14 results on '"Pasquazi A"'
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2. Resonant Fully Dielectric Metasurfaces for Ultrafast Terahertz Pulse Generation
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Peters Luke, Rocco Davide, Olivieri Luana, Leon Unai Arregui, Cecconi Vittorio, Carletti Luca, Gigli Carlo, Valle Giuseppe Della, Cutrona Antonio, Gongora Juan Sebastian Totero, Leo Giuseppe, Pasquazi Alessia, De Angelis Costantino, and Peccianti Marco
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Physics ,QC1-999 - Abstract
In the framework of optical frequency conversion, metasurfaces have elevated the potential for effective interfacial nonlinear coefficients through various modes of field localization. For the generation of pulsed ultrafast terahertz (THz) signals, metasurfaces present a viable alternative in the domain of surface-scalable sources driven by low-power oscillators (using nJ pulses). However, recent innovations have predominantly relied on surface plasmons (metals) and, more broadly, on excitations within non-transparency windows—conditions that typically impose limitations on applications and the choice of platforms. Here, we demonstrate the utilization of a fully-dielectric, fully transparent semiconductor that exploits surface-nano-structure-mediated resonances alongside its inherent quadratic nonlinear response. Our system exhibits a remarkable 40-fold efficiency enhancement in comparison to the non-decorated substrate.
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- 2024
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3. Multifrequency sources of quantum correlated photon pairs on-chip: a path toward integrated Quantum Frequency Combs
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Caspani Lucia, Reimer Christian, Kues Michael, Roztocki Piotr, Clerici Matteo, Wetzel Benjamin, Jestin Yoann, Ferrera Marcello, Peccianti Marco, Pasquazi Alessia, Razzari Luca, Little Brent E., Chu Sai T., Moss David J., and Morandotti Roberto
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Physics ,QC1-999 - Abstract
Recent developments in quantum photonics have initiated the process of bringing photonic-quantumbased systems out-of-the-lab and into real-world applications. As an example, devices to enable the exchange of a cryptographic key secured by the laws of quantum mechanics are already commercially available. In order to further boost this process, the next step is to transfer the results achieved by means of bulky and expensive setups into miniaturized and affordable devices. Integrated quantum photonics is exactly addressing this issue. In this paper, we briefly review the most recent advancements in the generation of quantum states of light on-chip. In particular, we focus on optical microcavities, as they can offer a solution to the problem of low efficiency that is characteristic of the materials typically used in integrated platforms. In addition, we show that specifically designed microcavities can also offer further advantages, such as compatibility with telecom standards (for exploiting existing fibre networks) and quantum memories (necessary to extend the communication distance), as well as giving a longitudinal multimode character for larger information transfer and processing. This last property (i.e., the increased dimensionality of the photon quantum state) is achieved through the ability to generate multiple photon pairs on a frequency comb, corresponding to the microcavity resonances. Further achievements include the possibility of fully exploiting the polarization degree of freedom, even for integrated devices. These results pave the way for the generation of integrated quantum frequency combs that, in turn, may find important applications toward the realization of a compact quantum-computing platform.
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- 2016
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4. Recent advances on time-stretch dispersive Fourier transform and its applications
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Thomas Godin, Lynn Sader, Anahita Khodadad Kashi, Pierre-Henry Hanzard, Ammar Hideur, David J. Moss, Roberto Morandotti, Goery Genty, John M. Dudley, Alessia Pasquazi, Michael Kues, and Benjamin Wetzel
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Ultrafast photonics ,Nonlinear fiber optics ,Laser systems ,Ultrafast imaging ,Quantum measurements ,Physics ,QC1-999 - Abstract
The need to measure high repetition rate ultrafast processes cuts across multiple areas of science. The last decade has seen tremendous advances in the development and application of new techniques in this field, as well as many breakthrough achievements analyzing non-repetitive optical phenomena. Several approaches now provide convenient access to single-shot optical waveform characterization, including the dispersive Fourier transform (DFT) and time-lens techniques, which yield real-time ultrafast characterization in the spectral and temporal domains, respectively. These complementary approaches have already proven to be highly successful to gain insight into numerous optical phenomena including the emergence of extreme events and characterizing the complexity of laser evolution dynamics. However, beyond the study of these fundamental processes, real-time measurements have also been driven by particular applications ranging from spectroscopy to velocimetry, while shedding new light in areas spanning ultrafast imaging, metrology or even quantum science. Here, we review a number of landmark results obtained using DFT-based technologies, including several recent advances and key selected applications.
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- 2022
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5. Optical multi-stability in a nonlinear high-order microring resonator filter
- Author
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Li Jin, Luigi Di Lauro, Alessia Pasquazi, Marco Peccianti, David J. Moss, Roberto Morandotti, Brent E. Little, and Sai Tak Chu
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Applied optics. Photonics ,TA1501-1820 - Abstract
We theoretically analyze and experimentally demonstrate optical bi-stability and multi-stability in an integrated nonlinear high-order microring resonator filter based on high-index contrast doped silica glass. We use a nonlinear model accounting for both the Kerr and thermal effects to analyze the instability behavior of the coupled-resonator based filter. The model also accurately predicts the multi-stable behavior of the filter when the input frequency is slightly detuned. To understand the role of the intracavity power distribution, we investigate the detuning of the individual rings of the filter from the optical response with a pump–probe experiment. Such a measurement is performed scanning the filter with a low-power probe beam tuned a few free spectral ranges away from the resonance where the pump is coupled. A comprehensive understanding of the relationship between the nonlinear behavior and the intracavity power distribution for the high-order microring resonator filter will help the design and implementation of future all-optical switching systems using this type of filter.
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- 2020
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6. Route to Intelligent Imaging Reconstruction via Terahertz Nonlinear Ghost Imaging
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Juan S. Totero Gongora, Luana Olivieri, Luke Peters, Jacob Tunesi, Vittorio Cecconi, Antonio Cutrona, Robyn Tucker, Vivek Kumar, Alessia Pasquazi, and Marco Peccianti
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terahertz ,nonlinear optical conversion ,complex optical systems ,adaptive imaging ,single-pixel imaging ,surface nonlinear photonics ,Mechanical engineering and machinery ,TJ1-1570 - Abstract
Terahertz (THz) imaging is a rapidly emerging field, thanks to many potential applications in diagnostics, manufacturing, medicine and material characterisation. However, the relatively coarse resolution stemming from the large wavelength limits the deployment of THz imaging in micro- and nano-technologies, keeping its potential benefits out-of-reach in many practical scenarios and devices. In this context, single-pixel techniques are a promising alternative to imaging arrays, in particular when targeting subwavelength resolutions. In this work, we discuss the key advantages and practical challenges in the implementation of time-resolved nonlinear ghost imaging (TIMING), an imaging technique combining nonlinear THz generation with time-resolved time-domain spectroscopy detection. We numerically demonstrate the high-resolution reconstruction of semi-transparent samples, and we show how the Walsh–Hadamard reconstruction scheme can be optimised to significantly reduce the reconstruction time. We also discuss how, in sharp contrast with traditional intensity-based ghost imaging, the field detection at the heart of TIMING enables high-fidelity image reconstruction via low numerical-aperture detection. Even more striking—and to the best of our knowledge, an issue never tackled before—the general concept of “resolution” of the imaging system as the “smallest feature discernible” appears to be not well suited to describing the fidelity limits of nonlinear ghost-imaging systems. Our results suggest that the drop in reconstruction accuracy stemming from non-ideal detection conditions is complex and not driven by the attenuation of high-frequency spatial components (i.e., blurring) as in standard imaging. On the technological side, we further show how achieving efficient optical-to-terahertz conversion in extremely short propagation lengths is crucial regarding imaging performance, and we propose low-bandgap semiconductors as a practical framework to obtain THz emission from quasi-2D structures, i.e., structure in which the interaction occurs on a deeply subwavelength scale. Our results establish a comprehensive theoretical and experimental framework for the development of a new generation of terahertz hyperspectral imaging devices.
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- 2020
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7. Nonlocal bonding of a soliton and a blue-detuned state in a microcomb laser
- Author
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Antonio Cutrona, Vittorio Cecconi, Pierre H. Hanzard, Maxwell Rowley, Debayan Das, Andrew Cooper, Luke Peters, Luana Olivieri, Benjamin Wetzel, Roberto Morandotti, Sai T. Chu, Brent E. Little, David J. Moss, Juan S. Totero Gongora, Marco Peccianti, and Alessia Pasquazi
- Subjects
Astrophysics ,QB460-466 ,Physics ,QC1-999 - Abstract
Abstract Laser cavity-solitons can appear in a microresonator-filtered laser when judiciously balancing the slow nonlinearities of the system. Under certain conditions, such optical states can be made to self-emerge and recover spontaneously, and the understanding of their robustness is critical for practical applications. Here, we study the formation of a bonded state comprising a soliton and a blue-detuned continuous wave, whose coexistence is mediated by dispersion in the nonlinear refractive index. Our real-time dispersive Fourier transform measurements, supported by comprehensive theoretical analysis, reveal the presence of an elastic bonding between the two states, resulting in an enhancement of the soliton’s robustness.
- Published
- 2023
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8. Nonlinear field-control of terahertz waves in random media for spatiotemporal focusing [version 3; peer review: 2 approved]
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Alessia Pasquazi, Vivek Kumar, Marco Peccianti, Juan Sebastian Totero Gongora, and Vittorio Cecconi
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Scattering ,terahertz ,time-domain spectroscopy ,random medium ,spatiotemporal focusing ,superfocusing ,eng ,Science ,Social Sciences - Abstract
Controlling the transmission of broadband optical pulses in scattering media is a critical open challenge in photonics. To date, wavefront shaping techniques at optical frequencies have been successfully applied to control the spatial properties of multiple-scattered light. However, a fundamental restriction in achieving an equivalent degree of control over the temporal properties of a broadband pulse is the limited availability of experimental techniques to detect the coherent properties (i.e., the spectral amplitude and absolute phase) of the transmitted field. Terahertz experimental frameworks, on the contrary, enable measuring the field dynamics of broadband pulses at ultrafast (sub-cycle) time scales directly. In this work, we provide a theoretical/numerical demonstration that, within this context, complex scattering can be used to achieve spatio-temporal control of instantaneous fields and manipulate the temporal properties of single-cycle pulses by solely acting on spatial degrees of freedom of the illuminating field. As direct application scenarios, we demonstrate spatio-temporal focusing, chirp compensation, and control of the carrier-envelope-phase (CEP) of a CP-stable, transform-limited THz pulse.
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- 2023
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9. Nonlinear field-control of terahertz waves in random media for spatiotemporal focusing [version 2; peer review: 2 approved]
- Author
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Alessia Pasquazi, Vivek Kumar, Marco Peccianti, Juan Sebastian Totero Gongora, and Vittorio Cecconi
- Subjects
Scattering ,terahertz ,time-domain spectroscopy ,random medium ,spatiotemporal focusing ,superfocusing ,eng ,Science ,Social Sciences - Abstract
Controlling the transmission of broadband optical pulses in scattering media is a critical open challenge in photonics. To date, wavefront shaping techniques at optical frequencies have been successfully applied to control the spatial properties of multiple-scattered light. However, a fundamental restriction in achieving an equivalent degree of control over the temporal properties of a broadband pulse is the limited availability of experimental techniques to detect the coherent properties (i.e., the spectral amplitude and absolute phase) of the transmitted field. Terahertz experimental frameworks, on the contrary, enable measuring the field dynamics of broadband pulses at ultrafast (sub-cycle) time scales directly. In this work, we provide a theoretical/numerical demonstration that, within this context, complex scattering can be used to achieve spatio-temporal control of instantaneous fields and manipulate the temporal properties of single-cycle pulses by solely acting on spatial degrees of freedom of the illuminating field. As direct application scenarios, we demonstrate spatio-temporal focusing, chirp compensation, and control of the carrier-envelope-phase (CEP) of a CP-stable, transform-limited THz pulse.
- Published
- 2022
- Full Text
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10. Terahertz emission mediated by ultrafast time-varying metasurfaces
- Author
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J. Tunesi, L. Peters, J. S. Totero Gongora, L. Olivieri, A. Fratalocchi, A. Pasquazi, and M. Peccianti
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Physics ,QC1-999 - Abstract
Systems with ultrafast time-varying dielectric properties represent an emerging physical framework. We demonstrate here the observation of subcycle dynamics interacting directly with an electromagnetic source comprised of morphologically constrained photoexcited carriers in a surface nanostructure. A transition to a metallic metasurface state occurs on time scales faster than the terahertz-field period, inducing large nonlinear ultrafast phase shifts in the terahertz emission and exposing an interesting physical setting.
- Published
- 2021
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11. Customizing supercontinuum generation via on-chip adaptive temporal pulse-splitting
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Benjamin Wetzel, Michael Kues, Piotr Roztocki, Christian Reimer, Pierre-Luc Godin, Maxwell Rowley, Brent E. Little, Sai T. Chu, Evgeny A. Viktorov, David J. Moss, Alessia Pasquazi, Marco Peccianti, and Roberto Morandotti
- Subjects
Science - Abstract
Controlling complex properties of optical systems, like the output of nonlinear light sources, is increasingly important for applications. Here, Wetzel et al. use an actively-controlled photonic chip to prepare patterns of femtosecond laser pulses used for tailoring supercontinuum generation.
- Published
- 2018
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12. Turing patterns in a fiber laser with a nested microresonator: Robust and controllable microcomb generation
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Hualong Bao, Luana Olivieri, Maxwell Rowley, Sai T. Chu, Brent E. Little, Roberto Morandotti, David J. Moss, Juan Sebastian Totero Gongora, Marco Peccianti, and Alessia Pasquazi
- Subjects
Physics ,QC1-999 - Abstract
Microcombs based on Turing patterns have been extensively studied in configurations that can be modeled by the Lugiato-Lefever equation. Typically, such schemes are implemented experimentally by resonant coupling of a continuous wave laser to a Kerr microcavity in order to generate highly coherent and robust waves. Here, we study the formation of such patterns in a system composed of a microresonator nested in an amplifying laser cavity, a scheme recently used to demonstrate laser cavity solitons with high optical efficiency and easy repetition rate control. Utilizing this concept, we study different regimes of Turing patterns, unveiling their formation dynamics and demonstrating their controllability and robustness. By conducting a comprehensive modulational instability study with a mean-field model of the system, we explain the pattern formation in terms of its evolution from background noise, paving the way towards complete self-starting operation. Our theoretical and experimental paper provides a clear pathway for repetition rate control of these waves over both fine (Megahertz) and large (Gigahertz) scales, featuring a fractional frequency nonuniformity better than 7×10^{−14} with a 100-ms time gate and without the need for active stabilization.
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- 2020
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13. Toward On-Chip Phase-Sensitive Optical Temporal Waveform Measurements
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Alessia Pasquazi, José Azana, Marco Peccianti, David J. Moss, and Roberto Morandotti
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Coherent detection ,nonlinear optics ,optical waveguides ,ultrafast pulse measurement ,Applied optics. Photonics ,TA1501-1820 ,Optics. Light ,QC350-467 - Abstract
This review summarizes the results obtained in 2011 toward the development of an “integrated optical oscilloscope,” encompassing research on new technologies for the measurement of ultrafast optical pulses in both amplitude and phase through the use of integrated devices, some of which are compatible with electronic circuit technology (CMOS).
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- 2012
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14. Nonlinear Disorder Mapping Through Three-Wave Mixing
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Alessia Pasquazi, Alessandro Busacca, Salvatore Stivala, Roberto Morandotti, and Gaetano Assanto
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Second-harmonic generation ,random quasi phase matching ,image analysis ,Applied optics. Photonics ,TA1501-1820 ,Optics. Light ,QC350-467 - Abstract
We implement a simple and powerful approach to characterize the domain distribution in the bulk of quadratic ferroelectric crystals via far-field second-harmonic spectroscopy. The approach is demonstrated in a lithium tantalate sample with periodic electric field poling and random mark-to-space ratio.
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- 2010
- Full Text
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