Search

Your search keyword '"Karnieli, A."' showing total 1,969 results
Start Over Author "Karnieli, A."
1,969 results on '"Karnieli, A."'

1. Automated modal analysis of entanglement with bipartite self-configuring optics

Author

Roques-Carmes, Charles, Karnieli, Aviv, Miller, David A. B., and Fan, Shanhui

Subjects
Quantum Physics, Physics - Optics
Abstract

Entanglement is a unique feature of quantum mechanics. In coupled systems of light and matter, entanglement manifests itself in the linear superposition of multipartite quantum states (e.g., parametrized by the multiple spatial, spectral, or temporal degrees of freedom of a light field). In bipartite systems, the Schmidt decomposition provides a modal decomposition of the entanglement structure over independent, separable states. Although ubiquitous as a tool to describe and measure entanglement, there exists no general method to decompose a bipartite quantum state onto its Schmidt modes. Here, we propose a method that relies on bipartite self-configuring optics that automatically "learns" the Schmidt decomposition of an arbitrary pure quantum state. Our method is agnostic to the degrees of freedom over which quantum entanglement is distributed and can reconstruct the Schmidt modes and values by variational optimization of the network's output powers or coincidences. We illustrate our method with numerical examples of spectral entanglement analysis for biphotons generated via spontaneous parametric down conversion and provide experimental guidelines for its realization, including the influence of losses and impurities. Our method provides a versatile and scalable way of analyzing entanglement in bipartite integrated quantum photonic systems.

Published
2024

2. Decoherence-free many-body Hamiltonians in nonlinear waveguide quantum electrodynamics

Author

Karnieli, Aviv, Tziperman, Offek, Roques-Carmes, Charles, and Fan, Shanhui

Subjects
Quantum Physics
Abstract

Enhancing interactions in many-body quantum systems, while protecting them from environmental decoherence, is at the heart of many quantum technologies. Waveguide quantum electrodynamics is a promising platform for achieving this, as it hosts infinite-range interactions and decoherence-free subspaces of quantum emitters. However, as coherent interactions between emitters are typically washed out in the wavelength-spacing regime hosting decoherence-free states, coherent control over the latter becomes limited, and many-body Hamiltonians in this important regime remain out of reach. Here we show that by incorporating emitter arrays with nonlinear waveguides hosting parametric gain, we obtain a unique class of many-body interaction Hamiltonians with coupling strengths that increase with emitter spacing, and persist even for wavelength-spaced arrays. We then propose to use these Hamiltonians to coherently generate decoherence-free states directly from the ground state, using only global squeezing drives, without the need for local addressing of individual emitters. Interestingly, we find that the dynamics approaches a unitary evolution in the limit of weak intra-waveguide squeezing, and discuss potential experimental realizations of this effect. Our results pave the way towards coherent control protocols in waveguide quantum electrodynamics, with applications including quantum computing, simulation, memory and nonclassical light generation.

Published
2024

3. Strong coupling and single-photon nonlinearity in free-electron quantum optics

Author

Karnieli, Aviv, Roques-Carmes, Charles, Rivera, Nicholas, and Fan, Shanhui

Subjects
Quantum Physics
Abstract

The observation that free electrons can interact coherently with quantized electromagnetic fields and matter systems has led to a plethora of proposals leveraging the unique quantum properties of free electrons. At the heart of these proposals lies the assumption of a strong quantum interaction between a flying free electron and a photonic mode. However, existing schemes are intrinsically limited by electron diffraction, which puts an upper bound on the interaction length and therefore the quantum coupling strength. Here, we propose the use of "free-electron fibers'': effectively one-dimensional photonic systems where free electrons co-propagate with two guided modes. The first mode applies a ponderomotive trap to the free electron, effectively lifting the limitations due to electron diffraction. The second mode strongly couples to the guided free electron, with an enhanced coupling that is orders of magnitude larger than previous designs. Moreover, the extended interaction lengths enabled by our scheme allows for strong single-photon nonlinearities mediated by free electrons. We predict a few interesting observable quantum effects in our system, such as deterministic single-photon emission and complex, nonlinear multimode dynamics. Our proposal paves the way towards the realization of many anticipated effects in free-electron quantum optics, such as non-Gaussian light generation, deterministic single photon emission, and quantum gates controlled by free-electron--photon interactions., Comment: References updated in version 2

Published
2024

4. Deep Semantic Model Fusion for Ancient Agricultural Terrace Detection

Author

Wang, Yi, Liu, Chenying, Tiwari, Arti, Silver, Micha, Karnieli, Arnon, Zhu, Xiao Xiang, and Albrecht, Conrad M

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Discovering ancient agricultural terraces in desert regions is important for the monitoring of long-term climate changes on the Earth's surface. However, traditional ground surveys are both costly and limited in scale. With the increasing accessibility of aerial and satellite data, machine learning techniques bear large potential for the automatic detection and recognition of archaeological landscapes. In this paper, we propose a deep semantic model fusion method for ancient agricultural terrace detection. The input data includes aerial images and LiDAR generated terrain features in the Negev desert. Two deep semantic segmentation models, namely DeepLabv3+ and UNet, with EfficientNet backbone, are trained and fused to provide segmentation maps of ancient terraces and walls. The proposed method won the first prize in the International AI Archaeology Challenge. Codes are available at https://github.com/wangyi111/international-archaeology-ai-challenge., Comment: IEEE Big Data 2022 workshop on Digital Twins for Accelerated Discovery of Climate & Sustainability Solutions (ADoCS)

Published
2023

5. Free-electron crystals for enhanced X-ray radiation.

Author

Wong, Lee, Shi, Xihang, Karnieli, Aviv, Lim, Jeremy, Kumar, Suraj, Carbajo, Sergio, Kaminer, Ido, and Wong, Liang

Abstract

Bremsstrahlung-the spontaneous emission of broadband radiation from free electrons that are deflected by atomic nuclei-contributes to the majority of X-rays emitted from X-ray tubes and used in applications ranging from medical imaging to semiconductor chip inspection. Here, we show that the bremsstrahlung intensity can be enhanced significantly-by more than three orders of magnitude-through shaping the electron wavefunction to periodically overlap with atoms in crystalline materials. Furthermore, we show how to shape the bremsstrahlung X-ray emission pattern into arbitrary angular emission profiles for purposes such as unidirectionality and multi-directionality. Importantly, we find that these enhancements and shaped emission profiles cannot be attributed solely to the spatial overlap between the electron probability distribution and the atomic centers, as predicted by the paraxial and non-recoil theory for free electron light emission. Our work highlights an unprecedented regime of free electron light emission where electron waveshaping provides multi-dimensional control over practical radiation processes like bremsstrahlung. Our results pave the way towards greater versatility in table-top X-ray sources and improved fundamental understanding of quantum electron-light interactions.

Published
2024

6. DropCompute: simple and more robust distributed synchronous training via compute variance reduction

Author

Giladi, Niv, Gottlieb, Shahar, Shkolnik, Moran, Karnieli, Asaf, Banner, Ron, Hoffer, Elad, Levy, Kfir Yehuda, and Soudry, Daniel

Subjects
Computer Science - Machine Learning
Abstract

Background: Distributed training is essential for large scale training of deep neural networks (DNNs). The dominant methods for large scale DNN training are synchronous (e.g. All-Reduce), but these require waiting for all workers in each step. Thus, these methods are limited by the delays caused by straggling workers. Results: We study a typical scenario in which workers are straggling due to variability in compute time. We find an analytical relation between compute time properties and scalability limitations, caused by such straggling workers. With these findings, we propose a simple yet effective decentralized method to reduce the variation among workers and thus improve the robustness of synchronous training. This method can be integrated with the widely used All-Reduce. Our findings are validated on large-scale training tasks using 200 Gaudi Accelerators., Comment: https://github.com/paper-submissions/dropcompute

Published
2023

7. Frequency-domain engineering of bright squeezed vacuum for continuous-variable quantum information

Author

Hurvitz, Inbar, Karnieli, Aviv, and Arie, Ady

Subjects
Quantum Physics
Abstract

Multimode bright squeezed vacuum is a non-classical state of light hosting a macroscopic photon number while offering promising capacity for encoding quantum information in its spectral degree of freedom. Here, we employ an accurate model for parametric downconversion in the high-gain regime and use nonlinear holography to design quantum correlations of bright squeezed vacuum in the frequency domain. We propose the design of quantum correlations over two-dimensional lattice geometries that are all-optically controlled, paving the way toward continuous-variable cluster state generation on an ultrafast timescale. Specifically, we investigate the generation of a square cluster state in the frequency domain and calculate its covariance matrix and the quantum nullifier uncertainties, that exhibit squeezing below the vacuum noise level., Comment: 11 pages, 5 figures

Published
2023
Full Text
View/download PDF

9. Designing Nonlinear Photonic Crystals for High-Dimensional Quantum State Engineering

Author

Rozenberg, Eyal, Karnieli, Aviv, Yesharim, Ofir, Foley-Comer, Joshua, Trajtenberg-Mills, Sivan, Mishra, Sarika, Prabhakar, Shashi, Pratap, Ravindra, Freedman, Daniel, Bronstein, Alex M., and Arie, Ady

Subjects
Quantum Physics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

We propose a novel, physically-constrained and differentiable approach for the generation of D-dimensional qudit states via spontaneous parametric down-conversion (SPDC) in quantum optics. We circumvent any limitations imposed by the inherently stochastic nature of the physical process and incorporate a set of stochastic dynamical equations governing its evolution under the SPDC Hamiltonian. We demonstrate the effectiveness of our model through the design of structured nonlinear photonic crystals (NLPCs) and shaped pump beams; and show, theoretically and experimentally, how to generate maximally entangled states in the spatial degree of freedom. The learning of NLPC structures offers a promising new avenue for shaping and controlling arbitrary quantum states and enables all-optical coherent control of the generated states. We believe that this approach can readily be extended from bulky crystals to thin Metasurfaces and potentially applied to other quantum systems sharing a similar Hamiltonian structures, such as superfluids and superconductors., Comment: ICLR Machine Learning for Materials (ML4Materials) Workshop 2023. arXiv admin note: text overlap with arXiv:2112.05934

Published
2023

10. Universal and ultrafast quantum computation based on free-electron-polariton blockade

Author

Karnieli, Aviv, Tsesses, Shai, Yu, Renwen, Rivera, Nicholas, Arie, Ady, Kaminer, Ido, and Fan, Shanhui

Subjects
Quantum Physics
Abstract

Cavity quantum electrodynamics (QED), wherein a quantum emitter is coupled to electromagnetic cavity modes, is a powerful platform for implementing quantum sensors, memories, and networks. However, due to the fundamental tradeoff between gate fidelity and execution time, as well as limited scalability, the use of cavity-QED for quantum computation was overtaken by other architectures. Here, we introduce a new element into cavity-QED - a free charged particle, acting as a flying qubit. Using free electrons as a specific example, we demonstrate that our approach enables ultrafast, deterministic and universal discrete-variable quantum computation in a cavity-QED-based architecture, with potentially improved scalability. Our proposal hinges on a novel excitation blockade mechanism in a resonant interaction between a free-electron and a cavity polariton. This nonlinear interaction is faster by several orders of magnitude with respect to current photon-based cavity-QED gates, enjoys wide tunability and can demonstrate fidelities close to unity. Furthermore, our scheme is ubiquitous to any cavity nonlinearity, either due to light-matter coupling as in the Jaynes-Cummings model or due to photon-photon interactions as in a Kerr-type many-body system. In addition to promising advancements in cavity-QED quantum computation, our approach paves the way towards ultrafast and deterministic generation of highly-entangled photonic graph states and is applicable to other quantum technologies involving cavity-QED.

Published
2023

11. Jaynes-Cummings interaction between low energy free-electrons and cavity photons

Author

Karnieli, Aviv and Fan, Shanhui

Subjects
Quantum Physics
Abstract

The Jaynes-Cummings Hamiltonian is at the core of cavity quantum electrodynamics, and is ubiquitous in a variety of quantum technologies. The ability to implement and control the various aspects of this Hamiltonian is thus of paramount importance. However, conventional implementations relying on bound-electron systems are fundamentally limited by the Coulomb potential that bounds the electron, in addition to suffering from practical limitations such as requiring cryogenic temperatures for operation and fabrication inhomogeneity. In this work, we propose theoretically a new approach to realize the Jaynes-Cummings Hamiltonian using low energy free-electrons coupled to dielectric microcavities, and exemplify several quantum technologies made possible by this approach. Our approach utilizes quantum recoil, which causes a large detuning that inhibits the emission of multiple consecutive photons, effectively transforming the free-electron into a two-level system coupled to the cavity mode. We show that this approach can be used for generation of single photons with unity efficiency and high fidelity. We then generalize the concept to achieve a multiple-level quantum emitter through a suitable design of cavity modes, allowing for deterministic photon-pair generation and even a quantum SWAP gate between a cavity photon and a free-electron qubit. An increase in coupling strength by a factor of \sqrt(N) can be achieved when an entangled symmetric state of N electrons is used to drive the cavity. Tunable by their kinetic energy and phase-matching to light waves, quantum free-electrons are inherently versatile emitters with an engineerable emission wavelength. As such, they pave the way towards new possibilities for quantum interconnects between photonic platforms at disparate spectral regimes., Comment: 18 pages, including Supplementary Material, 3 figures

Published
2023

12. Associations between medical students’ stress, academic burnout and moral courage efficacy

Author

Galit Neufeld-Kroszynski, Keren Michael, and Orit Karnieli-Miller

Subjects
Moral courage, Self-efficacy, Stress, Burnout, Medical students, Professionalism, Psychology, BF1-990
Abstract

Abstract Background Medical students, especially during the clinical years, are often exposed to breaches of safety and professionalism. These contradict personal and professional values exposing them to moral distress and to the dilemma of whether and how to act. Acting requires moral courage, i.e., overcoming fear to maintain one’s core values and professional obligations. It includes speaking up and “doing the right thing” despite stressors and risks (e.g., humiliation). Acting morally courageously is difficult, and ways to enhance it are needed. Though moral courage efficacy, i.e., individuals’ belief in their capability to act morally, might play a significant role, there is little empirical research on the factors contributing to students’ moral courage efficacy. Therefore, this study examined the associations between perceived stress, academic burnout, and moral courage efficacy. Methods A cross-sectional study among 239 medical students who completed self-reported questionnaires measuring perceived stress, academic burnout (‘exhaustion,’ ‘cynicism,’ ‘reduced professional efficacy’), and moral courage efficacy (toward others’ actions and toward self-actions). Data analysis via Pearson’s correlations, regression-based PROCESS macro, and independent t-tests for group differences. Results The burnout dimension of ‘reduced professional efficacy’ mediated the association between perceived stress and moral courage efficacy toward others’ actions. The burnout dimensions ‘exhaustion’ and ‘reduced professional efficacy’ mediated the association between perceived stress and moral courage efficacy toward self-actions. Conclusions The results emphasize the importance of promoting medical students’ well-being—in terms of stress and burnout—to enhance their moral courage efficacy. Medical education interventions should focus on improving medical students’ professional efficacy since it affects both their moral courage efficacy toward others and their self-actions. This can help create a safer and more appropriate medical culture.

Published
2024
Full Text
View/download PDF

13. Reinforced deep learning approach for analyzing spaceborne-derived crop phenology

Author

P.V. Arun and A. Karnieli

Subjects
Spatial heterogeneity, i.i.d. Assumption, Crop phenology, Vegetation Index Curves, Online Learning, VENµS, Physical geography, GB3-5030, Environmental sciences, GE1-350
Abstract

Vegetation Index (VI) curves capture the crop-specific phenological events from multi-temporal Earth observation images. Although advanced machine learning classifiers are the existing state-of-the-art, most of them assume the samples to be independent and identically distributed, which is not true for VI curve classification. This research proposed the consideration of spatial non-stationarity for VI curve-based crop classification. The proposed approach does not assume the samples to be independent and identically distributed. Different state-of-the-art approaches attempted to solve this problem by introducing architectural variations and considering the neighborhood patches. However, the inherent nature of the problem demanded an online approach. In the current research, this problem is formulated in a reinforcement learning framework where the generalizability of the predictor is improved using a feedback system. Different approaches for feedback were investigated in this study. The predictor was composed of a graph convolutional framework where the VI curves were transformed into a graph representation, incorporating the spatial, spectral, and temporal context. Graph convolutional operations were then used to learn the embedded representations and assign labels to the unlabeled points based on the labeled ones in the proximity. Further, a semi-supervised strategy was proposed where some initial feedback was employed to improve the generalizability of the model. Additionally, neighborhood-based feedback was also considered. The experiments using the VI curves collected over three farms in Israel covering wheat, potato, and barley crops illustrated the need for accounting the spatial non-stationarity in VI curve classification. The proposed dynamic feedback system and the graph-based strategy to consider spatial heterogeneity significantly improved the accuracy of the proposed framework. Additionally, the proposed reinforcement learning strategy ensures the dynamic refinement of model weights to facilitate the real-time applications even when the target data varies significantly. Although the proposed approach is generic, the end-to-end framework, as adopted in this research, is suitable for aerial or agricultural datasets. Hence, further fine tuning and remodeling may be required for non-agriculture or non-spatial datasets. However, the dynamic weight update may be adopted for any applications irrespective of the datasets.

Published
2024
Full Text
View/download PDF

14. DeepShadow: Neural Shape from Shadow

Author

Karnieli, Asaf, Fried, Ohad, and Hel-Or, Yacov

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

This paper presents DeepShadow, a one-shot method for recovering the depth map and surface normals from photometric stereo shadow maps. Previous works that try to recover the surface normals from photometric stereo images treat cast shadows as a disturbance. We show that the self and cast shadows not only do not disturb 3D reconstruction, but can be used alone, as a strong learning signal, to recover the depth map and surface normals. We demonstrate that 3D reconstruction from shadows can even outperform shape-from-shading in certain cases. To the best of our knowledge, our method is the first to reconstruct 3D shape-from-shadows using neural networks. The method does not require any pre-training or expensive labeled data, and is optimized during inference time., Comment: ECCV 2022. Project page available at https://asafkar.github.io/deepshadow/

Published
2022

17. Free-electron crystals for enhanced X-ray radiation

Author

Lee Wei Wesley Wong, Xihang Shi, Aviv Karnieli, Jeremy Lim, Suraj Kumar, Sergio Carbajo, Ido Kaminer, and Liang Jie Wong

Subjects
Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Abstract Bremsstrahlung—the spontaneous emission of broadband radiation from free electrons that are deflected by atomic nuclei—contributes to the majority of X-rays emitted from X-ray tubes and used in applications ranging from medical imaging to semiconductor chip inspection. Here, we show that the bremsstrahlung intensity can be enhanced significantly—by more than three orders of magnitude—through shaping the electron wavefunction to periodically overlap with atoms in crystalline materials. Furthermore, we show how to shape the bremsstrahlung X-ray emission pattern into arbitrary angular emission profiles for purposes such as unidirectionality and multi-directionality. Importantly, we find that these enhancements and shaped emission profiles cannot be attributed solely to the spatial overlap between the electron probability distribution and the atomic centers, as predicted by the paraxial and non-recoil theory for free electron light emission. Our work highlights an unprecedented regime of free electron light emission where electron waveshaping provides multi-dimensional control over practical radiation processes like bremsstrahlung. Our results pave the way towards greater versatility in table-top X-ray sources and improved fundamental understanding of quantum electron-light interactions.

Published
2024
Full Text
View/download PDF

18. SPDCinv: Inverse Quantum-Optical Design of High-Dimensional Qudits

Author

Rozenberg, Eyal, Karnieli, Aviv, Yesharim, Ofir, Foley-Comer, Joshua, Trajtenberg-Mills, Sivan, Freedman, Daniel, Bronstein, Alex M., and Arie, Ady

Subjects
Quantum Physics, Computer Science - Machine Learning
Abstract

Spontaneous parametric down-conversion in quantum optics is an invaluable resource for the realization of high-dimensional qudits with spatial modes of light. One of the main open challenges is how to directly generate a desirable qudit state in the SPDC process. This problem can be addressed through advanced computational learning methods; however, due to difficulties in modeling the SPDC process by a fully differentiable algorithm that takes into account all interaction effects, progress has been limited. Here, we overcome these limitations and introduce a physically-constrained and differentiable model, validated against experimental results for shaped pump beams and structured crystals, capable of learning every interaction parameter in the process. We avoid any restrictions induced by the stochastic nature of our physical model and integrate the dynamic equations governing the evolution under the SPDC Hamiltonian. We solve the inverse problem of designing a nonlinear quantum optical system that achieves the desired quantum state of down-converted photon pairs. The desired states are defined using either the second-order correlations between different spatial modes or by specifying the required density matrix. By learning nonlinear volume holograms as well as different pump shapes, we successfully show how to generate maximally entangled states. Furthermore, we simulate all-optical coherent control over the generated quantum state by actively changing the profile of the pump beam. Our work can be useful for applications such as novel designs of high-dimensional quantum key distribution and quantum information processing protocols. In addition, our method can be readily applied for controlling other degrees of freedom of light in the SPDC process, such as the spectral and temporal properties, and may even be used in condensed-matter systems having a similar interaction Hamiltonian., Comment: A code supporting the paper has been published (https://github.com/EyalRozenberg1/SPDCinv)

Published
2021

22. Imprinting the quantum statistics of photons on free electrons

Author

Dahan, Raphael, Gorlach, Alexey, Haeusler, Urs, Karnieli, Aviv, Eyal, Ori, Yousefi, Peyman, Segev, Mordechai, Arie, Ady, Eisenstein, Gadi, Hommelhoff, Peter, and Kaminer, Ido

Subjects
Quantum Physics, Physics - Accelerator Physics, Physics - Optics
Abstract

The fundamental interaction between free electrons and light stands at the base of both classical and quantum physics, with applications in free-electron acceleration, radiation sources, and electron microscopy. Yet, to this day, all experiments involving free-electron light interactions are fully explained by describing the light as a classical wave, disregarding its quantum nature. Here, we observe quantum statistics effects of photons on free-electron-light interactions. We demonstrate interactions passing continuously from Poissonian to super-Poissonian and up to thermal statistics, unveiling a surprising manifestation of Bohr's Correspondence Principle: the transition from quantum walk to classical random walk on the free-electron energy ladder. The electron walker serves as the probe in non-destructive quantum detection, measuring the photon-correlation ${g^{(2)} (0)}$ and higher-orders ${g^{(n)} (0)}$. Unlike conventional quantum-optical detectors, the electron can perform both quantum weak measurements and projective measurements by evolving into an entangled joint-state with the photons. Our findings suggest free-electron-based non-destructive quantum tomography of light, and constitute an important step towards combined attosecond-temporal and sub-A-spatial resolution microscopy.

Published
2021
Full Text
View/download PDF

23. Comment on: 'Nonlinear quantum effects in electromagnetic radiation of a vortex electron'

Author

Karnieli, Aviv, Remez, Roei, Kaminer, Ido, and Arie, Ady

Subjects
Quantum Physics
Abstract

This comment on the Phys. Rev. A paper "Nonlinear quantum effects in electromagnetic radiation of a vortex electron" by Karlovets and Pupasov-Maximov [Phys. Rev. A 103, 12214 (2021)] addresses their criticism of the combined experimental and theoretical study "Observing the quantum wave nature of free electrons through spontaneous emission" by Remez et al, published in Phys. Rev. Lett. [Phys. Rev. Lett. 123, 060401 (2019)]. We show, by means of simple optical arguments as well as numerical simulations, that the criticism raised by Karlovets and Pupasov-Maximov regarding the experimental regime reported by Remez et al is false. Further, we discuss a necessary clarification for the theoretical derivations presented by Karlovets and Pupasov-Maximov, as they only hold for a certain experimental situation where the final state of the emitting electron is observed in coincidence with the emitted photon - which is not the common scenario in cathodoluminescence. Upon lifting the concerns regarding the experimental regime reported by Remez et al, and explicitly clarifying the electron post-selection, we believe that the paper by Karlovets and Pupasov-Maximov may constitute a valuable contribution to the problem of spontaneous emission by shaped electron wavefunctions, as it presents new expressions for the emission rates beyond the ubiquitous paraxial approximation.

Published
2021
Full Text
View/download PDF

24. Inverse Design of Quantum Holograms in Three-Dimensional Nonlinear Photonic Crystals

Author

Rozenberg, Eyal, Karnieli, Aviv, Yesharim, Ofir, Trajtenberg-Mills, Sivan, Freedman, Daniel, Bronstein, Alex M., and Arie, Ady

Subjects
Quantum Physics, Computer Science - Machine Learning
Abstract

We introduce a systematic approach for designing 3D nonlinear photonic crystals and pump beams for generating desired quantum correlations between structured photon-pairs. Our model is fully differentiable, allowing accurate and efficient learning and discovery of novel designs., Comment: A supporting code will be published shortly

Published
2021
Full Text
View/download PDF

25. Ultrafast non-destructive measurement of the quantum state of light using free electrons

Author

Gorlach, Alexey, Karnieli, Aviv, Dahan, Raphael, Cohen, Eliahu, Pe'er, Avi, and Kaminer, Ido

Subjects
Quantum Physics
Abstract

Since the birth of quantum optics, the measurement of quantum states of nonclassical light has been of tremendous importance for advancement in the field. To date, conventional detectors such as photomultipliers, avalanche photodiodes, and superconducting nanowires, all rely at their core on linear excitation of bound electrons with light, posing fundamental restrictions on the detection. In contrast, the interaction of free electrons with light in the context of quantum optics is highly nonlinear and offers exciting possibilities. The first experiments that promoted this direction appeared over the past decade as part of photon-induced nearfield electron microscopy (PINEM), wherein free electrons are capable of high-order multi-photon absorption and emission. Here we propose using free electrons for quantum-optical detection of the complete quantum state of light. We show how the precise control of the electron before and after its interaction with quantum light enables to extract the photon statistics and implement full quantum state tomography using PINEM. This technique can reach sub-attosecond time resolutions, measure temporal coherence of any degree (e.g., g(1), g(2)), and simultaneously detect large numbers of photons with each electron. Importantly, the interaction of the electron with light is non-destructive, thereby leaving the photonic state (modified by the interaction) intact, which is conceptually different from conventional detectors. By using a pulse of multiple electrons, we envision how PINEM quantum detectors could achieve a single-shot measurement of the complete state of quantum light, even for non-reproducible emission events. Altogether, our work paves the way to novel kinds of photodetectors that utilize the ultrafast duration, high nonlinearity, and non-destructive nature of electron-light interactions., Comment: 5 figs, 20 pages + Supplementary Material

Published
2020

26. Super- and subradiance by entangled free particles

Author

Karnieli, Aviv, Rivera, Nicholas, Arie, Ady, and Kaminer, Ido

Subjects
Quantum Physics
Abstract

When multiple quantum emitters radiate, their emission rate may be enhanced or suppressed due to collective interference in a process known as super- or subradiance. Such processes are well-known to occur also in light emission by free charged particles. To date, all experimental and theoretical studies of super- and subradiance in these systems involved the classical correlations between the emitters. However, dependence on quantum correlations, such as entanglement between different emitting particles, has not been studied. Recent advances in coherent-shaping of free-electron wavefunctions motivate the investigation of such quantum regimes of super- and subradiance. In this Letter, we show how a pair of coincident path-entangled electrons can demonstrate either super- or subradiant light emission, depending on the two-particle wavefunction. By choosing different free-electron Bell-states, the spectrum and emission pattern of the light can be reshaped, in a manner that cannot be accounted for by a classical mixed state. We show these results for light emission in any optical medium, and discuss their generalization to many-body quantum states. Our findings suggest that light emission can be sensitive to the explicit quantum state of the emitting matter wave, and possibly serve as a non-destructive measurement scheme for measuring the quantum state of many-body systems., Comment: 12 pages, 2 figures

Published
2020
Full Text
View/download PDF

27. Shaping Quantum Photonic States Using Free Electrons

Author

Hayun, Adi Ben, Reinhardt, Ori, Nemirovsky, Jonathan, Karnieli, Aviv, Rivera, Nicholas, and Kaminer, Ido

Subjects
Quantum Physics
Abstract

It is a long-standing goal to generate robust deterministic states of light with unique quantum properties, such as squeezing, sub-Poissonian statistics and entanglement. It is of interest to consider whether such quantum states of light could be generated by exploiting interactions with free electrons, going beyond their already ubiquitous use in generating classical light. This question is motivated by developments in electron microscopy, which present a new platform for manipulating photons through their interaction with quantum free electrons. Here, we explore the shaping of photon statistics using the quantum interactions of free electrons with photons in optical cavities. We find a variety of quantum states of light that can be generated by a judicious choice of the input light and electron states. For example, we show how shaping an electron into an energy comb can provide an implementation of a photon displacement operation, allowing, for instance, the generation of displaced Fock and displaced squeezed states. We also show how one can generate a desired Fock state by repeated interactions of electrons with a cavity, followed by measurements. We develop the underlying theory of the interaction of both a single and many consecutive electrons with a common cavity mode. Looking forward, by exploiting the degrees of freedom of arbitrary electron-photon quantum states, we may achieve complete control over the statistics and correlations of output photonic states, leading to the generation of novel quantum states of light.

Published
2020
Full Text
View/download PDF

28. Light emission is fundamentally tied to the quantum coherence of the emitting particle

Author

Karnieli, Aviv, Rivera, Nicholas, Arie, Ady, and Kaminer, Ido

Subjects
Quantum Physics
Abstract

Coherent emission of light by free charged particles is ubiquitous in many areas of physics and engineering, with the light's properties believed to be successfully captured by classical electromagnetism in all relevant experimental settings. The advent of interactions between light and free quantum matter waves brought about fundamental questions regarding the role of the particle wavefunction. Here we show that even in seemingly classical experimental regimes, light emission is fundamentally tied to quantum properties of the emitting particles, such as their quantum coherence and correlations. By employing quantum electrodynamics, we unveil the role of the particle's coherent momentum uncertainty, without which decoherence of light becomes dominant. As an example, we consider Cherenkov radiation, envisioned for almost a century as a shockwave of light. We find instead that the shockwave's duration is fundamentally bound from below by the particle's coherent momentum uncertainty due to the underlying entanglement between the particle and light. This quantum optical paradigm opens new capabilities in analytical electron microscopy, enabling the measurement of quantum correlations of shaped electron wavepackets. Our findings also have applications for Cherenkov detectors in particle physics. For example, by measuring spectral photon autocorrelations, one can unveil the particle's wavefunction size, shape and coherence. Such schemes are especially intriguing for many high-energy particles, where other techniques are not available.

Published
2020
Full Text
View/download PDF

29. Adiabatic geometric phase in fully nonlinear three-wave mixing

Author

Li, Yongyao, Yesharim, Ofir, Hurvitz, Inbar, Karnieli, Aviv, Fu, Shenhe, Porat, Gil, and Arie, Ady

Subjects
Physics - Optics
Abstract

In a nonlinear three-wave mixing process, the interacting waves can accumulate an adiabatic geometric phase (AGP) if the nonlinear coefficient of the crystal is modulated in a proper manner along the nonlinear crystal. This concept was studied so far only for the case in which the pump wave is much stronger than the two other waves, hence can be assumed to be constant. Here we extend this analysis for the fully nonlinear process, in which all three waves can be depleted and we show that the sign and magnitude of the AGP can be controlled by the period, phase and duty cycle of the nonlinear modulation pattern. In this fully nonlinear interaction, all the states of the system can be mapped onto a closed surface. Specifically, we study a process in which the eigenstate of the system follows a circular rotation on the surface. Our analysis reveals that the AGP equals to the difference between the total phase accumulated along the circular trajectory and that along its vertical projection, which is universal for the undepleted (linear) and depleted (nonlinear) cases. Moreover, the analysis reveals that the AGPs in the processes of sum-frequency generation and difference-frequency generation have opposite chirality. Finally, we utilize the AGP in the fully nonlinear case for splitting the beam into different diffraction orders in the far field., Comment: 9 pages, 36 references, 7 figures. Published on Physical Review A

Published
2020
Full Text
View/download PDF

31. DETECTION OF PHYTOGEOGRAPHIC INDICATORS WITH REMOTE SENSING AND GEOARCHAEOLOGY FOR DEVELOPMENT OF A LONG-TERM CLIMATE MONITORING STATION IN ISRAEL

Author

N. Manspeizer and A. Karnieli

Subjects
Technology, Engineering (General). Civil engineering (General), TA1-2040, Applied optics. Photonics, TA1501-1820
Abstract

The Mediterranean basin is a strong candidate for monitoring climate change successfully, a priority of UN SDG 13, because of its long settlement history. Human-environmental contact has typically hindered monitoring efforts because the natural indicators that enable dependable monitoring have been altered anthropogenically. This research describes a two-step process which turns that synanthropism into an advantage through geoarchaeology, remote sensing, GIS, meteorology, and floristic classification. First, archaeological survey data were employed in a semi-arid region of Israel to identify areas of more and less intensive land-use over 2300 years. Trend surfaces were derived in GIS from ancient periods of most intense monoculture agriculture (Hellenistic, Byzantine, and Ottoman). 2020 land-cover was classified using VENμS satellite wet / dry season NDVI imagery and an airborne LiDAR canopy height model. This was reclassed after fieldwork to three broad land-cover classes and cross-tabulated with the 2300-year land-use intensity model in GIS. The results indicate a land-use legacy whereby woody perennial species are more abundant where land-use was cumulatively less intense. Second, unmanned aerial vehicle surveys were conducted in these areas of less-intense land-use. There, on lightly grazed lands where woody encroachment occurs but chamaephytes regenerate due to the grazing, microplots were established. Phanerophyte and chamaephyte shrubs were identified based on Raunkiaer type and the species associated with chorotype (geographic origin). This was compared with aridity index values derived for the study area between 2010-2022. The study provides a prototype, using dependable phytogeographic indicators, that may be developed into a long-term climate monitoring station (LTCMS).

Published
2023
Full Text
View/download PDF

33. Multi-Sensor Classification Framework of Urban Vegetation for Improving Ecological Services Management

Author

Arti Tiwari, Oz Kira, Julius Bamah, Hagar Boneh, and Arnon Karnieli

Subjects
vegetation, OBIA, PLS-DA, LiDAR, hyperspectral data, high-resolution orthophoto, Science
Abstract

Recent climatic changes have profoundly impacted the urban microclimate, exposing city dwellers to harsh living conditions. One effective approach to mitigating these events involves incorporating more green infrastructure into the cityscape. The ecological services provided by urban vegetation play a crucial role in enhancing the sustainability and livability of cities. However, monitoring urban vegetation and accurately estimating its status pose challenges due to the heterogeneous nature of the urban environment. In response to this, the current study proposes utilizing a remote sensing-based classification framework to enhance data availability, thereby improving practices related to urban vegetation management. The aim of the current research is to explore the spatial pattern of vegetation and enhance the classification of tree species within diverse and complex urban environments. This study combines various remote sensing observations to enhance classification capabilities. High-resolution colored rectified aerial photographs, LiDAR-derived products, and hyperspectral data are merged and analyzed using advanced classifier methods, specifically partial least squares-discriminant analysis (PLS-DA) and object-based image analysis (OBIA). The OBIA method demonstrates an impressive overall accuracy of 95.30%, while the PLS-DA model excels with a remarkable overall accuracy of 100%. The findings validate the efficacy of incorporating OBIA, aerial photographs, LiDAR, and hyperspectral data in improving tree species classification and mapping within the context of PLS-DA. This classification framework holds significant potential for enhancing management practices and tools, thereby optimizing the ecological services provided by urban vegetation and fostering the development of sustainable cities.

Published
2024
Full Text
View/download PDF

34. Universal and Ultrafast Quantum Computation Based on Free-Electron-Polariton Blockade

Author

Aviv Karnieli, Shai Tsesses, Renwen Yu, Nicholas Rivera, Ady Arie, Ido Kaminer, and Shanhui Fan

Subjects
Physics, QC1-999, Computer software, QA76.75-76.765
Abstract

Cavity QED, wherein a quantum emitter is coupled to electromagnetic cavity modes, is a powerful platform for implementing quantum sensors, memories, and networks. However, due to the fundamental trade-off between gate fidelity and execution time, as well as limited scalability, the use of cavity QED for quantum computation was overtaken by other architectures. Here, we introduce a new element into cavity QED—a free charged particle, acting as a flying qubit. Using free electrons as a specific example, we demonstrate that our approach enables ultrafast, deterministic, and universal discrete-variable quantum computation in a cavity-QED-based architecture, with potentially improved scalability. Our proposal hinges on a novel excitation blockade mechanism in a resonant interaction between a free-electron and a cavity polariton. This nonlinear interaction is faster by several orders of magnitude with respect to current photon-based cavity-QED gates, enjoys wide tunability and can demonstrate fidelities close to unity. Furthermore, our scheme is ubiquitous to any cavity nonlinearity, either due to light-matter coupling as in the Jaynes-Cummings model or due to photon-photon interactions as in a Kerr-type many-body system. In addition to promising advancements in cavity-QED quantum computation, our approach paves the way towards ultrafast and deterministic generation of highly entangled photonic graph states and is applicable to other quantum technologies involving cavity QED.

Published
2024
Full Text
View/download PDF

36. Burnout in Israeli medical students: a national survey

Author

Peter Gilbey, Mandy Moffat, Adi Sharabi-Nov, Omri Cohen, Galit Neufeld Kroszynski, Orit Karnieli-Miller, Roni Gillis, Jacob Urkin, and Khen Moscovici

Subjects
Burnout, Medical student, Undergraduate, Israel, Emotional Exhaustion, Cynicism, Special aspects of education, LC8-6691, Medicine
Abstract

Abstract Introduction Professional burnout is characterized by loss of enthusiasm for work, cynicism, and a low sense of personal efficacy. Burnout may adversely affect medical professionalism. Burnout is common in clinicians and varying rates have been reported in medical students. No data exist regarding the prevalence of burnout among Israeli medical students. The aims of this study were to assess the rate of burnout in Israeli medical students and to identify students who were particularly susceptible to burnout. Methods A cross-sectional questionnaire design was employed, gathering data from medical students in all years of study across three medical schools. Burnout was measured using the Maslach Burnout Inventory Student Survey (MBI-SS), translated into Hebrew. Results Of the 2160 students in the participating medical schools, 966 (44.7%) completed MBI-SS and demographic questionnaires. The overall burnout rate was 50.6%. Multivariate logistic regression analysis yielded that female gender, age under 25, advanced year of study, studying at a specific medical school and not being a parent are all significantly correlated with higher levels of burnout. Conclusions A high rate of burnout was found. The identification of young women who are not parents during advanced years of studies as being at-risk is important, in order to guide the development of burnout prevention interventions.

Published
2023
Full Text
View/download PDF

46. Core Experiences of Parents of Children with Autism during the COVID-19 Pandemic Lockdown

Author

Tokatly Latzer, Itay, Leitner, Yael, and Karnieli-Miller, Orit

Abstract

The lockdown that was imposed by governments as part of the attempt to contain the COVID-19 pandemic included extreme measures, such as home confinement and the shutting down of special education systems. Our aim was to learn about the core experiences of parents of children with autism during this significant life disturbance. Thirty-one parents of 25 children with autism participated in semi-structured telephone interviews which were transcribed verbatim and underwent a qualitative, immersion/crystallization analysis. The analysis was conducted in an iterative consensus-building process to identify parents' experiences, concerns, challenges, coping strategies, and perceived needs during the lockdown. The main themes that emerged related to the various parental concerns; the major difficulties encountered during this unique time, the functional, social, and behavioral implications the lockdown had on these children; and the manner in which the parents coped as an indication of their resourcefulness and outlook. Our findings broaden the insight into the underlying elements of the hardships and gains experienced by children with autism and their parents in times of significant life adversity. Programs in such times should be directed at supporting and guiding parents on how to better accommodate to the situation, thereby optimizing their coping strategies and resilience.

Published
2021
Full Text
View/download PDF

47. Perspectives on the cost of goods for hPSC banks for manufacture of cell therapies

Author

Jung-Hyun Kim, Eihachiro Kawase, Kapil Bharti, Ohad Karnieli, Yuji Arakawa, and Glyn Stacey

Subjects
Medicine
Abstract

This report summarizes key issues contributing to the cost of preparing human pluripotent stem cell lines for use in cell therapy manufacturing based on discussion between stem cell banking experts from ten countries at a workshop session on ‘cost of goods’ for human pluripotent stem cell banking organized by the International Stem Cell Banking Initiative (ISCBI) held at the Korea National Institutes of Health in Korea (25th September 2019). In this report, we also build on the workshop discussion and highlight and discuss the full range of costs and unexpected challenges on resources for the delivery of stocks of hPSCs suitable for use as starting materials in the manufacture of stem cell-based medicines. The experiences of global leaders from different national resource centers highlight issues to consider in cost management and the possibilities for reducing costs while moving into the clinical application stage.

Published
2022
Full Text
View/download PDF

48. Spatial and spectral analysis of fairy circles in Namibia on a landscape scale using satellite image processing and machine learning analysis

Author

Klil Noy, Micha Silver, Ondrej Pesek, Hezi Yizhaq, Eugene Marais, and Arnon Karnieli

Subjects
CNN model, Spectral indices, Texture variables, Spatial autocorrelation, Physical geography, GB3-5030, Environmental sciences, GE1-350
Abstract

Fairy circles (FCs) are a unique phenomenon characterized by circular patches, 4–10 m in diameter, of bare soil within a vegetated matrix. This project aimed to study the spatial and spectral characteristics of FCs on a landscape scale in Namibia. The specific objectives of this research are (1) processing satellite observations to explore the FCs distributions by applying statistical analysis and deep machine learning algorithms; (2) analyzing the FCs' geometric attributes to retrieve their spatial patterns regarding topographic features nearby. The FCs were classified within 25 km2 by processing 15 input layers through a convolutional neural network (CNN) model. The layers include four WorldView2 spectral bands, derived vegetation, biocrust, and mineral indices, and textural characteristics. The FCs’ geometry was extracted, and spatial autocorrelation was performed. By labeling 1600 FCs and using the CNN model, 14,536 FCs were mapped with 0.97% accuracy and a binary cross-entropy loss function value of only 0.01. Field measurements and laboratory analysis justified the need to use spectral indices for the model. Unique elongated FCs, clustered by hotspot analysis, were quantified and mapped along watercourses in alluvial fans with notable connectivity. On a landscape scale that has not yet been studied, spatial and spectral analyses became possible only with valuable remote sensing retrievals, deep statistical analysis, and machine learning algorithms.

Published
2023
Full Text
View/download PDF

49. Food-seeking behavior is triggered by skin ultraviolet exposure in males

Author

Parikh, Shivang, Parikh, Roma, Michael, Keren, Bikovski, Lior, Barnabas, Georgina, Mardamshina, Mariya, Hemi, Rina, Manich, Paulee, Goldstein, Nir, Malcov-Brog, Hagar, Ben-Dov, Tom, Glaich, Ohad, Liber, Daphna, Bornstein, Yael, Goltseker, Koral, Ben-Bezalel, Roy, Pavlovsky, Mor, Golan, Tamar, Spitzer, Liron, Matz, Hagit, Gonen, Pinchas, Percik, Ruth, Leibou, Lior, Perluk, Tomer, Ast, Gil, Frand, Jacob, Brenner, Ronen, Ziv, Tamar, Khaled, Mehdi, Ben-Eliyahu, Shamgar, Barak, Segev, Karnieli-Miller, Orit, Levin, Eran, Gepner, Yftach, Weiss, Ram, Pfluger, Paul, Weller, Aron, and Levy, Carmit

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results