Your search keyword '"Hong, Sungkun"' showing total 33 results

1. Enhanced optomechanical coupling between an optically levitated particle and an ultrahigh Q optical microcavity

Author

Alavi, Seyed Khalil, Sheng, Zijie, Lee, Haneul, Lee, Hansuek, and Hong, Sungkun

Subjects

Physics - Optics

Abstract

Exploring the dynamics of an optically levitated dielectric micro- and nanoparticle is an exciting new subject in quantum science. Recent years have witnessed rapid advancements in attaining quantum-limited optical detection and control of a nanoscale particle by coupling its motion to a high-finesse optical cavity in the resolved-sideband regime. In order to control the particle deeper in the quantum regime, it is necessary to significantly enhance the coupling between the particle and the cavity. Here, we present a novel platform that can allow for achieving this. Our system consists of a conventional optical tweezer and a toroidal optical microcavity with an ultrahigh quality (Q) factor. The optomechanical coupling between the particle and the cavity is established by placing the particle in the near field of the cavity. The significantly reduced mode volume allows us to achieve a 50-fold increase in the single photon optomechanical coupling compared to a conventional Fabry-P\'erot cavity with macroscopic mirrors, while ultralow loss of the cavity brings the system close to the resolved-sideband regime. Our approach paves the way for enabling quantum experiments on levitated mesoscopic particles with high quantum cooperativity near the resolved-sideband regime.

Published

2024

2. Optomechanically induced optical trapping system based on photonic crystal cavities

Author

Monterrosas-Romero, Manuel, Alavi, Seyed K., Koistinen, Ester M., and Hong, Sungkun

Subjects

Physics - Optics

Abstract

Optical trapping has proven to be a valuable experimental technique for precisely controlling small dielectric objects. However, due to their very nature, conventional optical traps are diffraction limited and require high intensities to confine the dielectric objects. In this work, we propose a novel optical trap based on dielectric photonic crystal nanobeam cavities, which overcomes the limitations of conventional optical traps by significant factors. This is achieved by exploiting an optomechanically induced backaction mechanism between a dielectric nanoparticle and the cavities. We perform numerical simulations to show that our trap can fully levitate a submicron-scale dielectric particle with a trap width as narrow as 56 nm. It allows for achieving a high trap stiffness, therefore, a high Q-frequency product for the particle's motion while reducing the optical absorption by a factor of 43 compared to the cases for conventional optical tweezers. Moreover, we show that multiple laser tones can be used further to create a complex, dynamic potential landscape with feature sizes well below the diffraction limit. The presented optical trapping system offers new opportunities for precision sensing and fundamental quantum experiments based on levitated particles.

Published

2023

3. Real-time optimal quantum control of mechanical motion at room temperature

Author

Magrini, Lorenzo, Rosenzweig, Philipp, Bach, Constanze, Deutschmann-Olek, Andreas, Hofer, Sebastian G., Hong, Sungkun, Kiesel, Nikolai, Kugi, Andreas, and Aspelmeyer, Markus

Subjects

Quantum Physics, Physics - Atomic Physics, Physics - Optics

Abstract

The ability to accurately control the dynamics of physical systems by measurement and feedback is a pillar of modern engineering. Today, the increasing demand for applied quantum technologies requires to adapt this level of control to individual quantum systems. Achieving this in an optimal way is a challenging task that relies on both quantum-limited measurements and specifically tailored algorithms for state estimation and feedback. Successful implementations thus far include experiments on the level of optical and atomic systems. Here we demonstrate real-time optimal control of the quantum trajectory of an optically trapped nanoparticle. We combine confocal position sensing close to the Heisenberg limit with optimal state estimation via Kalman filtering to track the particle motion in phase space in real time with a position uncertainty of 1.3 times the zero point fluctuation. Optimal feedback allows us to stabilize the quantum harmonic oscillator to a mean occupation of $n=0.56\pm0.02$ quanta, realizing quantum ground state cooling from room temperature. Our work establishes quantum Kalman filtering as a method to achieve quantum control of mechanical motion, with potential implications for sensing on all scales. In combination with levitation, this paves the way to full-scale control over the wavepacket dynamics of solid-state macroscopic quantum objects in linear and nonlinear systems.

Published

2020

4. An optomechanical Bell test

Author

Marinkovic, Igor, Wallucks, Andreas, Riedinger, Ralf, Hong, Sungkun, Aspelmeyer, Markus, and Gröblacher, Simon

Subjects

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

Abstract

Over the past few decades, experimental tests of Bell-type inequalities have been at the forefront of understanding quantum mechanics and its implications. These strong bounds on specific measurements on a physical system originate from some of the most fundamental concepts of classical physics - in particular that properties of an object are well defined independent of measurements (realism) and only affected by local interactions (locality). The violation of these bounds unambiguously shows that the measured system does not behave classically, void of any assumption on the validity of quantum theory. It has also found applications in quantum technologies for certifying the suitability of devices for generating quantum randomness, distributing secret keys and for quantum computing. Here we report on the violation of a Bell inequality involving a massive, macroscopic mechanical system. We create light-matter entanglement between the vibrational motion of two silicon optomechanical oscillators, each comprising approx. $10^{10}$ atoms, and two optical modes. This state allows us to violate a Bell inequality by more than 4 standard deviations, directly confirming the non-classical behavior of our optomechanical system under the fair sampling assumption.

Published

2018

5. Near-field coupling of a levitated nanoparticle to a photonic crystal cavity

Author

Magrini, Lorenzo, Norte, Richard A., Riedinger, Ralf, Marinković, Igor, Grass, David, Delić, Uroš, Gröblacher, Simon, Hong, Sungkun, and Aspelmeyer, Markus

Subjects

Quantum Physics, Physics - Optics

Abstract

Quantum control of levitated dielectric particles is an emerging subject in quantum optomechanics. A major challenge is to efficiently measure and manipulate the particle's motion at the Heisenberg uncertainty limit. Here we present a nanophotonic interface suited to address this problem. By optically trapping a 150 nm silica particle and placing it in the near field of a photonic crystal cavity, we achieve tunable single-photon optomechanical coupling of up to $g_0/2\pi=9$ kHz, three orders of magnitude larger than previously reported for levitated cavity optomechanical systems. Efficient collection and guiding of light through the nanophotonic structure results in a per-photon displacement sensitivity that is increased by two orders of magnitude compared to conventional far-field detection. The demonstrated performance shows a promising route for room temperature quantum optomechanics.

Published

2018

6. Remote quantum entanglement between two micromechanical oscillators

Author

Riedinger, Ralf, Wallucks, Andreas, Marinkovic, Igor, Löschnauer, Clemens, Aspelmeyer, Markus, Hong, Sungkun, and Gröblacher, Simon

Subjects

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

Abstract

Entanglement, an essential feature of quantum theory that allows for inseparable quantum correlations to be shared between distant parties, is a crucial resource for quantum networks. Of particular importance is the ability to distribute entanglement between remote objects that can also serve as quantum memories. This has been previously realized using systems such as warm and cold atomic vapours, individual atoms and ions, and defects in solid-state systems. Practical communication applications require a combination of several advantageous features, such as a particular operating wavelength, high bandwidth and long memory lifetimes. Here we introduce a purely micromachined solid-state platform in the form of chip-based optomechanical resonators made of nanostructured silicon beams. We create and demonstrate entanglement between two micromechanical oscillators across two chips that are separated by 20 centimetres. The entangled quantum state is distributed by an optical field at a designed wavelength near 1550 nanometres. Therefore, our system can be directly incorporated in a realistic fibre-optic quantum network operating in the conventional optical telecommunication band. Our results are an important step towards the development of large-area quantum networks based on silicon photonics.

Published

2017

7. Hanbury Brown and Twiss interferometry of single phonons from an optomechanical resonator

Author

Hong, Sungkun, Riedinger, Ralf, Marinkovic, Igor, Wallucks, Andreas, Hofer, Sebastian G., Norte, Richard A., Aspelmeyer, Markus, and Gröblacher, Simon

Subjects

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

Abstract

Nano- and micromechanical solid-state quantum devices have become a focus of attention. Reliably generating nonclassical states of their motion is of interest both for addressing fundamental questions about macroscopic quantum phenomena and for developing quantum technologies in the domains of sensing and transduction. We used quantum optical control techniques to conditionally generate single-phonon Fock states of a nanomechanical resonator. We performed a Hanbury Brown and Twiss-type experiment that verified the nonclassical nature of the phonon state without requiring full state reconstruction. Our result establishes purely optical quantum control of a mechanical oscillator at the single-phonon level.

Published

2017

8. Non-classical correlations between single photons and phonons from a mechanical oscillator

Author

Riedinger, Ralf, Hong, Sungkun, Norte, Richard A., Slater, Joshua A., Shang, Juying, Krause, Alexander G., Anant, Vikas, Aspelmeyer, Markus, and Gröblacher, Simon

Subjects

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

Abstract

Interfacing a single photon with another quantum system is a key capability in modern quantum information science. It allows quantum states of matter, such as spin states of atoms, atomic ensembles or solids, to be prepared and manipulated by photon counting and, in particular, to be distributed over long distances. Such light-matter interfaces have become crucial to fundamental tests of quantum physics and realizations of quantum networks. Here we report non-classical correlations between single photons and phonons -- the quanta of mechanical motion -- from a nanomechanical resonator. We implement a full quantum protocol involving initialization of the resonator in its quantum ground state of motion and subsequent generation and read-out of correlated photonphonon pairs. The observed violation of a Cauchy-Schwarz inequality is clear evidence for the non-classical nature of the mechanical state generated. Our results demonstrate the availability of on-chip solid-state mechanical resonators as light-matter quantum interfaces. The performance we achieved will enable studies of macroscopic quantum phenomena as well as applications in quantum communication, as quantum memories and as quantum transducers.

Published

2015

9. Real-time optimal quantum control of mechanical motion at room temperature

Author

Magrini, Lorenzo, Rosenzweig, Philipp, Bach, Constanze, Deutschmann-Olek, Andreas, Hofer, Sebastian G., Hong, Sungkun, Kiesel, Nikolai, Kugi, Andreas, and Aspelmeyer, Markus

Subjects

Control systems -- Research, Motion -- Research, Quantum computing -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

The ability to accurately control the dynamics of physical systems by measurement and feedback is a pillar of modern engineering.sup.1. Today, the increasing demand for applied quantum technologies requires adaptation of this level of control to individual quantum systems.sup.2,3. Achieving this in an optimal way is a challenging task that relies on both quantum-limited measurements and specifically tailored algorithms for state estimation and feedback.sup.4. Successful implementations thus far include experiments on the level of optical and atomic systems.sup.5-7. Here we demonstrate real-time optimal control of the quantum trajectory.sup.8 of an optically trapped nanoparticle. We combine confocal position sensing close to the Heisenberg limit with optimal state estimation via Kalman filtering to track the particle motion in phase space in real time with a position uncertainty of 1.3 times the zero-point fluctuation. Optimal feedback allows us to stabilize the quantum harmonic oscillator to a mean occupation of 0.56 [plus or minus] 0.02 quanta, realizing quantum ground-state cooling from room temperature. Our work establishes quantum Kalman filtering as a method to achieve quantum control of mechanical motion, with potential implications for sensing on all scales. In combination with levitation, this paves the way to full-scale control over the wavepacket dynamics of solid-state macroscopic quantum objects in linear and nonlinear systems. Optimal quantum control of an optically trapped nanoparticle in its ground state is demonstrated at room temperature, using Kalman filtering to track its quantum trajectory in real time., Author(s): Lorenzo Magrini [sup.1] , Philipp Rosenzweig [sup.2] , Constanze Bach [sup.1] , Andreas Deutschmann-Olek [sup.2] , Sebastian G. Hofer [sup.1] , Sungkun Hong [sup.3] [sup.4] , Nikolai Kiesel [sup.1] [...]

Published

2021

10. Decoherence imaging of spin ensembles using a scanning single-electron spin in diamond

Author

Luan, Lan, Grinolds, Michael S., Hong, Sungkun, Maletinsky, Patrick, Walsworth, Ronald L., and Yacoby, Amir

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The nitrogen-vacancy (NV) defect center in diamond has demonstrated great capability for nanoscale magnetic sensing and imaging for both static and periodically modulated target fields. However, it remains a challenge to detect and image randomly fluctuating magnetic fields. Recent theoretical and numerical works have outlined detection schemes that exploit changes in decoherence of the detector spin as a sensitive measure for fluctuating fields. Here we experimentally monitor the decoherence of a scanning NV center in order to image the fluctuating magnetic fields from paramagnetic impurities on an underlying diamond surface. We detect a signal corresponding to roughly 800 ${\mu}_B$ in 2 s of integration time, without any control on the target spins, and obtain magnetic-field spectral information using dynamical decoupling techniques. The extracted spatial and temporal properties of the surface paramagnetic impurities provide insight to prolonging the coherence of near-surface qubits for quantum information and metrology applications.

Published

2014

11. Coherent, mechanical control of a single electronic spin

Author

Hong, Sungkun, Grinolds, Michael S., Maletinsky, Patrick, Walsworth, Ronald L., Lukin, Mikhail D., and Yacoby, Amir

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The ability to control and manipulate spins via electrical, magnetic and optical means has generated numerous applications in metrology and quantum information science in recent years. A promising alternative method for spin manipulation is the use of mechanical motion, where the oscillation of a mechanical resonator can be magnetically coupled to a spins magnetic dipole, which could enable scalable quantum information architectures9 and sensitive nanoscale magnetometry. To date, however, only population control of spins has been realized via classical motion of a mechanical resonator. Here, we demonstrate coherent mechanical control of an individual spin under ambient conditions using the driven motion of a mechanical resonator that is magnetically coupled to the electronic spin of a single nitrogen-vacancy (NV) color center in diamond. Coherent control of this hybrid mechanical/spin system is achieved by synchronizing pulsed spin-addressing protocols (involving optical and radiofrequency fields) to the motion of the driven oscillator, which allows coherent mechanical manipulation of both the population and phase of the spin via motion-induced Zeeman shifts of the NV spins energy. We demonstrate applications of this coherent mechanical spin-control technique to sensitive nanoscale scanning magnetometry., Comment: 6 pages, 4 figures

Published

2012

12. Single Color Centers Implanted in Diamond Nanostructures

Author

Hausmann, Birgit J. M., Babinec, Thomas M., Choy, Jennifer T., Hodges, Jonathan S., Hong, Sungkun, Bulu, Irfan, Yacoby, A., Lukin, M. D., and Lončar, Marko

Subjects

Condensed Matter - Materials Science, Quantum Physics

Abstract

The development of materials processing techniques for optical diamond nanostructures containing a single color center is an important problem in quantum science and technology. In this work, we present the combination of ion implantation and top-down diamond nanofabrication in two scenarios: diamond nanopillars and diamond nanowires. The first device consists of a 'shallow' implant (~20nm) to generate Nitrogen-vacancy (NV) color centers near the top surface of the diamond crystal. Individual NV centers are then isolated mechanically by dry etching a regular array of nanopillars in the diamond surface. Photon anti-bunching measurements indicate that a high yield (>10%) of the devices contain a single NV center. The second device demonstrates 'deep' (~1\mu m) implantation of individual NV centers into pre-fabricated diamond nanowire. The high single photon flux of the nanowire geometry, combined with the low background fluorescence of the ultrapure diamond, allows us to sustain strong photon anti-bunching even at high pump powers., Comment: 20 pages, 7 figures

Published

2010

13. Remote quantum entanglement between two micromechanical oscillators

Author

Riedinger, Ralf, Wallucks, Andreas, Marinkovic, Igor, Löschnauer, Clemens, Aspelmeyer, Markus, Hong, Sungkun, and Gröblacher, Simon

Subjects

Oscillators -- Research, Quantum mechanics -- Research, Physics research, Silicon, Fiber optic equipment, Atoms, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Entanglement, an essential feature of quantum theory that allows for inseparable quantum correlations to be shared between distant parties, is a crucial resource for quantum networks.sup.1. Of particular importance is the ability to distribute entanglement between remote objects that can also serve as quantum memories. This has been previously realized using systems such as warm.sup.2,3 and cold atomic vapours.sup.4,5, individual atoms.sup.6 and ions.sup.7,8, and defects in solid-state systems.sup.9-11. Practical communication applications require a combination of several advantageous features, such as a particular operating wavelength, high bandwidth and long memory lifetimes. Here we introduce a purely micromachined solid-state platform in the form of chip-based optomechanical resonators made of nanostructured silicon beams. We create and demonstrate entanglement between two micromechanical oscillators across two chips that are separated by 20 centimetres . The entangled quantum state is distributed by an optical field at a designed wavelength near 1,550 nanometres. Therefore, our system can be directly incorporated in a realistic fibre-optic quantum network operating in the conventional optical telecommunication band. Our results are an important step towards the development of large-area quantum networks based on silicon photonics. Remote quantum entanglement is demonstrated in a micromachined solid-state system comprising two optomechanical oscillators across two chips physically separated by 20 cm and with an optical separation of around 70 m., Author(s): Ralf Riedinger [sup.1] , Andreas Wallucks [sup.2] , Igor Marinkovic [sup.2] , Clemens Löschnauer [sup.1] , Markus Aspelmeyer [sup.1] , Sungkun Hong [sup.1] , Simon Gröblacher [sup.2] Author Affiliations: [...]

Published

2018

14. Optomechanically induced optical trapping system based on photonic crystal cavities

Author

Monterrosas Romero, Jose Manuel, primary, Alavi, Seyed, additional, Koistinen, Ester, additional, and Hong, Sungkun, additional

Published

2023

15. Supplementary document for Optomechanically induced optical trapping system based on photonic crystal cavities - 6340115.pdf

Author

Hong, Sungkun, Romero, Jose Manuel Monterrosas, Alavi, Seyed, and Koistinen, Ester

Abstract

Supplemental document containing additional analysis and figures that aid the study described in the main manuscript

Published

2023

16. Non-classical correlations between single photons and phonons from a mechanical oscillator

Author

Riedinger, Ralf, Hong, Sungkun, Norte, Richard A., Slater, Joshua A., Shang, Juying, Krause, Alexander G., Anant, Vikas, Aspelmeyer, Markus, and Groblacher, Simon

Subjects

Photons -- Research -- Influence, Quantum theory -- Analysis, Oscillators (Electronics) -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Interfacing a single photon with another quantum system is a key capability in modern quantum information science. It allows quantum states of matter, such as spin states of atoms (1,2), [...]

Published

2016

17. Nanoscale magnetometry with NV centers in diamond

Author

Hong, Sungkun, Grinolds, Michael S., Pham, Linh M., Le Sage, David, Luan, Lan, Walsworth, Ronald L., and Yacoby, Amir

Published

2013

18. Nanophotonic near-field levitated optomechanics

Author

Magrini, Lorenzo, primary, Norte, Richard A., additional, Riedinger, Ralf, additional, Marinković, Igor, additional, Grass, David, additional, Delić, Uroš, additional, Gröblacher, Simon, additional, Hong, Sungkun, additional, and Aspelmeyer, Markus, additional

Published

2019

19. Near-field coupling of a levitated nanoparticle to a photonic crystal cavity

Author

Magrini, Lorenzo, primary, Norte, Richard A., additional, Riedinger, Ralf, additional, Marinković, Igor, additional, Grass, David, additional, Delić, Uroš, additional, Gröblacher, Simon, additional, Hong, Sungkun, additional, and Aspelmeyer, Markus, additional

Published

2018

20. Near-field coupling of a levitated nanoparticle to a photonic crystal cavity

Author

Magrini, Lorenzo (author), Norte, R.A. (author), Riedinger, R.F. (author), Marinkovic, I. (author), Grass, David (author), Delić, Uroš (author), Groeblacher, S. (author), Hong, Sungkun (author), Aspelmeyer, Markus (author), Magrini, Lorenzo (author), Norte, R.A. (author), Riedinger, R.F. (author), Marinkovic, I. (author), Grass, David (author), Delić, Uroš (author), Groeblacher, S. (author), Hong, Sungkun (author), and Aspelmeyer, Markus (author)

Abstract

Quantum control of levitated dielectric particles is an emerging subject in quantum optomechanics. A major challenge is to efficiently measure and manipulate the particle’s motion at the Heisenberg uncertainty limit. Here we present a nanophotonic interface suited to address this problem. By optically trapping a 150 nm silica particle and placing it in the near field of a photonic crystal cavity, we achieve tunable single-photon optomechanical coupling of up to g0∕2π 9kHz, three orders of magnitude larger than previously reported for levitated cavity optomechanical systems. Efficient collection and guiding of light through the nanophotonic structure results in a per-photon displacement sensitivity that is increased by two orders of magnitude compared to conventional far-field detection. The demonstrated performance shows a promising route for room temperature quantum optomechanics., QN/Groeblacher Lab, Dynamics of Micro and Nano Systems

Published

2018

21. Optomechanical Bell Test

Author

Marinkovic, I. (author), Wallucks, A. (author), Riedinger, Ralf (author), Hong, Sungkun (author), Aspelmeyer, Markus (author), Groeblacher, S. (author), Marinkovic, I. (author), Wallucks, A. (author), Riedinger, Ralf (author), Hong, Sungkun (author), Aspelmeyer, Markus (author), and Groeblacher, S. (author)

Abstract

Over the past few decades, experimental tests of Bell-type inequalities have been at the forefront of understanding quantum mechanics and its implications. These strong bounds on specific measurements on a physical system originate from some of the most fundamental concepts of classical physics - in particular that properties of an object are well-defined independent of measurements (realism) and only affected by local interactions (locality). The violation of these bounds unambiguously shows that the measured system does not behave classically, void of any assumption on the validity of quantum theory. It has also found applications in quantum technologies for certifying the suitability of devices for generating quantum randomness, distributing secret keys and for quantum computing. Here we report on the violation of a Bell inequality involving a massive, macroscopic mechanical system. We create light-matter entanglement between the vibrational motion of two silicon optomechanical oscillators, each comprising approx. 1010 atoms, and two optical modes. This state allows us to violate a Bell inequality by more than 4 standard deviations, directly confirming the nonclassical behavior of our optomechanical system under the fair sampling assumption., QN/Groeblacher Lab

Published

2018

22. Optomechanical Bell Test

Author

Marinković, Igor, primary, Wallucks, Andreas, additional, Riedinger, Ralf, additional, Hong, Sungkun, additional, Aspelmeyer, Markus, additional, and Gröblacher, Simon, additional

Published

2018

23. Hanbury Brown and Twiss interferometry of single phonons from an optomechanical resonator

Author

Hong, Sungkun, primary, Riedinger, Ralf, additional, Marinković, Igor, additional, Wallucks, Andreas, additional, Hofer, Sebastian G., additional, Norte, Richard A., additional, Aspelmeyer, Markus, additional, and Gröblacher, Simon, additional

Published

2017

24. Decoherence imaging of spin ensembles using a scanning single-electron spin in diamond

Author

Luan, Lan, primary, Grinolds, Michael S., additional, Hong, Sungkun, additional, Maletinsky, Patrick, additional, Walsworth, Ronald L., additional, and Yacoby, Amir, additional

Published

2015

25. Single-color centers implanted in diamond nanostructures

Author

Massachusetts Institute of Technology. Department of Nuclear Science and Engineering, Hodges, Jonathan S., Hausmann, Birgit J. M., Babinec, Thomas M., Choy, Jennifer T., Hong, Sungkun, Bulu, Irfan, Yacoby, Amir, Lukin, Mikhail D., Massachusetts Institute of Technology. Department of Nuclear Science and Engineering, Hodges, Jonathan S., Hausmann, Birgit J. M., Babinec, Thomas M., Choy, Jennifer T., Hong, Sungkun, Bulu, Irfan, Yacoby, Amir, and Lukin, Mikhail D.

Abstract

The development of material-processing techniques that can be used to generate optical diamond nanostructures containing a single-color center is an important problem in quantum science and technology. In this work, we present the combination of ion implantation and top-down diamond nanofabrication in two scenarios: diamond nanopillars and diamond nanowires. The first device consists of a 'shallow' implant (~20 nm) to generate nitrogen-vacancy (NV) color centers near the top surface of the diamond crystal prior to device fabrication. Individual NV centers are then mechanically isolated by etching a regular array of nanopillars in the diamond surface. Photon anti-bunching measurements indicate that a high yield (>10%) of the devices contain a single NV center. The second device demonstrates 'deep' (~1 μm) implantation of individual NV centers into diamond nanowires as a post-processing step. The high single-photon flux of the nanowire geometry, combined with the low background fluorescence of the ultrapure diamond, allowed us to observe sustained photon anti-bunching even at high pump powers., United States. Dept. of Defense (National Defense Science and Engineering Graduate Fellowship), National Science Foundation (U.S.) (NSF Graduate Research Fellowship), Alfred P. Sloan Foundation

Published

2012

26. Coherent, Mechanical Control of a Single Electronic Spin

Author

Hong, Sungkun, primary, Grinolds, Michael S., additional, Maletinsky, Patrick, additional, Walsworth, Ronald L., additional, Lukin, Mikhail D., additional, and Yacoby, Amir, additional

Published

2012

27. Single-color centers implanted in diamond nanostructures

Author

Hausmann, Birgit J M, primary, Babinec, Thomas M, additional, Choy, Jennifer T, additional, Hodges, Jonathan S, additional, Hong, Sungkun, additional, Bulu, Irfan, additional, Yacoby, Amir, additional, Lukin, Mikhail D, additional, and Lončar, Marko, additional

Published

2011

28. Coherent, Mechanical Controlof a Single Electronic Spin.

Author

Hong, Sungkun, Grinolds, Michael S., Maletinsky, Patrick, Walsworth, Ronald L., Lukin, Mikhail D., and Yacoby, Amir

Published

2012

29. Nanoscale Magnetic Imaging with a Single Nitrogen-Vacancy Center in Diamond

Author

Hong, Sungkun and Yacoby, Amir

Subjects

Physics, Condensed matter physics, Quantum physics, Electron spin, Magnetic resonance, Magnetometry, Nitrogen-vacancy center

Abstract

Magnetic imaging has been playing central roles not only in fundamental sciences but also in engineering and industry. Their numerous applications can be found in various areas, ranging from chemical analysis and biomedical imaging to magnetic data storage technology. An outstanding problem is to develope new magnetic imaging techniques with improved spatial resolutions down to nanoscale, while maintaining their magnetic sensitivities. For instance, if detecting individual electron or nuclear spins with nanomter spatial resolution is possible, it would allow for direct imaging of chemical structures of complex molecules, which then could bring termendous impacts on biological sciences. While realization of such nanoscale magnetic imaging still remains challenging, nitrogen-vacancy (NV) defects in diamond have recently considered as promising magnetic field sensors, as their electron spins show exceptionally long coherence even at room temperature. This thesis presents experimental progress in realizing a nanoscale magnetic imaging apparatus with a single nitrogen-vacancy (NV) color center diamond. We first fabricated diamond nanopillar devices hosting single NV centers at their ends, and incorporated them to a custom-built atomic force microscope (AFM). Our devices showed unprecedented combination of magnetic field sensitivity and spatial resolution for scanning NV systems. We then used these devices to magnetically image a single isolated electronic spin with nanometer resolution, for the first time under ambient condition. We also extended our study to improve and generalize the application of the scanning NV magnetometer we developed. We first introduced magnetic field gradients from a strongly magnetized tip, and demonstrated that the spatial resolution can be further improved by spectrally distinguishing identical spins at different locations. In addition, we developed a method to synchronize the periodic motion of an AFM tip and pulsed microwave sequences controlling an NV spin. This scheme enabled employment of 'AC magnetic field sensing scheme' in imaging samples with static and spatially varying magnetizations., Engineering and Applied Sciences

Published

2013

30. Nanoscale magnetic imaging of a single electron spin under ambient conditions

Author

Grinolds, Michael Sean, Hong, Sungkun, Maletinsky, Patrick, Luan, Lan, Lukin, Mikhail D., Walsworth, Ronald Lee, and Yacoby, Amir

Abstract

The detection of ensembles of spins under ambient conditions has revolutionized the biological, chemical and physical sciences through magnetic resonance imaging1 and nuclear magnetic resonance2, 3. Pushing sensing capabilities to the individual-spin level would enable unprecedented applications such as single-molecule structural imaging; however, the weak magnetic fields from single spins are undetectable by conventional far-field resonance techniques4. In recent years, there has been a considerable effort to develop nanoscale scanning magnetometers5, 6, 7, 8, which are able to measure fewer spins by bringing the sensor in close proximity to its target. The most sensitive of these magnetometers generally require low temperatures for operation, but the ability to measure under ambient conditions (standard temperature and pressure) is critical for many imaging applications, particularly in biological systems. Here we demonstrate detection and nanoscale imaging of the magnetic field from an initialized single electron spin under ambient conditions using a scanning nitrogen-vacancy magnetometer. Real-space, quantitative magnetic-field images are obtained by deterministically scanning our nitrogen-vacancy magnetometer 50 nm above a target electron spin, while measuring the local magnetic field using dynamically decoupled magnetometry protocols. We discuss how this single-spin detection enables the study of a variety of room-temperature phenomena in condensed-matter physics with an unprecedented combination of spatial resolution and spin sensitivity., Engineering and Applied Sciences, Physics

Published

2013

31. A Robust Scanning Diamond Sensor for Nanoscale Imaging with Single Nitrogen-Vacancy Centres

Author

Maletinsky, Patrick, Hong, Sungkun, Grinolds, Michael Sean, Hausmann, Birgit Judith Maria, Lukin, Mikhail D., Walsworth, Ronald L., Loncar, Marko, and Yacoby, Amir

Subjects

field optical microscopy, magnetic sensors, magnetic-resonance, coupled electron, light-source spin, resolution, photon, fabrication

Abstract

The nitrogen-vacancy defect centre in diamond has potential applications in nanoscale electric and magnetic-field sensing, single-photon microscopy, quantum information processing and bioimaging. These applications rely on the ability to position a single nitrogen-vacancy centre within a few nanometres of a sample, and then scan it across the sample surface, while preserving the centre’s spin coherence and readout fidelity. However, existing scanning techniques, which use a single diamond nanocrystal grafted onto the tip of a scanning probe microscope, suffer from short spin coherence times due to poor crystal quality, and from inefficient far-field collection of the fluorescence from the nitrogen-vacancy centre. Here, we demonstrate a robust method for scanning a single nitrogen-vacancy centre within tens of nanometres from a sample surface that addresses both of these concerns. This is achieved by positioning a single nitrogen-vacancy centre at the end of a high-purity diamond nanopillar, which we use as the tip of an atomic force microscope. Our approach ensures long nitrogen-vacancy spin coherence times \(\textrm{(∼75 }\mu \textrm{s)}\), enhanced nitrogen-vacancy collection efficiencies due to waveguiding, and mechanical robustness of the device (several weeks of scanning time). We are able to image magnetic domains with widths of 25 nm, and demonstrate a magnetic field sensitivity of \(56\textrm{ nT Hz}^{–1/2}\) at a frequency of 33 kHz, which is unprecedented for scanning nitrogen-vacancy centres., Engineering and Applied Sciences, Physics, Other Research Unit

Published

2012

32. 3646167.pdf

Author

Magrini, Lorenzo, Norte, Richard, Riedinger, Ralf, Marinković, Igor, Grass, David, Delić, Uroš, Gröblacher, Simon, Hong, Sungkun, and Aspelmeyer, Markus

Subjects

3. Good health

Abstract

Supplemental Document that contains additional information about the detailed experimental procedures and relevant theoretical background of the works presented in the main manuscript

33. 3646167.pdf

Author

Magrini, Lorenzo, Norte, Richard, Riedinger, Ralf, Marinković, Igor, Grass, David, Delić, Uroš, Gröblacher, Simon, Hong, Sungkun, and Aspelmeyer, Markus

Subjects

3. Good health

Abstract

Supplemental Document that contains additional information about the detailed experimental procedures and relevant theoretical background of the works presented in the main manuscript