Optical-domain spectral super-resolution via a quantum-memory-based
time-frequency processor
- URL: http://arxiv.org/abs/2106.04450v2
- Date: Sat, 5 Feb 2022 10:51:56 GMT
- Title: Optical-domain spectral super-resolution via a quantum-memory-based
time-frequency processor
- Authors: Mateusz Mazelanik, Adam Leszczy\'nski, Micha{\l} Parniak
- Abstract summary: We exploit the full spectral information of the optical field in order to beat the Rayleigh limit in spectroscopy.
We employ an optical quantum memory with spin-wave storage and an embedded processing capability to implement a time-inversion interferometer for input light.
Our tailored measurement achieves a resolution of 15 kHz and requires 20 times less photons than a corresponding Rayleigh-limited conventional method.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Existing super-resolution methods of optical imaging hold a solid place as an
application in natural sciences, but many new developments allow for beating
the diffraction limit in a more subtle way. One of the recently explored
strategies to fully exploit information already present in the field is to
perform a quantum-inspired tailored measurements. Here we exploit the full
spectral information of the optical field in order to beat the Rayleigh limit
in spectroscopy. We employ an optical quantum memory with spin-wave storage and
an embedded processing capability to implement a time-inversion interferometer
for input light, projecting the optical field in the symmetric-antisymmetric
mode basis. Our tailored measurement achieves a resolution of 15 kHz and
requires 20 times less photons than a corresponding Rayleigh-limited
conventional method. We demonstrate the advantage of our technique over both
conventional spectroscopy and heterodyne measurements, showing potential for
application in distinguishing ultra-narrowband emitters, optical communication
channels, or signals transduced from lower-frequency domains.
Related papers
- Super-resolution of ultrafast pulses via spectral inversion [0.0]
We experimentally demonstrate a spectroscopic super-resolution method aimed at broadband light (10s to 100s of GHz)
We study the paradigmatic problem of estimating a small separation between two incoherent spectral features of equal brightness, with a small number of photons per coherence time.
The setup is based on an actively stabilized Mach-Zehnder-type interferometer with electro-optic time lenses and passive spectral dispersers implementing the inversion.
arXiv Detail & Related papers (2024-03-18T12:21:37Z) - Spectrum-to-position mapping via programmable spatial dispersion
implemented in an optical quantum memory [0.0]
We propose a protocol for spectrum-to-position conversion using spatial spin wave modulation technique in gradient echo quantum memory.
Results hold prospects for ultra-precise spectroscopy and present an opportunity to enhance many protocols in quantum and classical communication, sensing, and computing.
arXiv Detail & Related papers (2023-08-03T14:41:44Z) - Retrieving space-dependent polarization transformations via near-optimal
quantum process tomography [55.41644538483948]
We investigate the application of genetic and machine learning approaches to tomographic problems.
We find that the neural network-based scheme provides a significant speed-up, that may be critical in applications requiring a characterization in real-time.
We expect these results to lay the groundwork for the optimization of tomographic approaches in more general quantum processes.
arXiv Detail & Related papers (2022-10-27T11:37:14Z) - On-chip quantum information processing with distinguishable photons [55.41644538483948]
Multi-photon interference is at the heart of photonic quantum technologies.
Here, we experimentally demonstrate that detection can be implemented with a temporal resolution sufficient to interfere photons detuned on the scales necessary for cavity-based integrated photon sources.
We show how time-resolved detection of non-ideal photons can be used to improve the fidelity of an entangling operation and to mitigate the reduction of computational complexity in boson sampling experiments.
arXiv Detail & Related papers (2022-10-14T18:16:49Z) - Ultra-long photonic quantum walks via spin-orbit metasurfaces [52.77024349608834]
We report ultra-long photonic quantum walks across several hundred optical modes, obtained by propagating a light beam through very few closely-stacked liquid-crystal metasurfaces.
With this setup we engineer quantum walks up to 320 discrete steps, far beyond state-of-the-art experiments.
arXiv Detail & Related papers (2022-03-28T19:37:08Z) - Slowing down light in a qubit metamaterial [98.00295925462214]
superconducting circuits in the microwave domain still lack such devices.
We demonstrate slowing down electromagnetic waves in a superconducting metamaterial composed of eight qubits coupled to a common waveguide.
Our findings demonstrate high flexibility of superconducting circuits to realize custom band structures.
arXiv Detail & Related papers (2022-02-14T20:55:10Z) - Rapid characterisation of linear-optical networks via PhaseLift [51.03305009278831]
Integrated photonics offers great phase-stability and can rely on the large scale manufacturability provided by the semiconductor industry.
New devices, based on such optical circuits, hold the promise of faster and energy-efficient computations in machine learning applications.
We present a novel technique to reconstruct the transfer matrix of linear optical networks.
arXiv Detail & Related papers (2020-10-01T16:04:22Z) - Hyperentanglement in structured quantum light [50.591267188664666]
Entanglement in high-dimensional quantum systems, where one or more degrees of freedom of light are involved, offers increased information capacities and enables new quantum protocols.
Here, we demonstrate a functional source of high-dimensional, noise-resilient hyperentangled states encoded in time-frequency and vector-vortex structured modes.
We generate highly entangled photon pairs at telecom wavelength that we characterise via two-photon interference and quantum state tomography, achieving near-unity visibilities and fidelities.
arXiv Detail & Related papers (2020-06-02T18:00:04Z) - Probing excited-state dynamics with quantum entangled photons:
Correspondence to coherent multidimensional spectroscopy [0.0]
Quantum light is a key resource for promoting quantum technology.
One such class of technology aims to improve the precision of optical measurements using engineered quantum states of light.
arXiv Detail & Related papers (2020-05-22T03:22:44Z) - Spectrally reconfigurable quantum emitters enabled by optimized fast
modulation [42.39394379814941]
Spectral control in solid state platforms such as color centers, rare earth ions, and quantum dots is attractive for realizing such applications on-chip.
We propose the use of frequency-modulated optical transitions for spectral engineering of single photon emission.
Our results suggest that frequency modulation is a powerful technique for the generation of new light states with unprecedented control over the spectral and temporal properties of single photons.
arXiv Detail & Related papers (2020-03-27T18:24:35Z) - Conditional Spectroscopy via Non-Stationary Optical Homodyne Quantum
State Tomography [0.0]
We introduce non-stationary quantum state tomography, which adapts the technique to the special requirements of ultrafast spectroscopy.
In detail, we gain access to the amplitude and phase of light fields with a temporal resolution of about 100,fs without the need for a fixed phase reference.
arXiv Detail & Related papers (2020-02-04T18:42:39Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.