Your search keyword '"Dobrovitski, V.V. (author)"' showing total 32 results

1. Efficient and robust estimation of many-qubit Hamiltonians

Author

Stilck França, Daniel (author), Markovich, L. (author), Dobrovitski, V.V. (author), Werner, Albert H. (author), Borregaard, J. (author), Stilck França, Daniel (author), Markovich, L. (author), Dobrovitski, V.V. (author), Werner, Albert H. (author), and Borregaard, J. (author)

Abstract

Characterizing the interactions and dynamics of quantum mechanical systems is an essential task in developing quantum technologies. We propose an efficient protocol based on the estimation of the time-derivatives of few qubit observables using polynomial interpolation for characterizing the underlying Hamiltonian dynamics and Markovian noise of a multi-qubit device. For finite range dynamics, our protocol exponentially relaxes the necessary time-resolution of the measurements and quadratically reduces the overall sample complexity compared to previous approaches. Furthermore, we show that our protocol can characterize the dynamics of systems with algebraically decaying interactions. The implementation of the protocol requires only the preparation of product states and single-qubit measurements. Furthermore, we improve a shadow tomography method for quantum channels that is of independent interest and discuss the robustness of the protocol to various errors. This protocol can be used to parallelize the learning of the Hamiltonian, rendering it applicable for the characterization of both current and future quantum devices., QID/Borregaard Group, QID/Dobrovitski Group, QN/Borregaard groep

Published

2024

2. Nonlinear Response and Crosstalk of Electrically Driven Silicon Spin Qubits

Author

Undseth, B.W. (author), Xue, X. (author), Mehmandoost, M. (author), Rimbach-Russ, Maximilian (author), Eendebak, P.T. (author), Samkharadze, Nodar (author), Sammak, A. (author), Dobrovitski, V.V. (author), Scappucci, G. (author), Vandersypen, L.M.K. (author), Undseth, B.W. (author), Xue, X. (author), Mehmandoost, M. (author), Rimbach-Russ, Maximilian (author), Eendebak, P.T. (author), Samkharadze, Nodar (author), Sammak, A. (author), Dobrovitski, V.V. (author), Scappucci, G. (author), and Vandersypen, L.M.K. (author)

Abstract

Micromagnet-based electric dipole spin resonance offers an attractive path for the near-term scaling of dense arrays of silicon spin qubits in gate-defined quantum dots while maintaining long coherence times and high control fidelities. However, accurately controlling dense arrays of qubits using a multiplexed drive will require an understanding of the cross-talk mechanisms that may reduce operational fidelity. We identify an unexpected cross-talk mechanism whereby the Rabi frequency of a driven qubit is drastically changed when the drive of an adjacent qubit is turned on. These observations raise important considerations for scaling single-qubit control., QCD/Vandersypen Lab, QID/Dobrovitski Group, BUS/TNO STAFF, QCD/Scappucci Lab, QN/Vandersypen Lab

Published

2023

3. Coherent Control of a Nuclear Spin via Interactions with a Rare-Earth Ion in the Solid State

Author

Uysal, Mehmet T. (author), Raha, Mouktik (author), Chen, Songtao (author), Phenicie, Christopher M. (author), Ourari, Salim (author), Wang, Mengen (author), Van De Walle, Chris G. (author), Dobrovitski, V.V. (author), Thompson, Jeff D. (author), Uysal, Mehmet T. (author), Raha, Mouktik (author), Chen, Songtao (author), Phenicie, Christopher M. (author), Ourari, Salim (author), Wang, Mengen (author), Van De Walle, Chris G. (author), Dobrovitski, V.V. (author), and Thompson, Jeff D. (author)

Abstract

Individually addressed Er3+ ions in solid-state hosts are promising resources for quantum repeaters, because of their direct emission in the telecom band and their compatibility with silicon photonic devices. While the Er3+ electron spin provides a spin-photon interface, ancilla nuclear spins could enable multiqubit registers with longer storage times. In this work, we demonstrate coherent coupling between the electron spin of a single Er3+ ion and a single I=1/2 nuclear spin in the solid-state host crystal, which is a fortuitously located proton (1H). We control the nuclear spin using dynamical-decoupling sequences applied to the electron spin, implementing one- and two-qubit gate operations. Crucially, the nuclear spin coherence time exceeds the electron coherence time by several orders of magnitude, because of its smaller magnetic moment. These results provide a path toward combining long-lived nuclear spin quantum registers with telecom-wavelength emitters for long-distance quantum repeaters., QID/Dobrovitski Group

Published

2023

4. Probing Spin Dynamics on Diamond Surfaces Using a Single Quantum Sensor

Author

Dwyer, Bo L. (author), Rodgers, Lila V.H. (author), Urbach, Elana K. (author), Bluvstein, Dolev (author), Sangtawesin, Sorawis (author), Zhou, Hengyun (author), Nassab, Yahia (author), Fitzpatrick, Mattias (author), Dobrovitski, V.V. (author), Dwyer, Bo L. (author), Rodgers, Lila V.H. (author), Urbach, Elana K. (author), Bluvstein, Dolev (author), Sangtawesin, Sorawis (author), Zhou, Hengyun (author), Nassab, Yahia (author), Fitzpatrick, Mattias (author), and Dobrovitski, V.V. (author)

Abstract

Understanding the dynamics of a quantum bit's environment is essential for the realization of practical systems for quantum information processing and metrology. We use single nitrogen-vacancy (NV) centers in diamond to study the dynamics of a disordered spin ensemble at the diamond surface. Specifically, we reduce the density of "dark"surface spins to interrogate their contribution to the decoherence of shallow NV center spin qubits. When the average surface spin spacing exceeds the NV center depth, we find that the surface spin contribution to the NV center free induction decay can be described by a stretched exponential with variable power n. We show that these observations are consistent with a model in which the spatial positions of the surface spins are fixed for each measurement, but some of them reconfigure between measurements. In particular, we observe a depth-dependent critical time associated with a dynamical transition from Gaussian (n=2) decay to n=2/3, and show that this transition arises from the competition between the small decay contributions of many distant spins and strong coupling to a few proximal spins at the surface. These observations demonstrate the potential of a local sensor for understanding complex systems and elucidate pathways for improving and controlling spin qubits at the surface., QID/Dobrovitski Group

Published

2022

5. Long-lived coherence in driven many-spin systems: From two to infinite spatial dimensions

Author

Hahn, W. (author), Dobrovitski, V.V. (author), Hahn, W. (author), and Dobrovitski, V.V. (author)

Abstract

Long-lived coherences, emerging under periodic pulse driving in the disordered ensembles of strongly interacting spins, offer immense advantages for future quantum technologies, but the physical origin and the key properties of this phenomenon remain poorly understood. We theoretically investigate this effect in ensembles of different dimensionality, and predict existence of the long-lived coherences in all such systems, from two-dimensional to infinite-dimensional (where every spin is coupled to all others with similar strength), which are of particular importance for quantum sensing and quantum information processing. We explore the transition from two to infinite dimensions, and show that the long-time coherence dynamics in all dimensionalities is qualitatively similar, although the short-time behavior is drastically different, exhibiting dimensionality-dependent singularity. Our study establishes the common physical origin of the long-lived coherences in different dimensionalities, and suggests that this effect is a generic feature of the strongly coupled spin systems with positional disorder. Our results lay out foundation for utilizing the long-lived coherences in a range of application, from quantum sensing with two-dimensional spin ensembles, to quantum information processing with the infinitely-dimensional spin systems in the cavity-QED settings., QID/Dobrovitski Group, QuTech

Published

2021

6. Long-lived coherence in driven many-spin systems: From two to infinite spatial dimensions

Author

Hahn, W. (author), Dobrovitski, V.V. (author), Hahn, W. (author), and Dobrovitski, V.V. (author)

Abstract

Long-lived coherences, emerging under periodic pulse driving in the disordered ensembles of strongly interacting spins, offer immense advantages for future quantum technologies, but the physical origin and the key properties of this phenomenon remain poorly understood. We theoretically investigate this effect in ensembles of different dimensionality, and predict existence of the long-lived coherences in all such systems, from two-dimensional to infinite-dimensional (where every spin is coupled to all others with similar strength), which are of particular importance for quantum sensing and quantum information processing. We explore the transition from two to infinite dimensions, and show that the long-time coherence dynamics in all dimensionalities is qualitatively similar, although the short-time behavior is drastically different, exhibiting dimensionality-dependent singularity. Our study establishes the common physical origin of the long-lived coherences in different dimensionalities, and suggests that this effect is a generic feature of the strongly coupled spin systems with positional disorder. Our results lay out foundation for utilizing the long-lived coherences in a range of application, from quantum sensing with two-dimensional spin ensembles, to quantum information processing with the infinitely-dimensional spin systems in the cavity-QED settings., QID/Dobrovitski Group

Published

2021

7. Orbital and Spin Dynamics of Single Neutrally-Charged Nitrogen-Vacancy Centers in Diamond

Author

Baier, S. (author), Bradley, C.E. (author), Middelburg, T. (author), Dobrovitski, V.V. (author), Taminiau, T.H. (author), Hanson, R. (author), Baier, S. (author), Bradley, C.E. (author), Middelburg, T. (author), Dobrovitski, V.V. (author), Taminiau, T.H. (author), and Hanson, R. (author)

Abstract

The neutral charge state plays an important role in quantum information and sensing applications basedon nitrogen-vacancy centers. However, the orbital and spin dynamics remain unexplored. Here, we useresonant excitation of single centers to directly reveal the fine structure, enabling selective addressing ofspin-orbit states. Through pump-probe experiments, we find the orbital relaxation time (430 ns at 4.7 K)and measure its temperature dependence up to 11.8 K. Finally, we reveal the spin relaxation time (1.5 s) andrealize projective high-fidelity single-shot readout of the spin state (≥98%)., QID/Hanson Lab, QuTech, QID/Taminiau Lab, BUS/Spider, QID/Dobrovitski Group, QN/Hanson Lab

Published

2020

8. Orbital and Spin Dynamics of Single Neutrally-Charged Nitrogen-Vacancy Centers in Diamond

Author

Baier, S. (author), Bradley, C.E. (author), Middelburg, T. (author), Dobrovitski, V.V. (author), Taminiau, T.H. (author), Hanson, R. (author), Baier, S. (author), Bradley, C.E. (author), Middelburg, T. (author), Dobrovitski, V.V. (author), Taminiau, T.H. (author), and Hanson, R. (author)

Abstract

The neutral charge state plays an important role in quantum information and sensing applications basedon nitrogen-vacancy centers. However, the orbital and spin dynamics remain unexplored. Here, we useresonant excitation of single centers to directly reveal the fine structure, enabling selective addressing ofspin-orbit states. Through pump-probe experiments, we find the orbital relaxation time (430 ns at 4.7 K)and measure its temperature dependence up to 11.8 K. Finally, we reveal the spin relaxation time (1.5 s) andrealize projective high-fidelity single-shot readout of the spin state (≥98%)., QID/Hanson Lab, QID/Taminiau Lab, BUS/Spider, QID/Dobrovitski Group, QN/Hanson Lab

Published

2020

9. Spin Lifetime and Charge Noise in Hot Silicon Quantum Dot Qubits

Author

Petit, L. (author), Boter, J.M. (author), Eenink, H.G.J. (author), Droulers, G. (author), Tagliaferri, M.L.V. (author), Li, R. (author), Franke, D.P. (author), Singh, K. J. (author), Clarke, J. S. (author), Schouten, R.N. (author), Dobrovitski, V.V. (author), Vandersypen, L.M.K. (author), Veldhorst, M. (author), Petit, L. (author), Boter, J.M. (author), Eenink, H.G.J. (author), Droulers, G. (author), Tagliaferri, M.L.V. (author), Li, R. (author), Franke, D.P. (author), Singh, K. J. (author), Clarke, J. S. (author), Schouten, R.N. (author), Dobrovitski, V.V. (author), Vandersypen, L.M.K. (author), and Veldhorst, M. (author)

Abstract

We investigate the magnetic field and temperature dependence of the single-electron spin lifetime in silicon quantum dots and find a lifetime of 2.8 ms at a temperature of 1.1 K. We develop a model based on spin-valley mixing and find that Johnson noise and two-phonon processes limit relaxation at low and high temperature, respectively. We also investigate the effect of temperature on charge noise and find a linear dependence up to 4 K. These results contribute to the understanding of relaxation in silicon quantum dots and are promising for qubit operation at elevated temperatures., QCD/Veldhorst Lab, QCD/Vandersypen Lab, General, QID/Dobrovitski Group, QN/Vandersypen Lab

Published

2018

10. Spin Lifetime and Charge Noise in Hot Silicon Quantum Dot Qubits

Author

Petit, L. (author), Boter, J.M. (author), Eenink, H.G.J. (author), Droulers, G. (author), Tagliaferri, M.L.V. (author), Li, R. (author), Franke, D.P. (author), Singh, K. J. (author), Clarke, J. S. (author), Schouten, R.N. (author), Dobrovitski, V.V. (author), Vandersypen, L.M.K. (author), Veldhorst, M. (author), Petit, L. (author), Boter, J.M. (author), Eenink, H.G.J. (author), Droulers, G. (author), Tagliaferri, M.L.V. (author), Li, R. (author), Franke, D.P. (author), Singh, K. J. (author), Clarke, J. S. (author), Schouten, R.N. (author), Dobrovitski, V.V. (author), Vandersypen, L.M.K. (author), and Veldhorst, M. (author)

Abstract

We investigate the magnetic field and temperature dependence of the single-electron spin lifetime in silicon quantum dots and find a lifetime of 2.8 ms at a temperature of 1.1 K. We develop a model based on spin-valley mixing and find that Johnson noise and two-phonon processes limit relaxation at low and high temperature, respectively. We also investigate the effect of temperature on charge noise and find a linear dependence up to 4 K. These results contribute to the understanding of relaxation in silicon quantum dots and are promising for qubit operation at elevated temperatures., QCD/Veldhorst Lab, QCD/Vandersypen Lab, ALG/General, QID/Dobrovitski Group, QN/Vandersypen Lab

Published

2018

11. Polaron spin echo envelope modulations in an organic semiconducting polymer

Author

Mkhitaryan, V. V. (author), Dobrovitski, V.V. (author), Mkhitaryan, V. V. (author), and Dobrovitski, V.V. (author)

Abstract

We present a theoretical analysis of the electron spin echo envelope modulation (ESEEM) spectra of polarons in semiconducting π-conjugated polymers. We show that the contact hyperfine coupling and the dipolar interaction between the polaron and the proton spins give rise to different features in the ESEEM spectra. Our theory enables direct selective probe of different groups of nuclear spins, which affect the polaron spin dynamics. Namely, we demonstrate how the signal from the distant protons (coupled to the polaron spin via dipolar interactions) can be distinguished from the signal coming from the protons residing on the polaron site (coupled to the polaron spin via contact hyperfine interaction). We propose a method for directly probing the contact hyperfine interaction, that would enable detailed study of the polaron orbital state and its immediate environment. We also analyze the decay of the spin echo modulation, and its connection to the polaron transport., QID/Dobrovitski Group

Published

2017

12. Quantum dynamics of nuclear spins and spin relaxation in organic semiconductors

Author

Mkhitaryan, V. V. (author), Dobrovitski, V.V. (author), Mkhitaryan, V. V. (author), and Dobrovitski, V.V. (author)

Abstract

We investigate the role of the nuclear-spin quantum dynamics in hyperfine-induced spin relaxation of hopping carriers in organic semiconductors. The fast-hopping regime, when the carrier spin does not rotate much between subsequent hops, is typical for organic semiconductors possessing long spin coherence times. We consider this regime and focus on a carrier random-walk diffusion in one dimension, where the effect of the nuclear-spin dynamics is expected to be the strongest. Exact numerical simulations of spin systems with up to 25 nuclear spins are performed using the Suzuki-Trotter decomposition of the evolution operator. Larger nuclear-spin systems are modeled utilizing the spin-coherent state P-representation approach developed earlier. We find that the nuclear-spin dynamics strongly influences the carrier spin relaxation at long times. If the random walk is restricted to a small area, it leads to the quenching of carrier spin polarization at a nonzero value at long times. If the random walk is unrestricted, the carrier spin polarization acquires a long-time tail, decaying as 1/t. Based on the numerical results, we devise a simple formula describing the effect quantitatively., QID/Dobrovitski Group

Published

2017

13. Absorption spectrum of a two-level system subjected to a periodic pulse sequence

Author

Fotso, H. F. (author), Dobrovitski, V.V. (author), Fotso, H. F. (author), and Dobrovitski, V.V. (author)

Abstract

We investigate how the quantum control of a two-level system (TLS) coupled to photons can modify and tune the TLS's photon absorption spectrum. Tuning and controlling the emission and the absorption are of great interest, e.g., for the development of efficient interfaces between stationary and flying qubits in modern architectures for quantum computation and quantum communication. We consider periodic pulse control, where the TLS is subjected to a periodic sequence of the near-resonant Rabi driving pulses, each pulse implementing a 180 rotation. For small interpulse delays, the absorption spectrum features a pronounced peak of stimulated emission at the pulse frequency, similar satellite peaks with smaller spectral weights, and the net absorption peaks on the sides. As long as the detuning between the carrier frequency of the driving and the TLS transition frequency remains moderate, this spectral shape shows little change. Therefore, the pulse control allows shifting the absorption peak to a desired position and locks the overall absorption spectrum to the carrier frequency of the driving pulses. A detailed description of the spectrum and its evolution as a function time, the interpulse spacing, and the detuning is presented., QID/Dobrovitski Group

Published

2017

14. Quantum dynamics of nuclear spins and spin relaxation in organic semiconductors

Author

Mkhitaryan, V. V. (author), Dobrovitski, V.V. (author), Mkhitaryan, V. V. (author), and Dobrovitski, V.V. (author)

Abstract

We investigate the role of the nuclear-spin quantum dynamics in hyperfine-induced spin relaxation of hopping carriers in organic semiconductors. The fast-hopping regime, when the carrier spin does not rotate much between subsequent hops, is typical for organic semiconductors possessing long spin coherence times. We consider this regime and focus on a carrier random-walk diffusion in one dimension, where the effect of the nuclear-spin dynamics is expected to be the strongest. Exact numerical simulations of spin systems with up to 25 nuclear spins are performed using the Suzuki-Trotter decomposition of the evolution operator. Larger nuclear-spin systems are modeled utilizing the spin-coherent state P-representation approach developed earlier. We find that the nuclear-spin dynamics strongly influences the carrier spin relaxation at long times. If the random walk is restricted to a small area, it leads to the quenching of carrier spin polarization at a nonzero value at long times. If the random walk is unrestricted, the carrier spin polarization acquires a long-time tail, decaying as 1/t. Based on the numerical results, we devise a simple formula describing the effect quantitatively., QID/Dobrovitski Group

Published

2017

15. Absorption spectrum of a two-level system subjected to a periodic pulse sequence

Author

Fotso, H. F. (author), Dobrovitski, V.V. (author), Fotso, H. F. (author), and Dobrovitski, V.V. (author)

Abstract

We investigate how the quantum control of a two-level system (TLS) coupled to photons can modify and tune the TLS's photon absorption spectrum. Tuning and controlling the emission and the absorption are of great interest, e.g., for the development of efficient interfaces between stationary and flying qubits in modern architectures for quantum computation and quantum communication. We consider periodic pulse control, where the TLS is subjected to a periodic sequence of the near-resonant Rabi driving pulses, each pulse implementing a 180 rotation. For small interpulse delays, the absorption spectrum features a pronounced peak of stimulated emission at the pulse frequency, similar satellite peaks with smaller spectral weights, and the net absorption peaks on the sides. As long as the detuning between the carrier frequency of the driving and the TLS transition frequency remains moderate, this spectral shape shows little change. Therefore, the pulse control allows shifting the absorption peak to a desired position and locks the overall absorption spectrum to the carrier frequency of the driving pulses. A detailed description of the spectrum and its evolution as a function time, the interpulse spacing, and the detuning is presented., QID/Dobrovitski Group

Published

2017

16. Gate fidelity and coherence of an electron spin in an Si/SiGe quantum dot with micromagnet

Author

Kawakami, E. (author), Jullien, T.M.J. (author), Scarlino, P. (author), Ward, Daniel R. (author), Savage, Donald E. (author), Lagally, Max G. (author), Dobrovitski, V.V. (author), Friesen, Mark (author), Coppersmith, Susan N. (author), Eriksson, M.A. (author), Vandersypen, L.M.K. (author), Kawakami, E. (author), Jullien, T.M.J. (author), Scarlino, P. (author), Ward, Daniel R. (author), Savage, Donald E. (author), Lagally, Max G. (author), Dobrovitski, V.V. (author), Friesen, Mark (author), Coppersmith, Susan N. (author), Eriksson, M.A. (author), and Vandersypen, L.M.K. (author)

Abstract

The gate fidelity and the coherence time of a quantum bit (qubit) are important benchmarks for quantum computation. We construct a qubit using a single electron spin in an Si/SiGe quantum dot and control it electrically via an artificial spin-orbit field from a micromagnet. We measure an average single-qubit gate fidelity of ∼99% using randomized benchmarking, which is consistent with dephasing from the slowly evolving nuclear spins in the substrate. The coherence time measured using dynamical decoupling extends up to ∼400 μs for 128 decoupling pulses, with no sign of saturation. We find evidence that the coherence time is limited by noise in the 10-kHz to 1-MHz range, possibly because charge noise affects the spin via the micromagnet gradient. This work shows that an electron spin in an Si/SiGe quantum dot is a good candidate for quantum information processing as well as for a quantum memory, even without isotopic purification., Vandersypen Lab, QN/Quantum Transport, QuTech, QN/Vandersypen Lab

Published

2016

17. Manipulating a spin qubit by the backaction of sequential partial adaptive measurements

Author

Bonato, C. (author), Blok, M.S. (author), Markham, M.L. (author), Twitchen, D.J. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Bonato, C. (author), Blok, M.S. (author), Markham, M.L. (author), Twitchen, D.J. (author), Dobrovitski, V.V. (author), and Hanson, R. (author)

Abstract

We report the control-free manipulation of a nuclear spin qubit in diamond, using only the backaction of sequential partial measurements with real-time feedback., QN/Quantum Nanoscience, Applied Sciences

Published

2014

18. Manipulating a spin qubit by the backaction of sequential partial adaptive measurements

Author

Bonato, C. (author), Blok, M.S. (author), Markham, M.L. (author), Twitchen, D.J. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Bonato, C. (author), Blok, M.S. (author), Markham, M.L. (author), Twitchen, D.J. (author), Dobrovitski, V.V. (author), and Hanson, R. (author)

Abstract

We report the control-free manipulation of a nuclear spin qubit in diamond, using only the backaction of sequential partial measurements with real-time feedback., QN/Quantum Nanoscience, Applied Sciences

Published

2014

19. Quantum state steering by real-time adaptive measurements on a single nuclear spin

Author

Blok, M.S. (author), Bonato, C. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Blok, M.S. (author), Bonato, C. (author), Dobrovitski, V.V. (author), and Hanson, R. (author)

Abstract

We present our most recent results on partial measurements of a nuclear spin in which the inevitable measurement back-action is controllably reduced. The post-selected measurement results can give rise to weak values. By using a real-time adaptive scheme the quantum state can be tuned using only measurements., QN/Quantum Nanoscience, Applied Sciences

Published

2013

20. Quantum state steering by real-time adaptive measurements on a single nuclear spin

Author

Blok, M.S. (author), Bonato, C. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Blok, M.S. (author), Bonato, C. (author), Dobrovitski, V.V. (author), and Hanson, R. (author)

Abstract

We present our most recent results on partial measurements of a nuclear spin in which the inevitable measurement back-action is controllably reduced. The post-selected measurement results can give rise to weak values. By using a real-time adaptive scheme the quantum state can be tuned using only measurements., QN/Quantum Nanoscience, Applied Sciences

Published

2013

21. Comparison of dynamical decoupling protocols for a nitrogen-vacancy center in diamond

Author

Wang, Z.H. (author), De Lange, G. (author), Riste, D. (author), Hanson, R. (author), Dobrovitski, V.V. (author), Wang, Z.H. (author), De Lange, G. (author), Riste, D. (author), Hanson, R. (author), and Dobrovitski, V.V. (author)

Abstract

We perform a detailed theoretical-experimental study of the dynamical decoupling (DD) of the nitrogen-vacancy (NV) center in diamond. We investigate the DD sequences applied to suppress the dephasing of the electron spin of the NV center induced by the coupling to a spin bath composed of the substitutional nitrogen atoms. The decoupling efficiency of various DD schemes is studied, including both periodic and aperiodic pulse sequences. For ideal control pulses, we find that the DD protocols with the Carr-Purcell-Meiboom-Gill (CPMG) timing of the pulses provides best performance. We show that, as the number of control pulses increases, the decoupling fidelity scaling differs qualitatively from the predictions of the Magnus expansion, and explain the origin of this difference. In particular, more advanced symmetrized or concatenated protocols do not improve the DD performance. Next, we investigate the impact of the systematic instrumental pulse errors in different periodic and aperiodic pulse sequences. The DD protocols with the single-axis control do not preserve all spin components in the presence of the pulse errors, and the two-axis control is needed. We demonstrate that the two-axis control sequence with the CPMG timing is very robust with respect to the pulse errors. The impact of the pulse errors can be diminished further by symmetrizing this protocol. For all protocols studied here, we present a detailed account of the pulse error parameters which make the strongest impact on the DD performance. In conclusion, we give specific recommendations about choosing the decoupling protocol for the system under investigation., QN/Quantum Nanoscience, Applied Sciences

Published

2012

22. Comparison of dynamical decoupling protocols for a nitrogen-vacancy center in diamond

Author

Wang, Z.H. (author), De Lange, G. (author), Riste, D. (author), Hanson, R. (author), Dobrovitski, V.V. (author), Wang, Z.H. (author), De Lange, G. (author), Riste, D. (author), Hanson, R. (author), and Dobrovitski, V.V. (author)

Abstract

We perform a detailed theoretical-experimental study of the dynamical decoupling (DD) of the nitrogen-vacancy (NV) center in diamond. We investigate the DD sequences applied to suppress the dephasing of the electron spin of the NV center induced by the coupling to a spin bath composed of the substitutional nitrogen atoms. The decoupling efficiency of various DD schemes is studied, including both periodic and aperiodic pulse sequences. For ideal control pulses, we find that the DD protocols with the Carr-Purcell-Meiboom-Gill (CPMG) timing of the pulses provides best performance. We show that, as the number of control pulses increases, the decoupling fidelity scaling differs qualitatively from the predictions of the Magnus expansion, and explain the origin of this difference. In particular, more advanced symmetrized or concatenated protocols do not improve the DD performance. Next, we investigate the impact of the systematic instrumental pulse errors in different periodic and aperiodic pulse sequences. The DD protocols with the single-axis control do not preserve all spin components in the presence of the pulse errors, and the two-axis control is needed. We demonstrate that the two-axis control sequence with the CPMG timing is very robust with respect to the pulse errors. The impact of the pulse errors can be diminished further by symmetrizing this protocol. For all protocols studied here, we present a detailed account of the pulse error parameters which make the strongest impact on the DD performance. In conclusion, we give specific recommendations about choosing the decoupling protocol for the system under investigation., QN/Quantum Nanoscience, Applied Sciences

Published

2012

23. Detection and Control of Individual Nuclear Spins Using a Weakly Coupled Electron Spin

Author

Taminiau, T.H. (author), Wagenaar, J.J.T. (author), Van der Sar, T. (author), Jelezko, F. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Taminiau, T.H. (author), Wagenaar, J.J.T. (author), Van der Sar, T. (author), Jelezko, F. (author), Dobrovitski, V.V. (author), and Hanson, R. (author)

Abstract

We experimentally isolate, characterize, and coherently control up to six individual nuclear spins that are weakly coupled to an electron spin in diamond. Our method employs multipulse sequences on the electron spin that resonantly amplify the interaction with a selected nuclear spin and at the same time dynamically suppress decoherence caused by the rest of the spin bath. We are able to address nuclear spins with interaction strengths that are an order of magnitude smaller than the electron spin dephasing rate. Our results provide a route towards tomography with single-nuclear-spin sensitivity and greatly extend the number of available quantum bits for quantum information processing in diamond., Quantum Nanoscience, Applied Sciences

Published

2012

24. Single-Spin Magnetometry with Multipulse Sensing Sequences

Author

De Lange, G. (author), Ristè, D. (author), Dobrovitski, V.V. (author), Hanson, R. (author), De Lange, G. (author), Ristè, D. (author), Dobrovitski, V.V. (author), and Hanson, R. (author)

Abstract

We experimentally demonstrate single-spin magnetometry with multipulse sensing sequences. The use of multipulse sequences can greatly increase the sensing time per measurement shot, resulting in enhanced ac magnetic field sensitivity. We theoretically derive and experimentally verify the optimal number of sensing cycles, for which the effects of decoherence and increased sensing time are balanced. We perform these experiments for oscillating magnetic fields with fixed phase as well as for fields with random phase. Finally, by varying the phase and frequency of the ac magnetic field, we measure the full frequency-filtering characteristics of different multipulse schemes and discuss their use in magnetometry applications., QN/Quantum Nanoscience, Applied Sciences

Published

2011

25. Single-Spin Magnetometry with Multipulse Sensing Sequences

Author

De Lange, G. (author), Ristè, D. (author), Dobrovitski, V.V. (author), Hanson, R. (author), De Lange, G. (author), Ristè, D. (author), Dobrovitski, V.V. (author), and Hanson, R. (author)

Abstract

We experimentally demonstrate single-spin magnetometry with multipulse sensing sequences. The use of multipulse sequences can greatly increase the sensing time per measurement shot, resulting in enhanced ac magnetic field sensitivity. We theoretically derive and experimentally verify the optimal number of sensing cycles, for which the effects of decoherence and increased sensing time are balanced. We perform these experiments for oscillating magnetic fields with fixed phase as well as for fields with random phase. Finally, by varying the phase and frequency of the ac magnetic field, we measure the full frequency-filtering characteristics of different multipulse schemes and discuss their use in magnetometry applications., QN/Quantum Nanoscience, Applied Sciences

Published

2011

26. Bootstrap Tomography of the Pulses for Quantum Control

Author

Dobrovitski, V.V. (author), De Lange, G. (author), Ristè, D. (author), Hanson, R. (author), Dobrovitski, V.V. (author), De Lange, G. (author), Ristè, D. (author), and Hanson, R. (author)

Abstract

Long-time dynamical decoupling and quantum control of qubits require high-precision control pulses. Full characterization (quantum tomography) of imperfect pulses presents a bootstrap problem: tomography requires initial states of a qubit which cannot be prepared without perfect pulses. We present a protocol for pulse error analysis, specifically tailored for a wide range of the single solid-state electron spins. Using a single electron spin of a nitrogen-vacancy center in diamond, we experimentally verify the correctness of the protocol, and demonstrate its usefulness for quantum control tasks., Kavli Institute of Nanoscience, Applied Sciences

Published

2010

27. Bootstrap Tomography of the Pulses for Quantum Control

Author

Dobrovitski, V.V. (author), De Lange, G. (author), Ristè, D. (author), Hanson, R. (author), Dobrovitski, V.V. (author), De Lange, G. (author), Ristè, D. (author), and Hanson, R. (author)

Abstract

Long-time dynamical decoupling and quantum control of qubits require high-precision control pulses. Full characterization (quantum tomography) of imperfect pulses presents a bootstrap problem: tomography requires initial states of a qubit which cannot be prepared without perfect pulses. We present a protocol for pulse error analysis, specifically tailored for a wide range of the single solid-state electron spins. Using a single electron spin of a nitrogen-vacancy center in diamond, we experimentally verify the correctness of the protocol, and demonstrate its usefulness for quantum control tasks., Kavli Institute of Nanoscience, Applied Sciences

Published

2010

28. Decay of Rabi Oscillations by Dipolar-Coupled Dynamical Spin Environments

Author

Dobrovitski, V.V. (author), Feiguin, A.E. (author), Hanson, R. (author), Awschalom, D.D. (author), Dobrovitski, V.V. (author), Feiguin, A.E. (author), Hanson, R. (author), and Awschalom, D.D. (author)

Abstract

We study the Rabi oscillations decay of a spin decohered by a spin bath whose internal dynamics is caused by dipolar coupling between the bath spins. The form and rate of decay as a function of the intrabath coupling is obtained analytically, and confirmed numerically. The complex form of decay smoothly varies from power law to exponential, and the rate changes nonmonotonically with the intrabath coupling, decreasing for both slow and fast baths. The form and rate of Rabi oscillations decay can be used to experimentally determine the intrabath coupling strength for a broad class of solid-state systems., Kavli Institute of Nanoscience, Applied Sciences

Published

2009

29. Excited-State Spectroscopy Using Single Spin Manipulation in Diamond

Author

Fuchs, G.D. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Batra, A. (author), Weis, C.D. (author), Schenkel, T. (author), Awschalom, D.D. (author), Fuchs, G.D. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Batra, A. (author), Weis, C.D. (author), Schenkel, T. (author), and Awschalom, D.D. (author)

Abstract

We use single-spin resonant spectroscopy to study the spin structure in the orbital excited state of a diamond nitrogen-vacancy (N-V) center at room temperature. The data show that the excited-state spin levels have a zero-field splitting that is approximately half of the value of the ground state levels, a g factor similar to the ground state value, and a hyperfine splitting ~20x larger than in the ground state. In addition, the width of the resonances reflects the electronic lifetime in the excited state. We also show that the spin level splitting can significantly differ between N-V centers, likely due to the effects of local strain, which provides a pathway to control over the spin Hamiltonian and may be useful for quantuminformation processing., Kavli Institute of Nanoscience, Applied Sciences

Published

2008

30. Decoherence dynamics of a single spin versus spin ensemble

Author

Dobrovitski, V.V. (author), Feiguin, A.E. (author), Awschalom, D.D. (author), Hanson, R. (author), Dobrovitski, V.V. (author), Feiguin, A.E. (author), Awschalom, D.D. (author), and Hanson, R. (author)

Abstract

We study decoherence of central spins by a spin bath, focusing on the difference between measurement of a single central spin and measurement of a large number of central spins (as found in typical spin-resonance experiments). For a dilute spin bath, the single spin demonstrates Gaussian free-induction decay, in contrast to exponential decay characteristic of spin ensembles. A strong difference between a single spin and a spin ensemble also exists for the Rabi oscillation decay: for a repeated Rabi oscillation experiment, suppression of decoherence happens for a single spin while acceleration takes place for a spin ensemble. The mathematical origin of such behavior is similar to quantum Zeno/anti-Zeno effects., Kavli Institute of Nanoscience, Applied Sciences

Published

2008

31. Decoherence dynamics of a single spin versus spin ensemble

Author

Dobrovitski, V.V. (author), Feiguin, A.E. (author), Awschalom, D.D. (author), Hanson, R. (author), Dobrovitski, V.V. (author), Feiguin, A.E. (author), Awschalom, D.D. (author), and Hanson, R. (author)

Abstract

We study decoherence of central spins by a spin bath, focusing on the difference between measurement of a single central spin and measurement of a large number of central spins (as found in typical spin-resonance experiments). For a dilute spin bath, the single spin demonstrates Gaussian free-induction decay, in contrast to exponential decay characteristic of spin ensembles. A strong difference between a single spin and a spin ensemble also exists for the Rabi oscillation decay: for a repeated Rabi oscillation experiment, suppression of decoherence happens for a single spin while acceleration takes place for a spin ensemble. The mathematical origin of such behavior is similar to quantum Zeno/anti-Zeno effects., Kavli Institute of Nanoscience, Applied Sciences

Published

2008

32. Excited-State Spectroscopy Using Single Spin Manipulation in Diamond

Author

Fuchs, G.D. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Batra, A. (author), Weis, C.D. (author), Schenkel, T. (author), Awschalom, D.D. (author), Fuchs, G.D. (author), Dobrovitski, V.V. (author), Hanson, R. (author), Batra, A. (author), Weis, C.D. (author), Schenkel, T. (author), and Awschalom, D.D. (author)

Abstract

We use single-spin resonant spectroscopy to study the spin structure in the orbital excited state of a diamond nitrogen-vacancy (N-V) center at room temperature. The data show that the excited-state spin levels have a zero-field splitting that is approximately half of the value of the ground state levels, a g factor similar to the ground state value, and a hyperfine splitting ~20x larger than in the ground state. In addition, the width of the resonances reflects the electronic lifetime in the excited state. We also show that the spin level splitting can significantly differ between N-V centers, likely due to the effects of local strain, which provides a pathway to control over the spin Hamiltonian and may be useful for quantuminformation processing., Kavli Institute of Nanoscience, Applied Sciences

Published

2008