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47 results on '"Jahromi, Ali. K."'

1. Broadband Omni-resonant Coherent Perfect Absorption in Graphene

Author

Jahromi, Ali K., Villinger, Massimo L., Halawany, Ahmed El, Shabahang, Soroush, Kondakci, H. Esat, Perlstein, Joshua D., and Abouraddy, Ayman F.

Subjects
Physics - Optics
Abstract

Coherent perfect absorption (CPA) refers to interferometrically induced complete absorption of incident light by a partial absorber independently of its intrinsic absorption (which may be vanishingly small) or its thickness. CPA is typically realized in a resonant device, and thus cannot be achieved over a broad continuous spectrum, which thwarts its applicability to photodetectors and solar cells, for example. Here, we demonstrate broadband omni-resonant CPA by placing a thin weak absorber in a planar cavity and pre-conditioning the incident optical field by introducing judicious angular dispersion. We make use of monolayer graphene embedded in silica as the absorber and boost its optical absorption from ~1.6% to ~60% over a bandwidth of ~70 nm in the visible. Crucially, an analytical model demonstrates that placement of the graphene monolayer at a peak in the cavity standing-wave field is not necessary to achieve CPA, contrary to conventional wisdom.

Published
2021

2. Coherent perfect absorption in resonant materials

Author

Shabahang, S., Jahromi, Ali. K., Pye, L. N., Perlstein, J. D., Villinger, M. L., and Abouraddy, Ayman F.

Subjects
Physics - Optics
Abstract

Coherent perfect absorption (CPA) is an interferometric effect that guarantees full absorption in a lossy layer independently of its intrinsic losses. To date, it has been observed only at a single wavelength or narrow bandwidths, whereupon wavelength-dependent absorption can be ignored. Here we produce CPA over a bandwidth of ~ 60 nm in a 2-um-thick polymer film with a low-doping concentration of an organic laser dye. A planar cavity is designed with a spectral `dip' to accommodate the dye resonant linewidth, and CPA is thus achieved even at its absorption edges. This approach allows realizing strong absorption in laser dyes - and resonant materials in general - independently of the intrinsic absorption levels, with a at spectral profile and without suffering absorption quenching due to high doping levels.

Published
2020

3. Diffusing wave spectroscopy: a unified treatment on temporal sampling and speckle ensemble methods

Author

Xu, Jian, Jahromi, Ali K., and Yang, Changhuei

Subjects
Physics - Optics, Physics - Medical Physics
Abstract

Diffusing wave spectroscopy (DWS) is a well-known set of methods to measure the temporal dynamics of dynamic samples. In DWS, dynamic samples scatter the incident coherent light, and the information of the temporal dynamics is encoded in the scattered light. To record and analyze the light signal, there exist two types of methods - temporal sampling methods and speckle ensemble methods. Temporal sampling methods, including diffuse correlation spectroscopy (DCS), use one or multiple large bandwidth detectors to well sample and analyze the temporal light signal to infer the sample temporal dynamics. Speckle ensemble methods, including speckle visibility spectroscopy (SVS), use a high-pixel-count camera sensor to capture a speckle pattern and use the speckle contrast to infer sample temporal dynamics. In this paper, we theoretically and experimentally demonstrate that the decorrelation time ({\tau}) measurement accuracy or SNR of the two types of methods has a unified and similar fundamental expression based on the number of independent observables (NIO) and the photon flux. Given a time measurement duration, NIO in temporal sampling methods is constrained by the measurement duration, while speckle ensemble methods can outperform by using simultaneous sampling channels to scale up NIO significantly. In the case of optical brain monitoring, the interplay of these factors favors speckle ensemble methods. We illustrate that this important engineering consideration is consistent with the previous research on blood pulsatile flow measurements, where a speckle ensemble method operating at 100-fold lower photon flux than a conventional temporal sampling system can achieve a comparable SNR.

Published
2020
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4. Doubling the near-infrared photocurrent in a solar cell via omni-resonant coherent perfect absorption

Author

Villinger, Massimo L., Shiri, Abbas, Shabahang, Soroush, Jahromi, Ali K., Nasr, Magued B., Villinger, Christopher H., and Abouraddy, Ayman F.

Subjects
Physics - Optics, Electrical Engineering and Systems Science - Systems and Control, Physics - Applied Physics
Abstract

Minimizing the material usage in thin-film solar cells can reduce manufacturing costs and enable mechanically flexible implementations, but concomitantly diminishes optical absorption. Coherent optical effects can help alleviate this inevitable drawback at discrete frequencies. For example, coherent perfect absorption guarantees that light is fully absorbed in a thin layer regardless of material or thickness but only on resonance. Here we show that omni resonance delivers such coherent enhancement over a broad bandwidth by structuring the optical field to nullify the angular dispersion intrinsic to resonant structures. After embedding an amorphous-silicon thin film photovoltaic cell in a planar cavity, pre conditioning the incident light using an alignment free optical arrangement severs the link between the resonant bandwidth and the cavity photon lifetime, thereby rendering the cavity omni resonant. Coherently enhanced near infrared absorption doubles the photocurrent over the targeted spectral range 660 to 740 nm where every wavelength resonates. These results may pave the way to transparent solar cells that optimally harvest near infrared light.

Published
2019

5. Coherent perfect absorption in a weakly absorbing fiber

Author

Jahromi, Ali. K. and Abouraddy, Ayman F.

Subjects
Physics - Optics
Abstract

Short-length fiber lasers are key elements for device integration in fiber systems. However, efficiently absorbing a pump beam in a short ion-doped fiber remains a challenge. We present an approach that renders a weakly absorbing short-length Er-doped fiber completely absorbing. We exploit the concept of coherent perfect absorption, whereby two appropriately designed fiber Bragg gratings define a short-length cavity that enforces complete absorption of an incident wave on resonance independently of the fiber intrinsic absorption. This approach applies to any spectral window and may lead to efficient single-longitudinal-mode fiber lasers for applications in optical communication, sensing, and metrology., Comment: 10 pages, 4 figures, Submitted to Opt. Express

Published
2017

6. Transparent Perfect Mirror

Author

Jahromi, Ali K., Shabahang, Soroush, Kondakci, H. Esat, Orsilla, Seppo, Melanen, Petri, and Abouraddy, Ayman F.

Subjects
Physics - Optics
Abstract

A mirror that reflects light fully and yet is transparent appears paradoxical. Current so-called transparent or "one-way" mirrors are not perfectly reflective and thus can be distinguished from a standard mirror. Constructing a transparent "perfect" mirror has profound implications for security, privacy, and camouflage. However, such a hypothetical device cannot be implemented in a passive structure. We demonstrate here a transparent perfect mirror in a non-Hermitian configuration: an active optical cavity where a certain prelasing gain extinguishes Poynting's vector at the device entrance. At this threshold, all vestiges of the cavity's structural resonances are eliminated and the device presents spectrally flat unity-reflectivity, thus, becoming indistinguishable from a perfect mirror when probed optically across the gain bandwidth. Nevertheless, the device is rendered transparent by virtue of persisting amplified transmission resonances. We confirm these predictions in two photonic realizations: a compact integrated active waveguide and a macroscopic all-optical-fiber system., Comment: The paper is highlighted in Nature Photonics: http://www.nature.com/nphoton/journal/v11/n6/full/nphoton.2017.90.html The supplementary data is available in: http://pubs.acs.org/doi/suppl/10.1021/acsphotonics.7b00052

Published
2017
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7. Statistical PT-symmetric lasing in an optical fiber network

Author

Jahromi, Ali K., Hassan, Absar U., Christodoulides, Demetrios N., and Abouraddy, Ayman F.

Subjects
Physics - Optics
Abstract

PT-symmetry in optics is a condition whereby the real and imaginary parts of the refractive index across a photonic structure are deliberately balanced. This balance can lead to a host of novel optical phenomena, such as unidirectional invisibility, loss-induced lasing, single-mode lasing from multimode resonators, and non-reciprocal effects in conjunction with nonlinearities. Because PT-symmetry has been thought of as fragile, experimental realizations to date have been usually restricted to on-chip micro-devices. Here, we demonstrate that certain features of PT-symmetry are sufficiently robust to survive the statistical fluctuations associated with a macroscopic optical cavity. We construct optical-fiber-based coupled-cavities in excess of a kilometer in length (the free spectral range is less than 0.8 fm) with balanced gain and loss in two sub-cavities and examine the lasing dynamics. In such a macroscopic system, fluctuations can lead to a cavity-detuning exceeding the free spectral range. Nevertheless, by varying the gain-loss contrast, we observe that both the lasing threshold and the growth of the laser power follow the predicted behavior of a stable PT-symmetric structure. Furthermore, a statistical symmetry-breaking point is observed upon varying the cavity loss. These findings indicate that PT-symmetry is a more robust optical phenomenon than previously expected, and points to potential applications in optical fiber networks and fiber lasers., Comment: Submitted to Nature Communications, Pages 1-19: Main manuscript; Pages 20-38: Supplementary materials

Published
2017
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8. Basis-neutral Hilbert-space analyzers

Author

Martin, Lane, Mardani, Davood, Kondakci, H. Esat, Larson, Walker D., Shabahang, Soroush, Jahromi, Ali K., Malhotra, Tanya, Vamivakas, A. Nick, Atia, George K., and Abouraddy, Ayman F.

Subjects
Physics - Optics, Quantum Physics
Abstract

Interferometry is one of the central organizing principles of optics. Key to interferometry is the concept of optical delay, which facilitates spectral analysis in terms of time-harmonics. In contrast, when analyzing a beam in a Hilbert space spanned by spatial modes -- a critical task for spatial-mode multiplexing and quantum communication -- basis-specific principles are invoked that are altogether distinct from that of `delay.' Here, we extend the traditional concept of temporal delay to the spatial domain, thereby enabling the analysis of a beam in an arbitrary spatial-mode basis -- exemplified using Hermite-Gaussian and radial Laguerre-Gaussian modes. Such generalized delays correspond to optical implementations of fractional transforms; for example, the fractional Hankel transform is the generalized delay associated with the space of Laguerre-Gaussian modes, and an interferometer incorporating such a `delay' obtains modal weights in the associated Hilbert space. By implementing an inherently stable, reconfigurable spatial-light-modulator-based polarization- interferometer, we have constructed a `Hilbert-space analyzer' capable of projecting optical beams onto any modal basis., Comment: 6 figures

Published
2016
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20. Diffusing wave spectroscopy: A unified treatment on temporal sampling and speckle ensemble methods.

Author

Xu, Jian, Jahromi, Ali K, and Yang, Changhuei

Subjects
SPECKLE interferometry, COHERENCE (Optics), SPECKLE interference, BLOOD flow measurement, SPECTRUM analysis, PHOTON flux
Abstract

Diffusing wave spectroscopy (DWS) is a well-known set of methods to measure the temporal dynamics of dynamic samples. In DWS, dynamic samples scatter the incident coherent light, and the information of the temporal dynamics is encoded in the scattered light. To record and analyze the light signal, there exist two types of methods—temporal sampling methods and speckle ensemble methods. Temporal sampling methods, including diffuse correlation spectroscopy, use one or multiple large bandwidth detectors to sample well and analyze the temporal light signal to infer the sample temporal dynamics. Speckle ensemble methods, including speckle visibility spectroscopy, use a high-pixel-count camera sensor to capture a speckle pattern and use the speckle contrast to infer sample temporal dynamics. In this paper, we theoretically and experimentally demonstrate that the decorrelation time (τ) measurement accuracy or signal-to-noise ratio (SNR) of the two types of methods has a unified and similar fundamental expression based on the number of independent observables (NIO) and the photon flux. Given a time measurement duration, the NIO in temporal sampling methods is constrained by the measurement duration, while speckle ensemble methods can outperform by using simultaneous sampling channels to scale up the NIO significantly. In the case of optical brain monitoring, the interplay of these factors favors speckle ensemble methods. We illustrate that this important engineering consideration is consistent with the previous research on blood pulsatile flow measurements, where a speckle ensemble method operating at 100-fold lower photon flux than a conventional temporal sampling system can achieve a comparable SNR. [ABSTRACT FROM AUTHOR]

Published
2021
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29. Transparent Perfect Mirror

Author

Jahromi, Ali K., primary, Shabahang, Soroush, additional, Kondakci, H. Esat, additional, Orsila, Seppo, additional, Melanen, Petri, additional, and Abouraddy, Ayman F., additional

Published
2017
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30. Basis-neutral Hilbert-space analyzers

Author

Martin, Lane, primary, Mardani, Davood, additional, Kondakci, H. Esat, additional, Larson, Walker D., additional, Shabahang, Soroush, additional, Jahromi, Ali K., additional, Malhotra, Tanya, additional, Vamivakas, A. Nick, additional, Atia, George K., additional, and Abouraddy, Ayman F., additional

Published
2017
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47. Inverse design of omnidirectional coherent absorbers for optical power beaming applications.

Author

Markowitz M, Vela E, Jahromi AK, Tamargo MC, Kuskovsky IL, and Miri MA

Abstract

An efficient photovoltaic power converter is a critical element in laser power beaming systems for maximizing the end-to-end power transfer efficiency while minimizing beam reflections from the receiver for safety considerations. We designed a multilayer absorber that can efficiently trap monochromatic light from broad incident angles. The proposed design is built on the concept of a one-way coherent absorber with inverse-designed aperiodic multilayer front- and back-reflectors that enable maximal optical absorption in a thin-film photovoltaic material for broad angles. We argue that the broad bandwidth is achieved through an optimization search process that automatically engineers the modal content of the cavity to create multiple overlapping resonant modes at the desired angle or frequency range. A realistic design is provided based on GaAs thin films with inverse-designed multilayer binary AlAs/AlGaAs mirrors. The proposed device can pave the way for efficient optical power beaming systems.

Published
2023
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