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
- EurekAlert!: New quantum sensing technology reveals sub-atomic signals
Our paper on nuclear quadrupolar resonance spectroscopy is featured on EurekAlert!
- Congratulations, Mathieu!
Congratulations to Mathieu on defending his PhD thesis!
- Congratulations, Sarah!
Congratulations to Sarah on defending her PhD thesis!
- Congratulations, Becca!
Congratulations to Becca on defending her PhD thesis!
- Congratulations, Sarah!
Sarah has won the Haller Prize, awarded to the best graduate student at the 32nd International Conference on Defects in Semiconductors. “The Haller Prize is named after Eugene E. Haller who was a major figure in the semiconductor community and an inspiring mentor for students.” (http://icds2023.org/prizes)
Recent Publications
Panfil, Yossef E.; Thompson, Sarah M.; Chen, Gary; Ng, Jonah; Kagan, Cherie R.; Bassett, Lee C.
Room-temperature quantum emission from CuZn-VS defects in ZnS:Cu colloidal nanocrystals Journal Article Forthcoming
In: Forthcoming.
@article{Panfil2025,
title = {Room-temperature quantum emission from CuZn-VS defects in ZnS:Cu colloidal nanocrystals},
author = {Yossef E. Panfil and Sarah M. Thompson and Gary Chen and Jonah Ng and Cherie R. Kagan and Lee C. Bassett},
url = {https://arxiv.org/abs/2501.11812},
year = {2025},
date = {2025-01-21},
urldate = {2025-01-21},
abstract = {We report room-temperature observations of CuZn-VS quantum emitters in individual ZnS:Cu nanocrystals (NCs). Using time-gated imaging, we isolate the distinct, ∼3-μs-long, red photoluminescence (PL) emission of CuZn-VS defects, enabling their precise identification and statistical characterization. The emitters exhibit distinct blinking and photon antibunching, consistent with individual NCs containing two to four CuZn-VS defects. The quantum emitters' PL spectra show a pronounced blue shift compared to NC dispersions, likely due to photochemical and charging effects. Emission polarization measurements of quantum emitters are consistent with a σ-character optical dipole transition and the symmetry of the CuZn-VS defect. These observations motivate further investigation of CuZn-VS defects in ZnS NCs for use in quantum technologies.},
keywords = {},
pubstate = {forthcoming},
tppubtype = {article}
}
We report room-temperature observations of CuZn-VS quantum emitters in individual ZnS:Cu nanocrystals (NCs). Using time-gated imaging, we isolate the distinct, ∼3-μs-long, red photoluminescence (PL) emission of CuZn-VS defects, enabling their precise identification and statistical characterization. The emitters exhibit distinct blinking and photon antibunching, consistent with individual NCs containing two to four CuZn-VS defects. The quantum emitters' PL spectra show a pronounced blue shift compared to NC dispersions, likely due to photochemical and charging effects. Emission polarization measurements of quantum emitters are consistent with a σ-character optical dipole transition and the symmetry of the CuZn-VS defect. These observations motivate further investigation of CuZn-VS defects in ZnS NCs for use in quantum technologies.
Huang, Tzu-Yung; Hopper, David A.; Omirzakhov, Kaisarbek; Idjadi, Mohamad Hossein; Breitweiser, S. Alexander; Aflatouni, Firooz; Bassett, Lee C.
Electronic Noise Considerations for Designing Integrated Solid-State Quantum Memories Journal Article Forthcoming
In: Forthcoming.
@article{Huang2024,
title = {Electronic Noise Considerations for Designing Integrated Solid-State Quantum Memories},
author = {Tzu-Yung Huang and David A. Hopper and Kaisarbek Omirzakhov and Mohamad Hossein Idjadi and S. Alexander Breitweiser and Firooz Aflatouni and Lee C. Bassett},
url = {https://arxiv.org/abs/2501.00683},
year = {2024},
date = {2024-12-31},
urldate = {2024-12-31},
abstract = {As quantum networks expand and are deployed outside research laboratories, a need arises to design and integrate compact control electronics for each memory node. It is essential to understand the performance requirements for such systems, especially concerning tolerable levels of noise, since these specifications dramatically affect a system's design complexity and cost. Here, using an approach that can be easily generalized across quantum-hardware platforms, we present a case study based on nitrogen-vacancy (NV) centers in diamond. We model and experimentally verify the effects of phase noise and timing jitter in the control system in conjunction with the spin qubit's environmental noise. We further consider the impact of different phase noise characteristics on the fidelity of dynamical decoupling sequences. The results demonstrate a procedure to specify design requirements for integrated quantum control signal generators for solid-state spin qubits, depending on their coherence time, intrinsic noise spectrum, and required fidelity.},
keywords = {},
pubstate = {forthcoming},
tppubtype = {article}
}
As quantum networks expand and are deployed outside research laboratories, a need arises to design and integrate compact control electronics for each memory node. It is essential to understand the performance requirements for such systems, especially concerning tolerable levels of noise, since these specifications dramatically affect a system's design complexity and cost. Here, using an approach that can be easily generalized across quantum-hardware platforms, we present a case study based on nitrogen-vacancy (NV) centers in diamond. We model and experimentally verify the effects of phase noise and timing jitter in the control system in conjunction with the spin qubit's environmental noise. We further consider the impact of different phase noise characteristics on the fidelity of dynamical decoupling sequences. The results demonstrate a procedure to specify design requirements for integrated quantum control signal generators for solid-state spin qubits, depending on their coherence time, intrinsic noise spectrum, and required fidelity.
Breitweiser, S. Alex; Ouellet, Mathieu; Huang, Tzu-Yung; Taminiau, Tim H.; Bassett, Lee C.
Quadrupolar resonance spectroscopy of individual nuclei using a room-temperature quantum sensor Journal Article
In: Nano Letters, vol. 24, iss. 51, pp. 16253-16260, 2024.
@article{Breitweiser2024,
title = {Quadrupolar resonance spectroscopy of individual nuclei using a room-temperature quantum sensor},
author = {S. Alex Breitweiser and Mathieu Ouellet and Tzu-Yung Huang and Tim H. Taminiau and Lee C. Bassett},
url = {https://pubs.acs.org/doi/abs/10.1021/acs.nanolett.4c04112},
year = {2024},
date = {2024-12-12},
urldate = {2024-12-12},
journal = {Nano Letters},
volume = {24},
issue = {51},
pages = {16253-16260},
abstract = {Nuclear quadrupolar resonance (NQR) spectroscopy reveals chemical bonding patterns in materials and molecules through the unique coupling between nuclear spins and local fields. However, traditional NQR techniques require macroscopic ensembles of nuclei to yield a detectable signal, which obscures molecule-to-molecule variations. Solid-state spin qubits, such as the nitrogen-vacancy (NV) center in diamond, facilitate the detection and control of individual nuclei through their local magnetic couplings. Here, we use NV centers to perform NQR spectroscopy on their associated nitrogen-14 (14N) nuclei at room temperature. In mapping the nuclear quadrupolar Hamiltonian, we resolve minute variations between individual nuclei. The measurements reveal correlations between the Hamiltonian parameters associated with the NV center’s electronic and nuclear spin states, as well as a previously unreported symmetry-breaking quadrupolar term. We further design pulse sequences to initialize, read out, and control the quantum evolution of the 14N nuclear state using the nuclear quadrupolar Hamiltonian.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Nuclear quadrupolar resonance (NQR) spectroscopy reveals chemical bonding patterns in materials and molecules through the unique coupling between nuclear spins and local fields. However, traditional NQR techniques require macroscopic ensembles of nuclei to yield a detectable signal, which obscures molecule-to-molecule variations. Solid-state spin qubits, such as the nitrogen-vacancy (NV) center in diamond, facilitate the detection and control of individual nuclei through their local magnetic couplings. Here, we use NV centers to perform NQR spectroscopy on their associated nitrogen-14 (14N) nuclei at room temperature. In mapping the nuclear quadrupolar Hamiltonian, we resolve minute variations between individual nuclei. The measurements reveal correlations between the Hamiltonian parameters associated with the NV center’s electronic and nuclear spin states, as well as a previously unreported symmetry-breaking quadrupolar term. We further design pulse sequences to initialize, read out, and control the quantum evolution of the 14N nuclear state using the nuclear quadrupolar Hamiltonian.
Bhatia, Pia; Shin, Trey T.; Kavetsky, Kyril; Sailors, Benjamin N.; Siokos, George; Uy-Tioco, Alexandra Sofia; Keneipp, Rachael N.; Gusdorff, Jordan A.; Bassett, Lee C.; Drndić, Marija
In: Micron, vol. 189, pp. 103747, 2024.
@article{Bhatia2024,
title = {A tale of two transfers: characterizing polydimethylsiloxane viscoelastic stamping and heated poly bis-A carbonate transfer of hexagonal boron nitride},
author = {Pia Bhatia and Trey T. Shin and Kyril Kavetsky and Benjamin N. Sailors and George Siokos and Alexandra Sofia Uy-Tioco and Rachael N. Keneipp and Jordan A. Gusdorff and Lee C. Bassett and Marija Drndić},
url = {https://www.sciencedirect.com/science/article/pii/S0968432824001641#sec0080},
doi = {10.1016/j.micron.2024.103747},
year = {2024},
date = {2024-11-26},
urldate = {2024-11-26},
journal = {Micron},
volume = {189},
pages = {103747},
abstract = {Two-dimensional (2D) materials have many applications ranging from heterostructure electronics to nanofluidics and quantum technology. In order to effectively utilize 2D materials towards these ends, they must be transferred and integrated into complex device geometries. In this report, we investigate two conventional methods for the transfer of 2D materials: viscoelastic stamping with polydimethylsiloxane (PDMS) and a heated transfer with poly bis-A carbonate (PC). We use both methods to transfer mechanically-exfoliated flakes of hexagonal boron nitride onto silicon nitride (SiNx) substrates and characterize the resulting transfers using atomic force microscopy (AFM), aberration-corrected scanning transmission electron microscopy (AC-STEM) and electron energy loss spectroscopy (EELS). We find that both transfer methods yield flakes with significant and comparable residue (within the limitations of our study on eight samples). Qualitative interpretation of EELS maps demonstrates that this residue is comprised of silicon, carbon and oxygen for both transfer methods. Quantitative analysis of AC-STEM images reveals that the area covered in residue is on average, slightly lower for PDMS transfers (31 % ± 1 %), compared to PC transfers (41 % ± 4 %). This work underscores the importance of improving existing transfer protocols towards applications where cleaner materials are critical, as well as the need for robust methods to clean 2D materials.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Two-dimensional (2D) materials have many applications ranging from heterostructure electronics to nanofluidics and quantum technology. In order to effectively utilize 2D materials towards these ends, they must be transferred and integrated into complex device geometries. In this report, we investigate two conventional methods for the transfer of 2D materials: viscoelastic stamping with polydimethylsiloxane (PDMS) and a heated transfer with poly bis-A carbonate (PC). We use both methods to transfer mechanically-exfoliated flakes of hexagonal boron nitride onto silicon nitride (SiNx) substrates and characterize the resulting transfers using atomic force microscopy (AFM), aberration-corrected scanning transmission electron microscopy (AC-STEM) and electron energy loss spectroscopy (EELS). We find that both transfer methods yield flakes with significant and comparable residue (within the limitations of our study on eight samples). Qualitative interpretation of EELS maps demonstrates that this residue is comprised of silicon, carbon and oxygen for both transfer methods. Quantitative analysis of AC-STEM images reveals that the area covered in residue is on average, slightly lower for PDMS transfers (31 % ± 1 %), compared to PC transfers (41 % ± 4 %). This work underscores the importance of improving existing transfer protocols towards applications where cleaner materials are critical, as well as the need for robust methods to clean 2D materials.
Gusdorff, Jordan A.; Bhatia, Pia; Shin, Trey T.; Uy-Tioco, Alexandra Sofia; Sailors, Benjamin N.; Keneipp, Rachael N.; Drndić, Marija; Bassett, Lee C.
Correlated Structural and Optical Characterization of Hexagonal Boron Nitride Journal Article Forthcoming
In: Forthcoming.
@article{Gusdorff2024,
title = {Correlated Structural and Optical Characterization of Hexagonal Boron Nitride},
author = {Jordan A. Gusdorff and Pia Bhatia and Trey T. Shin and Alexandra Sofia Uy-Tioco and Benjamin N. Sailors and Rachael N. Keneipp and Marija Drndić and Lee C. Bassett},
url = {https://arxiv.org/abs/2411.14408},
doi = {10.48550/arXiv.2411.14408},
year = {2024},
date = {2024-11-21},
urldate = {2024-11-21},
abstract = {Hexagonal boron nitride (hBN) hosts quantum emitters that exhibit single-photon emission and spin-dependent fluorescence at room temperature. These features make hBN a promising platform for quantum sensing and photonics. Despite many investigations of their optical properties, the emitters' chemical structure remains unclear, as does the role of contamination at surfaces and interfaces in forming the emitters or modifying their properties. We prepare hBN samples that are compatible with both confocal photoluminescence microscopy (PL) and transmission electron microscopy (TEM), and we use those techniques to investigate correlations between fluorescent emission, flake morphology, and surface residue. We find that the microscopy techniques themselves induce changes in hBN's optical activity and residue morphology: PL measurements induce photobleaching, whereas TEM measurements alter surface residue and emission characteristics. We also study the effects of common treatments — annealing and oxygen plasma cleaning — on the structure and optical activity of hBN. The results illustrate the power and importance of correlative studies to elucidate aspects of microscopic mechanisms that influence hBN's functionality as a host for quantum emitters and spin defects.},
keywords = {},
pubstate = {forthcoming},
tppubtype = {article}
}
Hexagonal boron nitride (hBN) hosts quantum emitters that exhibit single-photon emission and spin-dependent fluorescence at room temperature. These features make hBN a promising platform for quantum sensing and photonics. Despite many investigations of their optical properties, the emitters' chemical structure remains unclear, as does the role of contamination at surfaces and interfaces in forming the emitters or modifying their properties. We prepare hBN samples that are compatible with both confocal photoluminescence microscopy (PL) and transmission electron microscopy (TEM), and we use those techniques to investigate correlations between fluorescent emission, flake morphology, and surface residue. We find that the microscopy techniques themselves induce changes in hBN's optical activity and residue morphology: PL measurements induce photobleaching, whereas TEM measurements alter surface residue and emission characteristics. We also study the effects of common treatments — annealing and oxygen plasma cleaning — on the structure and optical activity of hBN. The results illustrate the power and importance of correlative studies to elucidate aspects of microscopic mechanisms that influence hBN's functionality as a host for quantum emitters and spin defects.