Quantum Engineering Laboratory
Our group studies quantum dynamics in nanoscale materials and devices using optics and electronics. We seek to better understand complex quantum-mechanical systems, with a goal of developing new technologies for communication, computation, and sensing based on quantum physics.
News
- Congratulations, Alex!Alex Breitweiser is awarded an IBM PhD Fellowship.
- Congratulations, Jordan!Incoming PhD student Jordan Gusdorff is awarded an NSF Graduate Research Fellowship.
- Congratulations, Abby!Abigail Poteshman is awarded the William E. Stephens Prize from the Penn. Dept. of Physics & Astronomy.
- Our paper on real-time control is selected as an Editor’s suggestion in Phys. Rev. Applied
- Penn Medium: Penn Engineers Ensure Quantum Experiments Get Off to the Right StartOur paper on real-time control is featured in Penn Medium.
Recent Publications
 | Kagan, Cherie R; Bassett, Lee C; Murray, Christopher B; Thompson, Sarah M Colloidal Quantum Dots as Platforms for Quantum Information Science Journal Article Chemical Reviews, 2020. @article{Kagan2020, title = {Colloidal Quantum Dots as Platforms for Quantum Information Science}, author = {Cherie R. Kagan and Lee C. Bassett and Christopher B. Murray and Sarah M. Thompson}, url = {https://pubs.acs.org/doi/10.1021/acs.chemrev.0c00831}, doi = {10.1021/acs.chemrev.0c00831}, year = {2020}, date = {2020-12-29}, journal = {Chemical Reviews}, abstract = {Colloidal quantum dots (QDs) are nanoscale semiconductor crystals with surface ligands that enable their dispersion in solvents. Quantum confinement effects facilitate wave function engineering to sculpt the spatial distribution of charge and spin states and thus the energy and dynamics of QD optical transitions. Colloidal QDs can be integrated in devices using solution-based assembly methods to position single QDs and to create ordered QD arrays. Here, we describe the synthesis, assembly, and photophysical properties of colloidal QDs that have captured scientific imagination and have been harnessed in optical applications. We focus especially on the current understanding of their quantum coherent effects and opportunities to exploit QDs as platforms for quantum information science. Freedom in QD design to isolate and control the quantum mechanical properties of charge, spin, and light presents various approaches to create systems with robust, addressable quantum states. We consider the attributes of QDs for optically addressable qubits in emerging quantum computation, sensing, simulation, and communication technologies, e.g., as robust sources of indistinguishable, single photons that can be integrated into photonic structures to amplify, direct, and tune their emission or as hosts for isolated, coherent spin states that can be coupled to light or to other spins in QD arrays.}, keywords = {}, pubstate = {published}, tppubtype = {article} } Colloidal quantum dots (QDs) are nanoscale semiconductor crystals with surface ligands that enable their dispersion in solvents. Quantum confinement effects facilitate wave function engineering to sculpt the spatial distribution of charge and spin states and thus the energy and dynamics of QD optical transitions. Colloidal QDs can be integrated in devices using solution-based assembly methods to position single QDs and to create ordered QD arrays. Here, we describe the synthesis, assembly, and photophysical properties of colloidal QDs that have captured scientific imagination and have been harnessed in optical applications. We focus especially on the current understanding of their quantum coherent effects and opportunities to exploit QDs as platforms for quantum information science. Freedom in QD design to isolate and control the quantum mechanical properties of charge, spin, and light presents various approaches to create systems with robust, addressable quantum states. We consider the attributes of QDs for optically addressable qubits in emerging quantum computation, sensing, simulation, and communication technologies, e.g., as robust sources of indistinguishable, single photons that can be integrated into photonic structures to amplify, direct, and tune their emission or as hosts for isolated, coherent spin states that can be coupled to light or to other spins in QD arrays. |
 | Bassett, L C Quantum optics with single spins Book Chapter Forthcoming Forthcoming. @inbook{Bassett2019, title = {Quantum optics with single spins}, author = {L C Bassett}, url = {https://arxiv.org/abs/1908.05566}, year = {2020}, date = {2020-11-13}, abstract = {Based on lectures at the 2018 International School of Physics "Enrico Fermi", Course 204: Nanoscale Quantum Optics Defects in solids are in many ways analogous to trapped atoms or molecules. They can serve as long-lived quantum memories and efficient light-matter interfaces. As such, they are leading building blocks for long-distance quantum networks and distributed quantum computers. This chapter describes the quantum-mechanical coupling between atom-like spin states and light, using the diamond nitrogen-vacancy (NV) center as a paradigm. We present an overview of the NV center's electronic structure, derive a general picture of coherent light-matter interactions, and describe several methods that can be used to achieve all-optical initialization, quantum-coherent control, and readout of solid-state spins. These techniques can be readily generalized to other defect systems, and they serve as the basis for advanced protocols at the heart of many emerging quantum technologies.}, keywords = {}, pubstate = {forthcoming}, tppubtype = {inbook} } Based on lectures at the 2018 International School of Physics "Enrico Fermi", Course 204: Nanoscale Quantum Optics Defects in solids are in many ways analogous to trapped atoms or molecules. They can serve as long-lived quantum memories and efficient light-matter interfaces. As such, they are leading building blocks for long-distance quantum networks and distributed quantum computers. This chapter describes the quantum-mechanical coupling between atom-like spin states and light, using the diamond nitrogen-vacancy (NV) center as a paradigm. We present an overview of the NV center's electronic structure, derive a general picture of coherent light-matter interactions, and describe several methods that can be used to achieve all-optical initialization, quantum-coherent control, and readout of solid-state spins. These techniques can be readily generalized to other defect systems, and they serve as the basis for advanced protocols at the heart of many emerging quantum technologies. |
 | Hopper, D A; Lauigan, J D; Huang, T -Y; Bassett, L C Real-Time Charge Initialization of Diamond Nitrogen-Vacancy Centers for Enhanced Spin Readout Journal Article Phys. Rev. Applied, 13 , pp. 024016, 2020. @article{Hopper2019, title = {Real-Time Charge Initialization of Diamond Nitrogen-Vacancy Centers for Enhanced Spin Readout}, author = {D A Hopper and J D Lauigan and T -Y Huang and L C Bassett}, url = {https://arxiv.org/abs/1907.08741 https://journals.aps.org/prapplied/abstract/10.1103/PhysRevApplied.13.024016 https://medium.com/penn-engineering/penn-engineers-ensure-quantum-experiments-get-off-to-the-right-start-bbe6f3382cb}, year = {2020}, date = {2020-02-07}, journal = {Phys. Rev. Applied}, volume = {13}, pages = {024016}, abstract = {Selected as an Editor's Suggestion. A common impediment to qubit performance is imperfect state initialization. In the case of the diamond nitrogen-vacancy (NV) center, the initialization fidelity is limited by fluctuations in the defect's charge state during optical pumping. Here, we use real-time control to deterministically initialize the NV center's charge state at room temperature. We demonstrate a maximum charge initialization fidelity of 99.4±0.1% and present a quantitative model of the initialization process that allows for systems-level optimization of the spin-readout signal-to-noise ratio. Even accounting for the overhead associated with the initialization sequence, increasing the charge initialization fidelity from the steady-state value of 75% near to unity allows for a factor-of-two speedup in experiments while maintaining the same signal-to-noise-ratio. In combination with high-fidelity readout based on spin-to-charge conversion, real-time initialization enables a factor-of-20 speedup over traditional methods, resulting in an ac magnetic sensitivity of 1.3 nT/Hz1/2 for our single NV-center spin. The real-time control method is immediately beneficial for quantum sensing applications with NV centers as well as probing charge-dependent physics, and it will facilitate protocols for quantum feedback control over multi-qubit systems.}, keywords = {}, pubstate = {published}, tppubtype = {article} } Selected as an Editor's Suggestion. A common impediment to qubit performance is imperfect state initialization. In the case of the diamond nitrogen-vacancy (NV) center, the initialization fidelity is limited by fluctuations in the defect's charge state during optical pumping. Here, we use real-time control to deterministically initialize the NV center's charge state at room temperature. We demonstrate a maximum charge initialization fidelity of 99.4±0.1% and present a quantitative model of the initialization process that allows for systems-level optimization of the spin-readout signal-to-noise ratio. Even accounting for the overhead associated with the initialization sequence, increasing the charge initialization fidelity from the steady-state value of 75% near to unity allows for a factor-of-two speedup in experiments while maintaining the same signal-to-noise-ratio. In combination with high-fidelity readout based on spin-to-charge conversion, real-time initialization enables a factor-of-20 speedup over traditional methods, resulting in an ac magnetic sensitivity of 1.3 nT/Hz1/2 for our single NV-center spin. The real-time control method is immediately beneficial for quantum sensing applications with NV centers as well as probing charge-dependent physics, and it will facilitate protocols for quantum feedback control over multi-qubit systems. |
 | Breitweiser, S A; Exarhos, A L; Patel, R N; Saouaf, J; Porat, B; Hopper, D A; Bassett, L C Efficient optical quantification of heterogeneous emitter ensembles Journal Article ACS Photonics, 7 , pp. 288-295, 2019. @article{Breitweiser2019, title = {Efficient optical quantification of heterogeneous emitter ensembles}, author = {S A Breitweiser and A L Exarhos and R N Patel and J Saouaf and B Porat and D A Hopper and L C Bassett}, url = {https://arxiv.org/abs/1909.12726 https://pubs.acs.org/doi/10.1021/acsphotonics.9b01707}, year = {2019}, date = {2019-12-17}, journal = {ACS Photonics}, volume = {7}, pages = {288-295}, abstract = {Defect-based quantum emitters in solid state materials offer a promising platform for quantum communication and sensing. Confocal fluorescence microscopy techniques have revealed quantum emitters in a multitude of host materials. In some materials, however, optical properties vary widely between emitters, even within the same sample. In these cases, traditional ensemble fluorescence measurements are confounded by heterogeneity, whereas individual defect-by-defect studies are impractical. Here, we develop a method to quantitatively and systematically analyze the properties of heterogeneous emitter ensembles using large-area photoluminescence maps. We apply this method to study the effects of sample treatments on emitters in hexagonal boron nitride, and we find that low-energy (3 keV) electron irradiation creates emitters, whereas high-temperature (850 ∘C) annealing in an inert gas environment brightens emitters.}, keywords = {}, pubstate = {published}, tppubtype = {article} } Defect-based quantum emitters in solid state materials offer a promising platform for quantum communication and sensing. Confocal fluorescence microscopy techniques have revealed quantum emitters in a multitude of host materials. In some materials, however, optical properties vary widely between emitters, even within the same sample. In these cases, traditional ensemble fluorescence measurements are confounded by heterogeneity, whereas individual defect-by-defect studies are impractical. Here, we develop a method to quantitatively and systematically analyze the properties of heterogeneous emitter ensembles using large-area photoluminescence maps. We apply this method to study the effects of sample treatments on emitters in hexagonal boron nitride, and we find that low-energy (3 keV) electron irradiation creates emitters, whereas high-temperature (850 ∘C) annealing in an inert gas environment brightens emitters. |