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  • richardmitnick 11:55 am on December 29, 2020 Permalink | Reply
    Tags: "Metasurface enabled quantum edge detection", Combining quantum entanglement and edge detection., Metasurfaces provide unique platforms to realize exotic phenomena including negative refraction; achromatic focusing; and electromagnetic cloaking due to the engineered dielectric or metallic architec, , , , Schrödinger’s cat   

    From phys.org: “Metasurface enabled quantum edge detection” 

    From phys.org

    December 29, 2020
    Thamarasee Jeewandara

    The schematics of a metasurface enabled quantum edge detection. (A) The metasurface is designed to perform edge detection for a preferred linear polarization. |V〉, i.e., polarization state is orthogonal to the analyzer. The dashed light red line stands for the electrical path. The question mark means that polarization selection of idler photons of the heralding arm is unknown. If the Schrödinger’s cat is illuminated by unknown linear polarization photons from the polarization entangled source, the image would be a superposition of a regular “solid cat” and an edge-enhanced “outlined cat.” (B) The switch state ON or OFF of the heralding arm. When the idler photons of the heralding arm are projected to |H〉, it indicates the switch OFF state and leads to a solid cat captured. While the heralded photons are projected to |V〉, an edge-enhanced outlined cat is obtained with the switch ON state. (C and D) The calculated and experimental results of a solid cat, respectively. (E and F) The calculated and experimental results of the edge-enhanced outlined cat, respectively. Credit: Science Advances.

    Metasurfaces provide unique platforms to realize exotic phenomena including negative refraction, achromatic focusing, and electromagnetic cloaking due to the engineered dielectric or metallic architectures. The intersection of metasurfaces and quantum optics can lead to significant opportunities that remain to be explored. In a new report now published on Science Advances, Junxiao Zhou, Shikai Liu and a research team in quantum information, nano-optoelectronic devices and computer engineering in China and the U.S. proposed and demonstrated a polarization-entangled photon source. They used the source to switch the optical edge mode in an imaging system to ON or OFF states based on a highly dielectric metasurface. The experiment enriched the fields of quantum optics and metamaterials as a promising direction toward quantum edge detection and image processing with a remarkable signal-to-noise ratio.

    Combining quantum entanglement and edge detection

    Photonic metasurfaces are two-dimensional (2-D) ultrathin arrays of engineered metallic or dielectric structures that can facilitate electromagnetic field manipulation of the local phase, amplitude and polarization. Researchers generally develop such capabilities for a variety of applications in classical optics. Quantum entanglement is essential in quantum optics for many applications including quantum cryptography, teleportation, superresolving metrology and quantum imaging. Recent efforts show a trend to combine the metasurface with entangled photons for potential applications in quantum optics. Edge detection is another factor that contributes to image processing to define the boundaries between regions in an image. It is a basic tool in computer vision to pre-process automations in medical imaging and forms a critical component of autonomous vehicles. Metasurface-enabled edge detection can be used in quantum optics to offer possibilities of remote-controlled image processing and cryptography. In this work, Zhou et al. therefore realized a polarization-entangled photon source and high-efficiency metasurface enabled switchable optical edge detection method. The combined strategy showed a high signal-to-noise (SNR) ratio at the same photon flux level (the number of photons per second per unit area).

    Experimental setup and sample characterization. (A) Experimental setup of metasurface enabled quantum edge detection. BDM, broadband dielectric mirror; PBS, polarization beam splitter; DM, dichromatic mirror; FC, fiber coupler; BPF, band-pass filter; ICCD, intensified charge coupled device. By pumping a nonlinear crystal (type II phase-matched bulk PPKTP crystal) with a 405-nm laser, pairs of orthogonally polarized photons with 810-nm wavelength are generated through the spontaneously parametric down-conversion process. The blue (red) light path presents the 405-nm (810 nm) light. Edge detection switch is on the heralding arm. An edge detection imaging system is on the imaging arm. (B) Photograph of the partial metasurface sample. Scale bar, 4 mm. (C) Polariscopic analysis characterized by crossed linear polarizers of the sample area marked in 2a. The blue bars indicate the orientation of rotated nanostructures in one period, which represents the Pancharatnam-Berry phase induced by the laser writing dielectric metasurface. Scale bar, 50 μm. (D) The scanning electron microscopy image of the sample area marked in (C). Scale bar, 1 μm. Photo credit: Junxiao Zhou, University of California, San Diego. Credit: Science Advances [above].

    Using the “Schrödinger’s cat” concept

    Zhou et al. used the Schrödinger’s cat concept to illustrate the expected performance of the switchable quantum edge detection scheme. They reviewed the basic principle of edge detection based on classical continuous wave (CW) light-illumination. In the experimental setup, the edge detection imaging arm was independent of the entangled source and the heralding arm, as well as the coincidence measurement components. When the incident photons achieved a horizontal polarization state, the beam of illuminated light passed through a cat-shaped aperture and an engineered metasurface to separate into a left- and right-handed overlapped polarized image with a horizontal shift. The overlapped components then passed through a horizontally oriented analyzer to form a ‘solid cat’ image. If, however, the incident photons were vertically polarized, the overlapped components recombined to a linear polarized component that is completely blocked by the analyzer to only form an outline of a cat. The researchers therefore used polarization-entangled photons as a source of illumination to develop quantum switchable edge detection in this way.

    The experimental setup and polarization-entangled photon pairs

    Characterizations of the entangled source. (A) Coincidence counts as a function of the HWP angle θ2 at one output port in 2 s. The red (blue) color of count data and interference corresponds to horizontal (diagonal) projection bases. The solid lines are sinusoidal fits to the data, error bars are estimated by assuming Poisson photon statistics in photon counting. Error bars are obtained from multiple measurements. (B and C) The real and imaginary parts of the reconstructed density matrix ρ of the two-photon states, respectively. Credit: Science Advances [above].

    The researchers generated polarization entangled photons using a spontaneous parametric down-conversion process in a 20-mm-long type II phase-matched periodically poled potassium titanyl phosphate (KTiOPO4/PPKTP) crystal embedded in a Sagnac interferometer. They set the temperature of the crystal to 17 degrees Celsius and used two broadband dielectric mirrors and a dual-wavelength polarization beam splitter to form the self-stable Sagnac interferometer. They then used a continuous wave single-frequency diode laser at 405 nm to generate the pump beam focused by a pair of lenses with optimized focal lengths to attain a beam waist approximating 40 microns at the center of the crystal. To balance the power in the clockwise and counter-clockwise-directions, Zhou et al. used a quarter-wave plate (QWP) and a half-wave plate (HWP) in front to the Sagnac loop.

    Using a dual-wavelength polarization beam splitter, they separated the down-converted photon pairs pumped by two counter-propagating beams, to send one into the imaging arm and the other to heralding arms, respectively. Zhou et al. also designed the metasurface employed in the setup using the Pancharatnam-Berry phase and fabricated it by scanning a femtosecond pulse laser within a silica slab. Then using scanning electron microscopy, they observed self-assembled nanostructures in the silica slab and showed their origin under intense laser irradiation to generate the metasurface. The team briefly described the quantum state preparation for the polarization entangled degenerate photon pairs generated from the Signac loop. They used the Bell state (the simplest example of nonseparable quantum entanglement) for this work by adjusting the experimental setup. Zhou et al. quantified the entanglement quality of the two-photon state using quantum tomography and reconstructed two-photon density matrix measurements.

    The switchable edge detection demonstration. (A to D) The metasurface sample orientation, which is aligned with the xy plane. The inset yellow arrows indicate the phase gradient direction of the metasurface. (E to H) The images of the whole object comprising the separated LCP and RCP components, which is the OFF state of the edge detection mode. (I to L) The images reveal edges along different directions, which is the ON state of the edge detection mode. Photo credit: Junxiao Zhou, University of California, San Diego. Credit: Science Advances [above].

    Quantum-entanglement enabled quantum edge detection

    After confirming the quality of generated polarization-entangled photon pairs, they demonstrated switchable quantum edge detection. To accomplish this, they prepared the photons in horizontal or vertical linear polarizations states using the setup and coupled the photons into the fiber and sent them to the edge detection image system to capture the final alternative image via an intensified charge-coupled device camera (ICCD). For instance, Zhou et al. obtained two overlapped images with a tiny shift, where the shift direction aligned with the phase gradient direction of the metasurface. When they increased the period of the metasurface structure, they decreased the shift between the two overlapped images to achieve high-resolution edge detection. The quantum edge detection scheme had another advantage due to its high signal-to-noise (SNR) ratio, where the team could significantly reduce the ambient noise in the setup, where noise only accumulated in a very short timeframe. By contrast, in classical optics, the noise would continue to accumulate. As proof of concept, they acquired an edge image with remarkable SNR for improved entanglement-enabled experimental quantum edge detection.


    In this way, Junxiao Zhou, Shikai Liu and colleagues combined quantum entanglement-enabled quantum edge detection using a metasurface filter combined with a polarization-entangled source. The metasurfaces provided ultrathin and lightweight optical elements with precisely engineered phase profiles to obtain a variety of functions to form a more compact and integrated system. The setup will assist the conception of security applications including image encryption and steganography. The method also offers an appealing signal-to-noise (SNR) ratio suited for a variety of photon-hungry imaging and sensing applications in biomedicine, including tracking enzymatic reactions and observing living organisms or photosensitive cells.

    More information:

    Flat optics with designer metasurfaces
    Nature Materials

    Experimental quantum teleportation

    See the full article here .


    Please help promote STEM in your local schools.

    Stem Education Coalition

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  • richardmitnick 11:00 am on August 14, 2020 Permalink | Reply
    Tags: "Yale quantum researchers create an error-correcting cat", , , , , Schrödinger’s cat, ,   

    From Yale University: “Yale quantum researchers create an error-correcting cat” 

    From Yale University

    August 12, 2020

    Media Contact
    Fred Mamoun

    By Jim Shelton

    (Illustration by Michael S. Helfenbein)

    Yale physicists have developed an error-correcting cat — a new device that combines the Schrödinger’s cat concept of superposition (a physical system existing in two states at once) with the ability to fix some of the trickiest errors in a quantum computation.

    It is Yale’s latest breakthrough in the effort to master and manipulate the physics necessary for a useful quantum computer: correcting the stream of errors that crop up among fragile bits of quantum information, called qubits, while performing a task.

    A new study reporting on the discovery appears in the journal Nature. The senior author is Michel Devoret, Yale’s F.W. Beinecke Professor of Applied Physics and Physics. The study’s co-first authors are Alexander Grimm, a former postdoctoral associate in Devoret’s lab who is now a tenure-track scientist at the Paul Scherrer Institute in Switzerland, and Nicholas Frattini, a graduate student in Devoret’s lab.

    Quantum computers have the potential to transform an array of industries, from pharmaceuticals to financial services, by enabling calculations that are orders of magnitude faster than today’s supercomputers.

    Yale — led by Devoret, Robert Schoelkopf, and Steven Girvin — continues to build upon two decades of groundbreaking quantum research. Yale’s approach to building a quantum computer is called “circuit QED” and employs particles of microwave light (photons) in a superconducting microwave resonator.

    In a traditional computer, information is encoded as either 0 or 1. The only errors that crop up during calculations are “bit-flips,” when a bit of information accidentally flips from 0 to 1 or vice versa. The way to correct it is by building in redundancy: using three “physical” bits of information to ensure one “effective” — or accurate — bit.

    In contrast, quantum information bits — qubits — are subject to both bit-flips and “phase-flips,” in which a qubit randomly flips between quantum superpositions (when two opposite states exist simultaneously).

    Until now, quantum researchers have tried to fix errors by adding greater redundancy, requiring an abundance of physical qubits for each effective qubit.

    Enter the cat qubit — named for Schrödinger’s cat, the famous paradox used to illustrate the concept of superposition.

    The idea is that a cat is placed in a sealed box with a radioactive source and a poison that will be triggered if an atom of the radioactive substance decays. The superposition theory of quantum physics suggests that until someone opens the box, the cat is both alive and dead, a superposition of states. Opening the box to observe the cat causes it to abruptly change its quantum state randomly, forcing it to be either alive or dead.

    “Our work flows from a new idea. Why not use a clever way to encode information in a single physical system so that one type of error is directly suppressed?” Devoret asked.

    Unlike the multiple physical qubits needed to maintain one effective qubit, a single cat qubit can prevent phase flips all by itself. The cat qubit encodes an effective qubit into superpositions of two states within a single electronic circuit — in this case a superconducting microwave resonator whose oscillations correspond to the two states of the cat qubit.

    “We achieve all of this by applying microwave frequency signals to a device that is not significantly more complicated than a traditional superconducting qubit,” Grimm said.

    The researchers said they are able to change their cat qubit from any one of its superposition states to any other superposition state, on command. In addition, the researchers developed a new way of reading out — or identifying — the information encoded into the qubit.

    “This makes the system we have developed a versatile new element that will hopefully find its use in many aspects of quantum computation with superconducting circuits,” Devoret said.

    Co-authors of the study are Girvin, Shruti Puri, Shantanu Mundhada, and Steven Touzard, all of Yale; Mazyar Mirrahimi of Inria Paris; and Shyam Shankar of the University of Texas-Austin.

    The United States Department of Defense, the United States Army Research Office, and the National Science Foundation funded the research.


    Physicists can predict the jumps of Schrödinger’s cat (and finally save it)
    In quantum computing, doubling down on Schrödinger’s cat

    See the full article here .


    Please help promote STEM in your local schools.

    Stem Education Coalition

    Yale University comprises three major academic components: Yale College (the undergraduate program), the Graduate School of Arts and Sciences, and the professional schools. In addition, Yale encompasses a wide array of centers and programs, libraries, museums, and administrative support offices. Approximately 11,250 students attend Yale.

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