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1. A Perspective on Quantum Sensors from Basic Research to Commercial Applications

Author

Oh, Eun, Gregoire, Maxwell D., Black, Adam T., Hughes, K. Jeramy, Kunz, Paul D., Larsen, Michael, Lautier-Gaud, Jean, Lee, Jongmin, Schwindt, Peter D. D., Mouradian, Sara L., Narducci, Frank A., and Sackett, Charles A.

Subjects
Quantum Physics
Abstract

Quantum sensors represent a new generation of sensors with improved precision, accuracy, stability, and robustness to environmental effects compared to their classical predecessors. After decades of laboratory development, several types of quantum sensors are now commercially available or are part-way through the commercialization process. This article provides a brief description of the operation of a selection of quantum sensors that employ the principles of atom-light interactions and discusses progress toward packaging those sensors into products. This article covers quantum inertial and gravitational sensors, including gyroscopes, accelerometers, gravimeters, and gravity gradiometers that employ atom interferometry, nuclear magnetic resonance gyroscopes, atomic and spin-defect magnetometers, and Rydberg electric field sensors., Comment: 96 pages

Published
2024

2. Accuracy guarantees and quantum advantage in analogue open quantum simulation with and without noise

Author

Kashyap, Vikram, Styliaris, Georgios, Mouradian, Sara, Cirac, Juan Ignacio, and Trivedi, Rahul

Subjects
Quantum Physics
Abstract

Many-body open quantum systems, described by Lindbladian master equations, are a rich class of physical models that display complex equilibrium and out-of-equilibrium phenomena which remain to be understood. In this paper, we theoretically analyze noisy analogue quantum simulation of geometrically local open quantum systems and provide evidence that this problem is both hard to simulate on classical computers and could be approximately solved on near-term quantum devices. First, given a noiseless quantum simulator, we show that the dynamics of local observables and the fixed-point expectation values of rapidly-mixing local observables in geometrically local Lindbladians can be obtained to a precision of $\varepsilon$ in time that is $\text{poly}(\varepsilon^{-1})$ and uniform in system size. Furthermore, we establish that the quantum simulator would provide an exponential advantage, in run-time scaling with respect to the target precision and either the evolution time (when simulating dynamics) or the Lindbladian's decay rate (when simulating fixed-points) over any classical algorithm for these problems unless BQP = BPP. We then consider the presence of noise in the quantum simulator in the form of additional geometrically-local Linbdladian terms. We show that the simulation tasks considered in this paper are stable to errors, i.e. they can be solved to a noise-limited, but system-size independent, precision. Finally, we establish that there are stable geometrically local Lindbladian simulation problems such that as the noise rate on the simulator is reduced, classical algorithms must take time exponentially longer in the inverse noise rate to attain the same precision unless BQP = BPP.

Published
2024

3. Technologies for Modulation of Visible Light and their Applications

Author

Park, Sanghyo, Notaros, Milica, Mohanty, Aseema, Kim, Donggyu, Notaros, Jelena, and Mouradian, Sara

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Control over the amplitude, phase, and spatial distribution of visible-spectrum light underlies many technologies, but commercial solutions remain bulky, require high control power, and are often too slow. Active integrated photonics for visible light promises a solution, especially with recent materials and fabrication advances. In this review, we discuss three growing application spaces which rely on control of visible light: control and measurement of atomic quantum technologies, augmented-reality displays, and measurement and control of biological systems. We then review the commercial dynamic surfaces and bulk systems which currently provide visible-light modulation and the current state-of-the-art integrated solutions. Throughout the review we focus on speed, control power, size, optical bandwidth, and technological maturity when comparing technologies.

Published
2024

4. Systematic study of rotational decoherence with a trapped-ion planar rotor

Author

Glikin, Neil, Stickler, Benjamin A., Tollefsen, Ryan, Mouradian, Sara, Yadav, Neha, Urban, Erik, Hornberger, Klaus, and Haeffner, Hartmut

Subjects
Quantum Physics, Physics - Atomic Physics
Abstract

Quantum rotors promise unique advantages for quantum sensing, quantum simulation, and quantum information processing. At present, a variety of systems ranging from nanoparticles to single molecules and trapped ions have demonstrated detection and control of rotational motion in and near the quantum regime. For future applications of quantum rotors, understanding their dynamics in the presence of ambient environments and decoherence will be critical. While other model quantum systems such as the harmonic oscillator have seen extensive experimental study of their decoherence dynamics, such experiments remain an open task for the rigid rotor. We present measurements of fundamental scaling relationships for decoherence of a quantum planar rotor realized with two trapped ions, and find excellent agreement with recent theoretical work., Comment: 9 pages + supplementary information, 3 + 4 figures

Published
2023

5. Quantum Sensing of Intermittent Stochastic Signals

Author

Mouradian, Sara, Glikin, Neil, Megidish, Eli, Ellers, Kai-Isaak, and Haeffner, Hartmut

Subjects
Quantum Physics, Physics - Applied Physics, Physics - Atomic Physics
Abstract

Realistic quantum sensors face a trade-off between the number of sensors measured in parallel and the control and readout fidelity ($F$) across the ensemble. We investigate how the number of sensors and fidelity affect sensitivity to continuous and intermittent signals. For continuous signals, we find that increasing the number of sensors by $1/F^2$ for $F<1$ always recovers the sensitivity achieved when $F=1$. However, when the signal is intermittent, more sensors are needed to recover the sensitivity achievable with one perfect quantum sensor. We also demonstrate the importance of near-unity control fidelity and readout at the quantum projection noise limit by estimating the frequency components of a stochastic, intermittent signal with a single trapped ion sensor. Quantum sensing has historically focused on large ensembles of sensors operated far from the standard quantum limit. The results presented in this manuscript show that this is insufficient for quantum sensing of intermittent signals and re-emphasizes the importance of the unique scaling of quantum projection noise near an eigenstate., Comment: 5 pages, 4 figures

Published
2020
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6. Quantum sensing of intermittent stochastic signals

Author

Mouradian, Sara L, Glikin, Neil, Megidish, Eli, Ellers, Kai-Isaak, and Haeffner, Hartmut

Subjects
Quantum Physics, Physical Sciences, Chemical sciences, Mathematical sciences, Physical sciences
Abstract

Realistic quantum sensors face a trade-off between the number of sensors measured in parallel and the control and readout fidelity (F) across the ensemble. We investigate how the number of sensors and fidelity affect sensitivity to continuous and intermittent signals. For continuous signals, we find that increasing the number of sensors by 1/F2 for F

Published
2021

7. Large-scale integration of near-indistinguishable artificial atoms in hybrid photonic circuits

Author

Wan, Noel H., Lu, Tsung-Ju, Chen, Kevin C., Walsh, Michael P., Trusheim, Matthew E., De Santis, Lorenzo, Bersin, Eric A., Harris, Isaac B., Mouradian, Sara L., Christen, Ian R., Bielejec, Edward S., and Englund, Dirk

Subjects
Quantum Physics
Abstract

A central challenge in developing quantum computers and long-range quantum networks lies in the distribution of entanglement across many individually controllable qubits. Colour centres in diamond have emerged as leading solid-state 'artificial atom' qubits, enabling on-demand remote entanglement, coherent control of over 10 ancillae qubits with minute-long coherence times, and memory-enhanced quantum communication. A critical next step is to integrate large numbers of artificial atoms with photonic architectures to enable large-scale quantum information processing systems. To date, these efforts have been stymied by qubit inhomogeneities, low device yield, and complex device requirements. Here, we introduce a process for the high-yield heterogeneous integration of 'quantum micro-chiplets' (QMCs) -- diamond waveguide arrays containing highly coherent colour centres -- with an aluminium nitride (AlN) photonic integrated circuit (PIC). Our process enables the development of a 72-channel defect-free array of germanium-vacancy (GeV) and silicon-vacancy (SiV) colour centres in a PIC. Photoluminescence spectroscopy reveals long-term stable and narrow average optical linewidths of 54 MHz (146 MHz) for GeV (SiV) emitters, close to the lifetime-limited linewidth of 32 MHz (93 MHz). Additionally, inhomogeneities in the individual qubits can be compensated in situ with integrated tuning of the optical frequencies over 100 GHz. The ability to assemble large numbers of nearly indistinguishable artificial atoms into phase-stable PICs provides an architecture toward multiplexed quantum repeaters and general-purpose quantum computers., Comment: 5 figures

Published
2019
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8. Coherent Control of the Rotational Degree of Freedom of a Two-Ion Coulomb Crystal

Author

Urban, Erik, Glikin, Neil, Mouradian, Sara, Krimmel, Kai, Hemmerling, Boerge, and Haeffner, Hartmut

Subjects
Quantum Physics, Physics - Atomic Physics
Abstract

We demonstrate the preparation and coherent control of the angular momentum state of a two-ion crystal. The ions are prepared with an average angular momentum of $7780\hbar$ freely rotating at 100~kHz in a circularly symmetric potential, allowing us to address rotational sidebands. By coherently exciting these motional sidebands, we create superpositions of states separated by up to four angular momentum quanta. Ramsey experiments show the expected dephasing of the superposition which is dependent on the number of quanta separating the states. These results demonstrate coherent control of a collective motional state described as a quantum rotor in trapped ions. Moreover, our work offers an expansion of the utility of trapped ions for quantum simulation, interferometry, and sensing.

Published
2019
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9. Optical coherence of diamond nitrogen-vacancy centers formed by ion implantation and annealing

Author

van Dam, Suzanne B., Walsh, Michael, Degen, Maarten J., Bersin, Eric, Mouradian, Sara L., Galiullin, Airat, Ruf, Maximilian, IJspeert, Mark, Taminiau, Tim H., Hanson, Ronald, and Englund, Dirk R.

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

The advancement of quantum optical science and technology with solid-state emitters such as nitrogen-vacancy (NV) centers in diamond critically relies on the coherence of the emitters' optical transitions. A widely employed strategy to create NV centers at precisely controlled locations is nitrogen ion implantation followed by a high-temperature annealing process. We report on experimental data directly correlating the NV center optical coherence to the origin of the nitrogen atom. These studies reveal low-strain, narrow-optical-linewidth ($<500$ MHz) NV centers formed from naturally-occurring $^{14}$N atoms. In contrast, NV centers formed from implanted $^{15}$N atoms exhibit significantly broadened optical transitions ($>1$ GHz) and higher strain. The data show that the poor optical coherence of the NV centers formed from implanted nitrogen is not due to an intrinsic effect related to the diamond or isotope. These results have immediate implications for the positioning accuracy of current NV center creation protocols and point to the need to further investigate the influence of lattice damage on the coherence of NV centers from implanted ions.

Published
2018
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10. Individual Control and Readout of Qubits in a Sub-Diffraction Volume

Author

Bersin, Eric, Walsh, Michael, Mouradian, Sara L., Trusheim, Matthew E., Schröder, Tim, and Englund, Dirk

Subjects
Quantum Physics, Physics - Applied Physics, Physics - Optics
Abstract

Medium-scale ensembles of coupled qubits offer a platform for near-term quantum technologies including computing, sensing, and the study of mesoscopic quantum systems. Atom-like emitters in solids have emerged as promising quantum memories, with demonstrations of spin-spin entanglement by optical and magnetic interactions. Magnetic coupling in particular is attractive for efficient and deterministic entanglement gates, but raises the problem of individual spin addressing at the necessary nanometer-scale separation. Current super-resolution techniques can reach this resolution, but are destructive to the states of nearby qubits. Here, we demonstrate the measurement of individual qubit states in a sub-diffraction cluster by selectively exciting spectrally distinguishable nitrogen vacancy (NV) centers. We demonstrate super-resolution localization of single centers with nanometer spatial resolution, as well as individual control and readout of spin populations. These measurements indicate a readout-induced crosstalk on non-addressed qubits below $4\times10^{-2}$. This approach opens the door to high-speed control and measurement of qubit registers in mesoscopic spin clusters, with applications ranging from entanglement-enhanced sensors to error-corrected qubit registers to multiplexed quantum repeater nodes., Comment: 7 pages, 4 figures + supplementary information

Published
2018
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11. Two-Dimensional Photonic Crystal Slab Nanocavities on Bulk Single-Crystal Diamond

Author

Wan, Noel H., Mouradian, Sara, and Englund, Dirk

Subjects
Quantum Physics, Physics - Applied Physics
Abstract

Color centers in diamond are promising spin qubits for quantum computing and quantum networking. In photon-mediated entanglement distribution schemes, the efficiency of the optical interface ultimately determines the scalability of such systems. Nano-scale optical cavities coupled to emitters constitute a robust spin-photon interface that can increase spontaneous emission rates and photon extraction efficiencies. In this work, we introduce the fabrication of 2D photonic crystal slab nanocavities with high quality factors and cubic wavelength mode volumes -- directly in bulk diamond. This planar platform offers scalability and considerably expands the toolkit for classical and quantum nanophotonics in diamond.

Published
2018
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12. Efficient Extraction of Light from a Nitrogen-Vacancy Center in a Diamond Parabolic Reflector

Author

Wan, Noel H., Shields, Brendan J., Kim, Donggyu, Mouradian, Sara, Lienhard, Benjamin, Walsh, Michael, Bakhru, Hassaram, Schröder, Tim, and Englund, Dirk

Subjects
Quantum Physics
Abstract

Quantum emitters in solids are being developed for a range of quantum technologies, including quantum networks, computing, and sensing. However, a remaining challenge is the poor photon collection due to the high refractive index of most host materials. Here we overcome this limitation by introducing monolithic parabolic reflectors as an efficient geometry for broadband photon extraction from quantum emitter and experimentally demonstrate this device for the nitrogen-vacancy (NV) center in diamond. Simulations indicate a photon collection efficiency exceeding 75% across the visible spectrum and experimental devices, fabricated using a high-throughput gray-scale lithography process, demonstrate a photon extraction efficiency of $(48\pm 5)$%. This device enables a raw experimental efficiency of $(12\pm 2)$\% with fluorescence detection rates as high as $(4.6 - 5.7)\times 10^6$ counts per second from a single NV center.

Published
2017
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13. Rectangular Photonic Crystal Nanobeam Cavities in Bulk Diamond

Author

Mouradian, Sara, Wan, Noel H., Schröder, Tim, and Englund, Dirk

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science, Physics - Atomic Physics, Physics - Optics, Quantum Physics
Abstract

We demonstrate the fabrication of photonic crystal nanobeam cavities with rectangular cross section into bulk diamond. In simulation, these cavities have an unloaded quality factor (Q) of over 1 million. Measured cavity resonances show fundamental modes with spectrometer-limited quality factors larger than 14,000 within 1nm of the NV center's zero phonon line at 637nm. We find high cavity yield across the full diamond chip with deterministic resonance trends across the fabricated parameter sweeps.

Published
2017
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14. A Tunable Waveguide-Coupled Cavity Design for Efficient Spin-Photon Interfaces in Photonic Integrated Circuits

Author

Mouradian, Sara and Englund, Dirk

Subjects
Physics - Optics, Quantum Physics
Abstract

A solid state emitter coupled to a photonic crystal cavity exhibits increased photon emission into a single frequency mode. However, current designs for photonic crystal cavities coupled to quantum emitters have three main problems: emitters are placed near surfaces that can degrade their optical properties, the cavity fluorescence cannot be collected into a single useful mode for further routing, and post-fabrication tuning is not currently possible in a stable and reversible manner for each node individually. In this paper, we introduce a hybrid cavity design with minimal fabrication of the host material that keeps the emitter $\geq100\,$nm from all surfaces. This cavity has an unloaded quality factor ($Q$) larger than $1\times10^6$ and a loaded $Q$ of $5.5\times10^4$ with more than 75% of the emission coupled directly into an underlying photonic integrated circuit built from a convenient material that provides low loss waveguides. Finally this design can be actively and reversibly tuned onto resonance with the emitter, allowing tuning over more than 10 times the cavity linewidth while maintaining $\geq50$% of the $Q$ factor with no effects to other cavities on the same chip., Comment: 5 pages, 3 figures

Published
2016

15. Bright and photostable single-photon emitter in silicon carbide

Author

Lienhard, Benjamin, Schröder, Tim, Mouradian, Sara, Dolde, Florian, Tran, Toan Trong, Aharonovich, Igor, and Englund, Dirk R.

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics
Abstract

Single-photon sources are of paramount importance in quantum communication, quantum computation, and quantum metrology. In particular, there is great interest in realizing scalable solid-state platforms that can emit triggered photons on demand to achieve scalable nanophotonic networks. We report on a visible-spectrum single-photon emitter in 4H silicon carbide (SiC). The emitter is photostable at room and low temperatures, enabling photon counts per second in excess of 2$\times$10$^6$ from unpatterned bulk SiC. It exists in two orthogonally polarized states, which have parallel absorption and emission dipole orientations. Low-temperature measurements reveal a narrow zero phonon line (linewidth $<0.1~$nm) that accounts for $>30$% of the total photoluminescence spectrum.

Published
2016
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16. Review Article: Quantum Nanophotonics in Diamond

Author

Schröder, Tim, Mouradian, Sara, Zheng, Jiabao, Trusheim, Matthew E., Walsh, Michael, Chen, Edward H., Li, Luozhou, Bayn, Igal, and Englund, Dirk

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics, Physics - Optics
Abstract

The past decade has seen great advances in developing color centers in diamond for sensing, quantum information processing, and tests of quantum foundations. Increasingly, the success of these applications as well as fundamental investigations of light-matter interaction depend on improved control of optical interactions with color centers -- from better fluorescence collection to efficient and precise coupling with confined single optical modes. Wide ranging research efforts have been undertaken to address these demands through advanced nanofabrication of diamond. This review will cover recent advances in diamond nano- and microphotonic structures for efficient light collection, color center to nanocavity coupling, hybrid integration of diamond devices with other material systems, and the wide range of fabrication methods that have enabled these complex photonic diamond systems.

Published
2016

17. Efficient Photon Coupling from a Diamond Nitrogen Vacancy Centre by Integration with Silica Fibre

Author

Patel, Rishi N., Schröder, Tim, Wan, Noel, Li, Luozhou, Mouradian, Sara L., Chen, Edward H., and Englund, Dirk R.

Subjects
Physics - Optics, Quantum Physics
Abstract

A central goal in quantum information science is to efficiently interface photons with single optical modes for quantum networking and distributed quantum computing. Here, we introduce and experimentally demonstrate a compact and efficient method for the low-loss coupling of a solid-state qubit, the nitrogen vacancy (NV) centre in diamond, with a single-mode optical fibre. In this approach, single-mode tapered diamond waveguides containing exactly one high quality NV memory are selected and integrated on tapered silica fibres. Numerical optimization of an adiabatic coupler indicates that near-unity-efficiency photon transfer is possible between the two modes. Experimentally, we find an overall collection efficiency between 18-40 % and observe a raw single photon count rate above 700 kHz. This integrated system enables robust, alignment-free, and efficient interfacing of single-mode optical fibres with single photon emitters and quantum memories in solids.

Published
2015
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18. Entanglement-Enhanced Sensing in a Lossy and Noisy Environment

Author

Zhang, Zheshen, Mouradian, Sara, Wong, Franco N. C., and Shapiro, Jeffrey H.

Subjects
Quantum Physics, Physics - Optics
Abstract

Nonclassical states are essential for optics-based quantum information processing, but their fragility limits their utility for practical scenarios in which loss and noise inevitably degrade, if not destroy, nonclassicality. Exploiting nonclassical states in quantum metrology yields sensitivity advantages over all classical schemes delivering the same energy per measurement interval to the sample being probed. These enhancements, almost without exception, are severely diminished by quantum decoherence. Here, we experimentally demonstrate an entanglement-enhanced sensing system that is resilient to quantum decoherence. We employ entanglement to realize a 20% signal-to-noise ratio improvement over the optimum classical scheme in an entanglement-breaking environment plagued by 14 dB of loss and a noise background 75 dB stronger than the returned probe light. Our result suggests that advantageous quantum-sensing technology could be developed for practical situations., Comment: 5 pages, 3 figures

Published
2014
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20. Scalable integration of long-lived quantum memories into a photonic circuit

Author

Mouradian, Sara L., Schröder, Tim, Poitras, Carl B., Li, Luozhou, Goldstein, Jordan, Chen, Edward H., Cardenas, Jaime, Markham, Matthew L., Twitchen, Daniel J., Lipson, Michal, and Englund, Dirk

Subjects
Physics - Optics
Abstract

We demonstrate a photonic circuit with integrated long-lived quantum memories. Pre-selected quantum nodes - diamond micro-waveguides containing single, stable, and negatively charged nitrogen vacancy centers - are deterministically integrated into low-loss silicon nitride waveguides. Each quantum memory node efficiently couples into the single-mode waveguide (> 1 Mcps collected into the waveguide) and exhibits long spin coherence times of up to 120 {\mu}s. Our system facilitates the assembly of multiple quantum memories into a photonic integrated circuit with near unity yield, paving the way towards scalable quantum information processing., Comment: 5 pages, 4 figures

Published
2014

21. Three megahertz photon collection rate from an NV center with millisecond spin coherence

Author

Li, Luozhou, Chen, Edward H., Zheng, Jiabao, Mouradian, Sara L., Dolde, Florian, Schröder, Tim, Karaveli, Sinan, Markham, Matthew L., Twitchen, Daniel J., and Englund, Dirk

Subjects
Physics - Optics
Abstract

Efficient collection of the broadband fluorescence of the diamond nitrogen vacancy center is essential for a range of applications in sensing, on-demand single photon generation, and quantum information processing. Here, we introduce a circular `bullseye' diamond grating enabling a collected photon rate of $(3.0\pm0.1)\times10^6$ counts per second from a single nitrogen-vacancy center with a spin coherence time of 1.7$\pm$0.1 ms. Back-focal-plane studies indicate efficient redistribution into low-NA modes., Comment: 6 pages, 9 figures

Published
2014
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31. Two-Dimensional Photonic Crystal Slab Nanocavities on Bulk Single-Crystal Diamond

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Wan, Noel Heng Loon, Mouradian, Sara L, Englund, Dirk R., Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Wan, Noel Heng Loon, Mouradian, Sara L, and Englund, Dirk R.

Abstract

© 2018 Author(s). Color centers in diamond are promising spin qubits for quantum computing and quantum networking. In photon-mediated entanglement distribution schemes, the efficiency of the optical interface ultimately determines the scalability of such systems. Nano-scale optical cavities coupled to emitters constitute a robust spin-photon interface that can increase spontaneous emission rates and photon extraction efficiencies. In this work, we introduce the fabrication of 2D photonic crystal slab nanocavities with high quality factors and cubic wavelength mode volumes - directly in bulk diamond. This planar platform offers scalability and considerably expands the toolkit for classical and quantum nanophotonics in diamond.

Published
2021

32. Two-dimensional photonic crystal slab nanocavities on bulk single-crystal diamond

Author

Wan, Noel H, Mouradian, Sara, Englund, Dirk, Wan, Noel H, Mouradian, Sara, and Englund, Dirk

Abstract

© 2018 Author(s). Color centers in diamond are promising spin qubits for quantum computing and quantum networking. In photon-mediated entanglement distribution schemes, the efficiency of the optical interface ultimately determines the scalability of such systems. Nano-scale optical cavities coupled to emitters constitute a robust spin-photon interface that can increase spontaneous emission rates and photon extraction efficiencies. In this work, we introduce the fabrication of 2D photonic crystal slab nanocavities with high quality factors and cubic wavelength mode volumes - directly in bulk diamond. This planar platform offers scalability and considerably expands the toolkit for classical and quantum nanophotonics in diamond.

Published
2021

33. A tunable waveguide-coupled cavity design for scalable interfaces to solid-state quantum emitters

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Mouradian, Sara L, Englund, Dirk, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Mouradian, Sara L, and Englund, Dirk

Abstract

© 2017 Author(s). Photonic nanocavities in diamond have emerged as useful structures for interfacing photons and embedded atomic color centers, such as the nitrogen vacancy center. Here, we present a hybrid nanocavity design that enables (i) a loaded quality factor exceeding 50 000 (unloaded Q>106) with 75% of the enhanced emission collected into an underlying waveguide circuit, (ii) MEMS-based cavity spectral tuning without straining the diamond, and (iii) the use of a diamond waveguide with straight sidewalls to minimize surface defects and charge traps. This system addresses the need for scalable on-chip photonic interfaces to solid-state quantum emitters.

Published
2021

34. Large-scale integration of artificial atoms in hybrid photonic circuits

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Han, Noel H., Lu, Tsung-Ju, Chen, Kevin C., Walsh, Michael P., Trusheim, Matthew E, De Santis, Lorenzo, Bersin, Eric Alexander, Harris, Isaac B., Mouradian, Sara L, Christen, Ian R., Englund, Dirk R., Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Han, Noel H., Lu, Tsung-Ju, Chen, Kevin C., Walsh, Michael P., Trusheim, Matthew E, De Santis, Lorenzo, Bersin, Eric Alexander, Harris, Isaac B., Mouradian, Sara L, Christen, Ian R., and Englund, Dirk R.

Abstract

A central challenge in developing quantum computers and long-range quantum networks is the distribution of entanglement across many individually controllable qubits1. Colour centres in diamond have emerged as leading solid-state ‘artificial atom’ qubits2,3 because they enable on-demand remote entanglement4, coherent control of over ten ancillae qubits with minute-long coherence times5 and memory-enhanced quantum communication6. A critical next step is to integrate large numbers of artificial atoms with photonic architectures to enable large-scale quantum information processing systems. So far, these efforts have been stymied by qubit inhomogeneities, low device yield and complex device requirements. Here we introduce a process for the high-yield heterogeneous integration of ‘quantum microchiplets’—diamond waveguide arrays containing highly coherent colour centres—on a photonic integrated circuit (PIC). We use this process to realize a 128-channel, defect-free array of germanium-vacancy and silicon-vacancy colour centres in an aluminium nitride PIC. Photoluminescence spectroscopy reveals long-term, stable and narrow average optical linewidths of 54 megahertz (146 megahertz) for germanium-vacancy (silicon-vacancy) emitters, close to the lifetime-limited linewidth of 32 megahertz (93 megahertz). We show that inhomogeneities of individual colour centre optical transitions can be compensated in situ by integrated tuning over 50 gigahertz without linewidth degradation. The ability to assemble large numbers of nearly indistinguishable and tunable artificial atoms into phase-stable PICs marks a key step towards multiplexed quantum repeaters7,8 and general-purpose quantum processors., United States. National Aeronautics and Space Administration (Contract DE-NA-0003525), National Science Foundation (U.S.) (Award DMR-1419807), United States. Air Force Research Laboratory. RITA program (FA8750-16-2-0141), United States. Department of Energy. Photonics at Thermodynamic Limits’ Energy Frontier Research Center (Grant DE-SC0019140)

Published
2021

35. Individual control and readout of qubits in a sub-diffraction volume

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Bersin, Eric Alexander, Walsh, Michael E, Mouradian, Sara L, Trusheim, Matthew E, Schroder, Tim, Englund, Dirk R., Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Bersin, Eric Alexander, Walsh, Michael E, Mouradian, Sara L, Trusheim, Matthew E, Schroder, Tim, and Englund, Dirk R.

Abstract

Medium-scale ensembles of coupled qubits offer a platform for near-term quantum technologies as well as studies of many-body physics. A central challenge for coherent control of such systems is the ability to measure individual quantum states without disturbing nearby qubits. Here, we demonstrate the measurement of individual qubit states in a sub-diffraction cluster by selectively exciting spectrally distinguishable nitrogen vacancy centers. We perform super-resolution localization of single centers with nanometer spatial resolution, as well as individual control and readout of spin populations. These measurements indicate a readout-induced crosstalk on non-addressed qubits below 4 × 10−2. This approach opens the door to high-speed control and measurement of qubit registers in mesoscopic spin clusters, with applications ranging from entanglement-enhanced sensors to error-corrected qubit registers to multiplexed quantum repeater nodes., National Science Foundation (U.S.) (Grant DMR-1231319), European Commission. Framework Programme for Research and Innovation. Marie Sklodowska-Curie Actions (Agreement 753067 OPHOCS), Germany. Federal Ministry of Education and Research ((BMBF, DiNOQuant, Project 13N14921), United States. Air Force. Office of Scientific Research. Multidisciplinary University Research Initiative (Optimal Measurements for Scalable Quantum Technologies FA9550-14-1-0052), United States. Air Force. Office of Scientific Research (Grant FA9550-16-1-0391)

Published
2021

36. Design and fabrication of a 128-channel array of quantum memories in hybrid photonic circuits

Author

Lu, Tsung-Ju, primary, Wan, Noel H., additional, Chen, Kevin C., additional, Walsh, Michael P., additional, Trusheim, Matthew E., additional, De Santis, Lorenzo, additional, Bersin, Eric A., additional, Harris, Isaac B., additional, Mouradian, Sara L., additional, Christen, Ian R., additional, Bielejec, Edward S., additional, and Englund, Dirk, additional

Published
2020
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37. A 128-channel diamond quantum memory array integrated in a microphotonic chip

Author

Wan, Noel H., primary, Lu, Tsung-Ju, additional, Chen, Kevin C., additional, Walsh, Michael, additional, Trusheim, Matthew, additional, De Santis, Lorenzo, additional, Bersin, Eric, additional, Harris, Isaac, additional, Mouradian, Sara, additional, Christen, Ian, additional, Bielejec, Edward, additional, and Englund, Dirk, additional

Published
2020
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39. Efficient Extraction of Light from a Nitrogen-Vacancy Center in a Diamond Parabolic Reflector

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Wan, Noel Heng Loon, Shields, Brendan J., Kim, Donggyu, Mouradian, Sara L, Lienhard, Benjamin, Walsh, Michael P., Bakhru, Hassaram, Schroder, Tim, Englund, Dirk R., Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Wan, Noel Heng Loon, Shields, Brendan J., Kim, Donggyu, Mouradian, Sara L, Lienhard, Benjamin, Walsh, Michael P., Bakhru, Hassaram, Schroder, Tim, and Englund, Dirk R.

Abstract

Quantum emitters in solids are being developed for a range of quantum technologies, including quantum networks, computing, and sensing. However, a remaining challenge is the poor photon collection due to the high refractive index of most host materials. Here we overcome this limitation by introducing monolithic parabolic reflectors as an efficient geometry for broadband photon extraction from quantum emitter and experimentally demonstrate this device for the nitrogen-vacancy (NV) center in diamond. Simulations indicate a photon collection efficiency exceeding 75% across the visible spectrum and experimental devices, fabricated using a high-throughput gray scale lithography process, demonstrating a photon extraction efficiency of (41 ± 5)%. This device enables a raw experimental detection efficiency of (12 ± 1)% with fluorescence detection rates as high as (4.114 ± 0.003) × 106 counts per second (cps) from a single NV center. Enabled by our deterministic emitter localization and fabrication process, we find a high number of exceptional devices with an average count rate of (3.1 ± 0.9) × 106 cps.

Published
2019

40. Rectangular photonic crystal nanobeam cavities in bulk diamond

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Mouradian, Sara L, Wan, Noel Heng Loon, Shroder, Tim, Englund, Dirk R., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Mouradian, Sara L, Wan, Noel Heng Loon, Shroder, Tim, and Englund, Dirk R.

Abstract

We demonstrate the fabrication of photonic crystal nanobeam cavities with rectangular cross section into bulk diamond. In simulation, these cavities have an unloaded quality (Q) factor of over 1 × 106. Measured cavity resonances show fundamental modes with spectrometer-limited Q factors ≥14×103 within 1 nm of the nitrogen vacancy centers zero phonon line at 637 nm. We find high cavity yield across the full diamond chip with deterministic resonance trends across the fabricated parameter sweeps., National Science Foundation (U.S.) (Grant DMR-1231319)

Published
2019

44. Quantum nanophotonics in diamond [Invited]

Author

Schr��der, Tim, Mouradian, Sara, Zheng, Jiabao, Trusheim, Matthew E., Walsh, Michael, Chen, Edward H., Li, Luozhou, Bayn, Igal, Englund, Dirk, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Schroder, Tim, Mouradian, Sara L, Zheng, Jiabao, Trusheim, Matthew E, Walsh, Michael, Chen, Edward H, Li, Luozhou, Bayn, Igal Igor, and Englund, Dirk R.

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Atomic Physics (physics.atom-ph), Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences, Quantum Physics (quant-ph), Optics (physics.optics), Physics - Atomic Physics, Physics - Optics
Abstract

The past two decades have seen great advances in developing color centers in diamond for sensing, quantum information processing, and tests of quantum foundations. Increasingly, the success of these applications as well as fundamental investigations of light–matter interaction depend on improved control of optical interactions with color centers—from better fluorescence collection to efficient and precise coupling with confined single optical modes. Wide ranging research efforts have been undertaken to address these demands through advanced nanofabrication of diamond. This review will cover recent advances in diamond nano- and microphotonic structures for efficient light collection, color center to nanocavity coupling, hybrid integration of diamond devices with other material systems, and the wide range of fabrication methods that have enabled these complex photonic diamond systems., United States. Air Force Office of Scientific Research (FA9550-11-1-0014), United States. Department of Energy. Office of Basic Energy Sciences (DE-SC0012704)

Published
2016

45. Efficient photon coupling from a diamond nitrogen vacancy center by integration with silica fiber

Author

Patel, Rishi N., Schroder, Tim, Wan, Noel Heng Loon, Li, Luozhou, Mouradian, Sara L, Chen, Edward H, Englund, Dirk R., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Patel, Rishi N., Schroder, Tim, Wan, Noel Heng Loon, Li, Luozhou, Mouradian, Sara L, Chen, Edward H, and Englund, Dirk R.

Subjects
Physics::Optics, Original Article
Abstract

A central goal in quantum information science is to efficiently interface photons with single optical modes for quantum networking and distributed quantum computing. Here, we introduce and experimentally demonstrate a compact and efficient method for the low-loss coupling of a solid-state qubit, the nitrogen vacancy (NV) center in diamond, with a single-mode optical fiber. In this approach, single-mode tapered diamond waveguides containing exactly one high quality NV memory are selected and integrated on tapered silica fibers. Numerical optimization of an adiabatic coupler indicates that near-unity-efficiency photon transfer is possible between the two modes. Experimentally, we find an overall collection efficiency between 16% and 37% and estimate a single photon count rate at saturation above 700 kHz. This integrated system enables robust, alignment-free, and efficient interfacing of single-mode optical fibers with single photon emitters and quantum memories in solids., National Science Foundation (U.S.) (0801525)

Published
2016

46. A scalable quantum computation platform : solid state quantum memories coupled to photonic integrated circuits

Author

Dirk R. Englund., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., Mouradian, Sara L. (Sara Lambert), Dirk R. Englund., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., and Mouradian, Sara L. (Sara Lambert)

Abstract

Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Computer Science, 2018., Cataloged from PDF version of thesis., Includes bibliographical references (pages 93-107)., Quantum computation and communication systems exploit quantum mechanical effects to surpass their classical counterparts in certain applications. However, while proof-of-principle experimental demonstrations have been performed, these are limited to a handful of nodes with limited - and often immutable - connectivity. Here we demonstrate an integrated platform for solid state quantum information processing. Pre-characterized solid state quantum nodes (nitrogen vacancy centers in diamond nanophotonic structures) are placed into a photonic integrated circuit which allows for low-loss and phase-stable collection, routing, and detection of photons as well as on-chip state manipulation and classical control. Moreover, the fabrication of high-quality photonic resonators in diamond allows for the increased emission and collection rates of photons coherent with the spin state. These two advances promise an on-chip entanglement rate much larger than the decoherence rate, allowing the creation and maintenance of cluster states for quantum computation., by Sara Lambert Mouradian., Ph. D.

Published
2018

47. Super-resolution localization and readout of individual solid state qubits

Author

Bersin, Eric, Walsh, Michael, Mouradian, Sara, Trusheim, Matt, Schröder, Tim, Englund, Dirk, Bersin, Eric, Walsh, Michael, Mouradian, Sara, Trusheim, Matt, Schröder, Tim, and Englund, Dirk

Abstract

We demonstrate super-resolution imaging and readout of solid state defect centers. Multiple nitrogen vacancy centers within 130 nm are resolved. Simultaneous control sequences are performed to demonstrate protection of nearby NV states during readout.

Published
2018

48. NV-based quantum memories coupled to photonic integrated circuits

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Mouradian, Sara L, Schroder, Tim, Zheng, Jiabao, Lu, Tsung-Ju Jeff, Choi, Hyeongrak, Wan, Noel Heng Loon, Walsh, Michael E, Bersin, Eric Alexander, Englund, Dirk R., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Mouradian, Sara L, Schroder, Tim, Zheng, Jiabao, Lu, Tsung-Ju Jeff, Choi, Hyeongrak, Wan, Noel Heng Loon, Walsh, Michael E, Bersin, Eric Alexander, and Englund, Dirk R.

Abstract

The negatively charged nitrogen vacancy (NV) center in diamond is a promising solid-state quantum memory. However, developing networks comprising such quantum memories is limited by the fabrication yield of the quantum nodes and the collection efficiency of indistinguishable photons. In this letter, we report on advances on a hybrid quantum system that allows for scalable production of networks, even with low-yield node fabrication. Moreover, an NV center in a simple single mode diamond waveguide is shown in simulation and experiment to couple well to a single mode SiN waveguide with a simple adiabatic taper for optimal mode transfer. In addition, cavity enhancement of the zero phonon line of the NV center with a resonance coupled to the waveguide mode allows a simulated < 1800 fold increase in the collection of photon states coherent with the state of the NV center into a single frequency and spatial mode., United States. Air Force. Office of Scientific Research (Grant FA9550-11-1-0014), U.S. Army Research Laboratory. Center for Distributed Quantum Information (FA9550-14-1-0052)

Published
2018

49. Low-jitter single-photon detector arrays integrated with silicon and aluminum nitride photonic chips

Author

Najafi, Faraz, Mower, Jacob, Bellei, Francesco, Lee, Catherine, Hu, Xiaolong, Schroder, Tim, Kharel, Prashanta, Marsili, Francesco, Assefa, Solomon, Berggren, Karl K., Harris, Nicholas Christopher, Dane, Andrew Edward, Mouradian, Sara L., Englund, Dirk Robert, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Berggren, Karl K., Najafi, Faraz, Mower, Jacob, Harris, Nicholas Christopher, Bellei, Francesco, Dane, Andrew Edward, Lee, Catherine, Hu, Xiaolong, Mouradian, Sara L., Schroder, Tim, and Englund, Dirk Robert

Subjects
Silicon photonics, Materials science, Silicon, business.industry, Hybrid silicon laser, Physics::Instrumentation and Detectors, Photonic integrated circuit, Detector, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, chemistry.chemical_element, Physics::Optics, Nitride, GeneralLiterature_MISCELLANEOUS, chemistry, Optoelectronics, Photonics, business, Electronic circuit, ComputingMethodologies_COMPUTERGRAPHICS
Abstract

We present progress on a scalable scheme for integration of single-photon detectors with silicon and aluminum nitride photonic circuits. We assemble arrays of low-jitter waveguide-integrated single-photon detectors and show up to 24% system detection efficiency.

Published
2015

50. Aluminum nitride integrated photonics platform for the ultraviolet to visible spectrum

Author

Lu, Tsung-Ju, primary, Fanto, Michael, additional, Choi, Hyeongrak, additional, Thomas, Paul, additional, Steidle, Jeffrey, additional, Mouradian, Sara, additional, Kong, Wei, additional, Zhu, Di, additional, Moon, Hyowon, additional, Berggren, Karl, additional, Kim, Jeehwan, additional, Soltani, Mohammad, additional, Preble, Stefan, additional, and Englund, Dirk, additional

Published
2018
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