study the role of imperfections present in real systems on the generation of time-bin encoded Greenberger-Horne-Zeilinger and one-dimensional cluster states. We consider both fundamental limitations, such as the effect of phonon-induced dephasing, interaction with the nuclear spin bath, and second-order emissions, as well as technological imperfections, such as branching effects, non-perfect filtering, and photon losses. In a companion paper, we consider a particular physical implementation based on a quantum dot emitter embedded in a photonic crystal waveguide and apply our theoretical formalism to assess the fidelities achievable with current technologies.

Published

2020

37. High-fidelity multi-photon-entangled cluster state with solid-state quantum emitters in photonic nanostructures

Author

Tiurev, Konstantin, Appel, Martin Hayhurst, Mirambell, Pol Llopart, Lauritzen, Mikkel Bloch, Tiranov, Alexey, Lodahl, Peter, and Sørensen, Anders Søndberg

Subjects

Quantum Physics

Abstract

We propose a complete architecture for deterministic generation of entangled multiphoton states. Our approach utilizes periodic driving of a quantum-dot emitter and an efficient light-matter interface enabled by a photonic crystal waveguide. We assess the quality of the photonic states produced from a real system by including all intrinsic experimental imperfections. Importantly, the protocol is robust against the nuclear spin bath dynamics due to a naturally built-in refocussing method reminiscent to spin echo. We demonstrate the feasibility of producing Greenberger-Horne-Zeilinger and one-dimensional cluster states with fidelities and generation rates exceeding those achieved with conventional 'fusion' methods in current state-of-the-art experiments. The proposed hardware constitutes a scalable and resource-efficient approach towards implementation of measurement-based quantum communication and computing.

Published

2020

38. A coherent spin-photon interface with waveguide induced cycling transitions

Author

Appel, Martin Hayhurst, Tiranov, Alexey, Javadi, Alisa, Löbl, Matthias Christian, Wang, Ying, Scholz, Sven, Wieck, Andreas Dirk, Ludwig, Arne, Warburton, Richard John, and Lodahl, Peter

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Solid-state quantum dots are promising candidates for efficient light-matter interfaces connecting internal spin degrees of freedom to the states of emitted photons. However, selection rules prevent the combination of efficient spin control and optical cyclicity in this platform. By utilizing a photonic crystal waveguide we here experimentally demonstrate optical cyclicity up to $\approx15$ through photonic state engineering while achieving high fidelity spin initialization and coherent optical spin control. These capabilities pave the way towards scalable multi-photon entanglement generation and on-chip spin-photon gates., Comment: 5 pages, 4 figures

Published

2020

39. Experimental reconstruction of the few-photon nonlinear scattering matrix from a single quantum dot in a nanophotonic waveguide

Author

Jeannic, Hanna Le, Ramos, Tomás, Simonsen, Signe F., Pregnolato, Tommaso, Liu, Zhe, Schott, Rüdiger, Wieck, Andreas D., Ludwig, Arne, Rotenberg, Nir, García-Ripoll, Juan José, and Lodahl, Peter

Subjects

Quantum Physics

Abstract

Coherent photon-emitter interfaces offer a way to mediate efficient nonlinear photon-photon interactions, much needed for quantum information processing. Here we experimentally study the case of a two-level emitter, a quantum dot, coupled to a single optical mode in a nanophotonic waveguide. We carry out few-photon transport experiments and record the statistics of the light to reconstruct the scattering matrix elements of 1- and 2-photon components. This provides direct insight to the complex nonlinear photon interaction that contains rich many-body physics., Comment: 14 pages, 7 figures

Published

2020

40. Near Transform-limited Quantum Dot Linewidths in a Broadband Photonic Crystal Waveguide

Author

Pedersen, Freja T., Wang, Ying, Olesen, Cecilie T., Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Löbl, Matthias C., Warburton, Richard J., Midolo, Leonardo, Uppu, Ravitej, and Lodahl, Peter

Subjects

Quantum Physics, Physics - Optics

Abstract

Planar nanophotonic structures enable broadband, near-unity coupling of emission from quantum dots embedded within, thereby realizing ideal singe-photon sources. The efficiency and coherence of the single-photon source is limited by charge noise, which results in the broadening of the emission spectrum.We report suppression of the noise by fabricating photonic crystal waveguides in a gallium arsenide membrane containing quantum dots embedded in a $p$-$i$-$n$ diode. Local electrical contacts in the vicinity of the waveguides minimize the leakage current and allow fast electrical control ($\approx$4 MHz bandwidth) of the quantum dot resonances. Resonant linewidth measurements of $79$ quantum dots coupled to the photonic crystal waveguides exhibit near transform-limited emission over a 6 nm wide range of emission wavelengths. Importantly, the local electrical contacts allow independent tuning of multiple quantum dots on the same chip, which together with the transform-limited emission are key components in realizing multiemitter-based quantum information processing., Comment: 6 pages with 4 figures

Published

2020

41. Scalable integrated single-photon source

Author

Uppu, Ravitej, Pedersen, Freja T., Wang, Ying, Olesen, Cecilie T., Papon, Camille, Zhou, Xiaoyan, Midolo, Leonardo, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, and Lodahl, Peter

Subjects

Quantum Physics, Physics - Optics

Abstract

Photonic qubits are key enablers for quantum-information processing deployable across a distributed quantum network. An on-demand and truly scalable source of indistinguishable single photons is the essential component enabling high-fidelity photonic quantum operations. A main challenge is to overcome noise and decoherence processes in order to reach the steep benchmarks on generation efficiency and photon indistinguishability required for scaling up the source. We report on the realization of a deterministic single-photon source featuring near-unity indistinguishability using a quantum dot in an 'on-chip' planar nanophotonic waveguide circuit. The device produces long strings of $>100$ single photons without any observable decrease in the mutual indistinguishability between photons. A total generation rate of $122$ million photons per second is achieved corresponding to an 'on-chip' source efficiency of $84 \%$. These specifications of the single-photon source are benchmarked for boson sampling and found to enable scaling into the regime of quantum advantage., Comment: 17 pages, 12 figures

Published

2020

42. On-chip deterministic operation of quantum dots in dual-mode waveguides for a plug-and-play single-photon source

Author

Uppu, Ravitej, Eriksen, Hans T., Thyrrestrup, Henri, Uğurlu, Aslı D., Wang, Ying, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Löbl, Matthias C., Warburton, Richard J., Lodahl, Peter, and Midolo, Leonardo

Subjects

Quantum Physics, Physics - Optics

Abstract

A deterministic source of coherent single photons is an enabling device of quantum-information processing for quantum simulators, and ultimately a full-fledged quantum internet. Quantum dots (QDs) in nanophotonic structures have been employed as excellent sources of single photons, and planar waveguides are well suited for scaling up to multiple photons and emitters exploring near-unity photon-emitter coupling and advanced active on-chip functionalities. An ideal single-photon source requires suppressing noise and decoherence, which notably has been demonstrated in electrically-contacted heterostructures. It remains a challenge to implement deterministic resonant excitation of the QD required for generating coherent single photons, since residual light from the excitation laser should be suppressed without compromising source efficiency and scalability. Here, we present the design and realization of a novel planar nanophotonic device that enables deterministic pulsed resonant excitation of QDs through the waveguide. Through nanostructure engineering, the excitation light and collected photons are guided in two orthogonal waveguide modes enabling deterministic operation. We demonstrate a coherent single-photon source that simultaneously achieves high-purity ($g^{(2)}(0)$ = 0.020 $\pm$ 0.005), high-indistinguishability ($V$ = 96 $\pm$ 2 %), and $>$80 % coupling efficiency into the waveguide. The novel `plug-and-play' coherent single-photon source could be operated unmanned for several days and will find immediate applications, e.g., for constructing heralded multi-photon entanglement sources for photonic quantum computing or sensing., Comment: 12 pages, 10 figures

Published

2020

43. A wave-function ansatz method for calculating field correlations and its application to the study of spectral filtering and quantum dynamics of multi-emitter systems

Author

Das, Sumanta, Zhai, Liang, Čepulskovskis, Mantas, Javadi, Alisa, Mahmoodian, Sahand, Lodahl, Peter, and Sørensen, Anders S.

Subjects

Quantum Physics, Physics - Optics

Abstract

We develop a formalism based on a time-dependent wave-function ansatz to study correlations of photons emitted from a collection of two-level quantum emitters. We show how to simulate the system dynamics and evaluate the intensity of the scattered photons and the second-order correlation function $g^{(2)}$ in terms of the amplitudes of the different components of the wave function. Our approach is efficient for considering systems that contain up to two excitations. To demonstrate this we first consider the example of spectral filtering of photons emitted from a single quantum emitter. We show how our formalism can be used to study spectral filtering of the two-photon component of the emitted light from a single quantum emitter for various kinds of filters. Furthermore, as a general application of our formalism, we show how it can be used to study photon-photon correlations in an optically dense ensemble of two-level quantum emitters. In particular we lay out the details of simulating correlated photon transport in such ensembles reported recently by S. Mahmoodian {\it et.al.} [Phys. Rev. Lett. {\bf 121}, 143601 (2018)]. Compared to other existing techniques, the advantage of our formalism is that it is applicable to any generic spectral filter and quantum many-body systems involving a large number of quantum emitters while requiring only a modest computational resource., Comment: 20 pages, 8 figures

Published

2019

44. Radiative Auger Process in the Single-Photon Limit

Author

Löbl, Matthias C., Spinnler, Clemens, Javadi, Alisa, Zhai, Liang, Nguyen, Giang N., Ritzmann, Julian, Midolo, Leonardo, Lodahl, Peter, Wieck, Andreas D., Ludwig, Arne, and Warburton, Richard J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

In a multi-electron atom, an excited electron can decay by emitting a photon. Typically, the leftover electrons are in their ground state. In a radiative Auger process, the leftover electrons are in an excited state and a redshifted photon is created. In a semiconductor quantum dot, radiative Auger is predicted for charged excitons. Here we report the observation of radiative Auger on trions in single quantum dots. For a trion, a photon is created on electron-hole recombination, leaving behind a single electron. The radiative Auger process promotes this additional (Auger) electron to a higher shell of the quantum dot. We show that the radiative Auger effect is a powerful probe of this single electron: the energy separations between the resonance fluorescence and the radiative Auger emission directly measure the single-particle splittings of the electronic states in the quantum dot with high precision. In semiconductors, these single-particle splittings are otherwise hard to access by optical means as particles are excited typically in pairs, as excitons. After the radiative Auger emission, the Auger carrier relaxes back to the lowest shell. Going beyond the original theoretical proposals, we show how applying quantum optics techniques to the radiative Auger photons gives access to the single-electron dynamics, notably relaxation and tunneling. This is also hard to access by optical means: even for quasi-resonant $p$-shell excitation, electron relaxation takes place in the presence of a hole, complicating the relaxation dynamics. The radiative Auger effect can be exploited in other semiconductor nanostructures and quantum emitters in the solid state to determine the energy levels and the dynamics of a single carrier.

Published

2019

45. On-chip nanomechanical filtering of quantum-dot single-photon sources

Author

Zhou, Xiaoyan, Uppu, Ravitej, Liu, Zhe, Papon, Camille, Schott, Rudiger, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, and Midolo, Leonardo

Subjects

Physics - Applied Physics, Physics - Optics, Quantum Physics

Abstract

Semiconductor quantum dots in photonic integrated circuits enable scaling quantum-information processing to many single photons and quantum-optical gates. On-chip spectral filters are essential to achieve high-purity and coherent photon emission from quantum dots embedded in waveguides, without resorting to free-space optics. Such spectral filters should be tunable, to compensate for the inhomogeneous spectral distribution of the quantum dots transitions. Here, we report an on-chip filter monolithically integrated with quantum dots, that uses nanomechanical motion for tuning its resonant wavelength over 10 nm, enabling operation at cryogenic temperatures and avoiding cross-talk with the emitter. We demonstrate single-photon emission from a quantum dot under non-resonant excitation by employing only the on-chip filter. These results are key for the development of fully-integrated de-multiplexing, multi-path photon encoding schemes, and multi-emitter circuits.

Published

2019

46. Lifetimes and quantum efficiencies of quantum dots deterministically positioned in photonic-crystal waveguides

Author

Chu, Xiao-Liu, Pregnolato, Tommaso, Schott, Rüdiger, Wieck, Andreas D., Ludwig, Arne, Rotenberg, Nir, and Lodahl, Peter

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Interfacing single emitters and photonic nanostructures enables modifying their emission properties, such as enhancing individual decay rates or controlling the emission direction. To achieve full control, the single emitter must be positioned in the nanostructures deterministically. Here, we use spectroscopy to gain spectral and spatial information about individual quantum dots in order to position each emitter in a pre-determined location in a unit cell of a photonic-crystal waveguide. Depending on the spatial and spectral positioning within the structured nanophotonic mode, we observe that the quantum dot emission can either be suppressed or enhanced. These results demonstrate the capacity of photonic-crystal waveguides to control the emission of single photons and that the ability to position quantum dots will be crucial to the creation of complex multi-emitter quantum photonic circuits., Comment: 7 pages, 7 figures

Published

2019

47. One-way quantum repeater based on near-deterministic photon-emitter interfaces

Author

Borregaard, Johannes, Pichler, Hannes, Schöder, Tim, Lukin, Mikhail D., Lodahl, Peter, and Sørensen, Anders S.

Subjects

Quantum Physics

Abstract

We propose a novel one-way quantum repeater architecture based on photonic tree-cluster states. Encoding a qubit in a photonic tree-cluster protects the information from transmission loss and enables long-range quantum communication through a chain of repeater stations. As opposed to conventional approaches that are limited by the two-way communication time, the overall transmission rate of the current quantum repeater protocol is determined by the local processing time enabling very high communication rates. We further show that such a repeater can be constructed with as little as two stationary qubits and one quantum emitter per repeater station, which significantly increases the experimental feasibility. We discuss potential implementations with diamond defect centers and semiconductor quantum dots efficiently coupled to photonic nanostructures and outline how such systems may be integrated into repeater stations., Comment: Merged article and supplemental material, corrected typos in Eq. (8)-(10) in supplemental material

Published

2019

48. Deterministic positioning of nanophotonic waveguides around single self-assembled quantum dots

Author

Pregnolato, Tommaso, Chu, Xiao-Liu, Schröder, Tim, Schott, Rüdiger, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, and Rotenberg, Nir

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

The capability to embed self-assembled quantum dots (QDs) at predefined positions in nanophotonic structures is key to the development of complex quantum photonic architectures. Here, we demonstrate that QDs can be deterministically positioned in nanophotonic waveguides by pre-locating QDs relative to a global reference frame using micro-photoluminescence ($\mu$PL) spectroscopy. After nanofabrication, $\mu$PL images reveal misalignments between the central axis of the waveguide and the embedded QD of only $(9\pm46$) nm and $(1\pm33$) nm, for QDs embedded in undoped and doped membranes, respectively. A priori knowledge of the QD positions allows us to study the spectral changes introduced by nanofabrication. We record average spectral shifts ranging from 0.1 to 1.1 nm, indicating that the fabrication-induced shifts can generally be compensated by electrical or thermal tuning of the QDs. Finally, we quantify the effects of the nanofabrication on the polarizability, the permanent dipole moment and the emission frequency at vanishing electric field of different QD charge states, finding that these changes are constant down to QD-surface separations of only 70 nm. Consequently, our approach deterministically integrates QDs into nanophotonic waveguides whose light-fields contain nanoscale structure and whose group index varies at the nanometer level., Comment: 26 pages, 9 figures. Updated version of the manuscript, with new appendices and new figures

Published

2019

49. Suspended Spot-Size Converters for Scalable Single-Photon Devices

Author

Uğurlu, Aslı D., Thyrrestrup, Henri, Uppu, Ravitej, Ouellet-Plamondon, Claudéric, Schott, Rüdiger, Wieck, Andreas D., Ludwig, Arne, Lodahl, Peter, and Midolo, Leonardo

Subjects

Physics - Applied Physics, Physics - Optics, Quantum Physics

Abstract

We report on the realization of a highly efficient optical spot-size converter for the end-face coupling of single photons from GaAs-based nanophotonic waveguides with embedded quantum dots. The converter is realized using an inverted taper and an epoxy polymer overlay providing a 1.3~$\mu$m output mode field diameter. We demonstrate the collection of single photons from a quantum dot into a lensed fiber with a rate of 5.84$\pm0.01$~MHz and estimate a chip-to-fiber coupling efficiency of $\sim48$~\%. The stability and compatibility with cryogenic temperatures make the epoxy waveguides a promising material to realize efficient and scalable interconnects between heterogeneous quantum photonic integrated circuits., Comment: 16 pages, 5 figures, 1 table

Published

2019

50. Coherent nonlinear optics of quantum emitters in nanophotonic waveguides

Author

Türschmann, Pierre, Jeannic, Hanna Le, Simonsen, Signe F., Haakh, Harald R., Götzinger, Stephan, Sandoghdar, Vahid, Lodahl, Peter, and Rotenberg, Nir

Subjects

Quantum Physics

Abstract

Coherent quantum optics, where the interaction of a photon with an emitter does not scramble phase coherence, lies at the heart of many quantum optical effects and emerging technologies. Solid-state emitters coupled to nanophotonic waveguides are a promising platform for quantum devices, as this combination is scalable. Yet, reaching full coherence in these systems is challenging due to the dynamics of the solid-state environment of the emitters. Here, we review progress towards coherent light-matter interactions with solid-state quantum emitters coupled to nanophotonic waveguides. We first lay down the theoretical foundation for coherent and nonlinear light-matter interactions of a two-level system in a quasi-one-dimensional system, and then benchmark experimental realizations. We then discuss higher-order nonlinearities that arise due to the addition of photons of different frequencies, more complex energy-level schemes of the emitters, and the coupling of multiple emitters via a shared photonic mode. Throughout, we highlight protocols for applications and novel effects that are based on these coherent interactions, the steps taken towards their realization, and the challenges that remain to be overcome., Comment: 14 pages, 7 figures, 1 table

Published

2019