Multi-level quantum noise spectroscopy

Sung, Youngkyu; Vepsäläinen, Antti; Braumüller, Jochen; Yan, Fei; Wang, Joel I-Jan; Kjærgaard, Morten; Winik, Roni; Krantz, Philip; Bengtsson, Andreas; Melville, Alexander; Niedzielski, Bethany; Schwartz, Maurice L.; Kim, David K.; Yoder, Jonilyn; Orlando, Terry P.; Gustavsson, Simon; Oliver, William

doi:10.1038/s41467-021-21098-3

Cited by 23 publications

(25 citation statements)

References 48 publications

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“…While this can be realized in many different experimental platforms (e.g., a superconducting transmon qubit, as implemented in Ref. 19 ), we focus here on sensor based on a S = 1 NV defect in diamond 22 . For this system, we discuss a specific protocol to reconstruct finite-frequency spectral function by engineering time-dependent quenches.…”

Section: Resultsmentioning

confidence: 99%

“…A key technique in quantum sensing is to use a suitably driven sensor qubit to characterize a noisy, dissipative environment. Commonly referred to as quantum noise spectroscopy (QNS) 1 , this modality allows one to understand and possibly mitigate sources of decoherence that degrade a quantum processor 2 – 19 . It also serves as a powerful means to probe a complicated many-body target system via its fluctuation properties (see, e.g., 20 – 24 ).…”

Section: Introductionmentioning

confidence: 99%

“…It also serves as a powerful means to probe a complicated many-body target system via its fluctuation properties (see, e.g., 20 – 24 ). While many QNS protocols focus on the more specific problem of characterizing classical Gaussian noise 4 – 12 , recent work has explored methods that go beyond these assumptions 13 – 19 , 25 – 30 .…”

Section: Introductionmentioning

confidence: 99%

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Intrinsic and induced quantum quenches for enhancing qubit-based quantum noise spectroscopy

Wang

Clerk

2021

Nat Commun

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Quantum sensing protocols that exploit the dephasing of a probe qubit are powerful and ubiquitous methods for interrogating an unknown environment. They have a variety of applications, ranging from noise mitigation in quantum processors, to the study of correlated electron states. Here, we discuss a simple strategy for enhancing these methods, based on the fact that they often give rise to an inadvertent quench of the probed system: there is an effective sudden change in the environmental Hamiltonian at the start of the sensing protocol. These quenches are extremely sensitive to the initial environmental state, and lead to observable changes in the sensor qubit evolution. We show how these new features give access to environmental response properties. This enables methods for direct measurement of bath temperature, and for detecting non-thermal equilibrium states. We also discuss how to deliberately control and modulate this quench physics, which enables reconstruction of the bath spectral function. Extensions to non-Gaussian quantum baths are also discussed, as is the application of our ideas to a range of sensing platforms (e.g., nitrogen-vacancy (NV) centers in diamond, semiconductor quantum dots, and superconducting circuits).

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Intrinsic and induced quantum quenches for enhancing qubit-based quantum noise spectroscopy

Wang

Clerk

2021

Nat Commun

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“…Noise spectroscopy elucidates the fundamental noise sources in spin systems, which is essential for developing spin qubits with long coherence times for quantum information processing [1], communication [2], and sensing [3]. But noise spectroscopy typically relies on microwave coherent spin control to extract the noise spectrum [4][5][6][7][8][9], which becomes infeasible when there are highfrequency noise components stronger than the available microwave power. Here, we demonstrate an alternative all-optical approach to performing noise spectroscopy.…”

mentioning

confidence: 99%

“…The coherent control of spin qubits can be used to conduct noise spectroscopy of their surrounding environment [4][5][6][7][8][9], in which the spin is used to probe the frequencies of the fluctuating fields generated by neighbouring nuclear and electronic spins as well as the strength of their interaction with the spin (i.e., the spectral density). Such noise spectroscopy using microwave fields has shed light on the fundamental noise processes of spin systems such as superconducting qubits [4,5], nitrogen-vacancy centres in diamond [6,7], and gate-defined quantum dots [8,9]. However, the bandwidth of noise spectroscopy utilising microwave fields is limited by the rate of the spin rotation (i.e., the Rabi frequency), which must exceed the frequencies of the noise.…”

mentioning

confidence: 99%

All-optical noise spectroscopy of a solid-state spin

Farfurnik

Singh

Luo

et al. 2021

Preprint

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Noise spectroscopy elucidates the fundamental noise sources in spin systems, which is essential for developing spin qubits with long coherence times for quantum information processing, communication, and sensing. But noise spectroscopy typically relies on microwave coherent spin control to extract the noise spectrum, which becomes infeasible when there are high-frequency noise components stronger than the available microwave power. Here, we demonstrate an alternative all-optical approach to performing noise spectroscopy. Our approach utilises coherent Raman rotations of the spin state with controlled timing and phase to implement Carr-Purcell-Meiboom-Gill (CPMG) pulse sequences. Analysing the spin dynamics under these sequences enables us to extract the noise spectrum of a dense ensemble of nuclear spins interacting with a single spin in a quantum dot, which has thus far only been modelled theoretically. By providing large spectral bandwidths of over 100 MHz, our Raman-based approach could serve as an important tool to study spin dynamics and decoherence mechanisms for a broad range of solid-state spin qubits.

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