{"id":175,"date":"2024-06-05T21:12:05","date_gmt":"2024-06-05T21:12:05","guid":{"rendered":"https:\/\/live-optics-wp.pantheonsite.io\/melkabbash\/?page_id=175"},"modified":"2024-07-10T18:39:27","modified_gmt":"2024-07-10T18:39:27","slug":"publications","status":"publish","type":"page","link":"https:\/\/wp.optics.arizona.edu\/melkabbash\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\n<ol class=\"wp-block-list\" reversed>\n<li>S. Trajtenberg-Mills et al., Metal-Optic Nanophotonic Modulators in Standard CMOS Technology.\u00a0 (2024). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Metal-Optic-Nanophotonic-Modulators-in-Standard-CMOS-Technology.pdf\">PDF<\/a><\/li>\n\n\n\n<li><mark style=\"background-color:#17ff00\" class=\"has-inline-color\">S. Trajtenberg-Mills et al., LNoS: Lithium Niobate on Silicon Spatial Light Modulator. arXiv preprint arXiv:2402.14608\u00a0 (2024). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/LNoS-Lithium-Niobate-on-Silicon-Spatial-Light-Modulator.pdf\">PDF<\/a><\/mark><\/li>\n\n\n\n<li>K. V. Sreekanth, S. Jana, M. ElKabbash, R. Singh, J. Teng, Phase change material-based tunable Fano resonant optical coatings and their applications. Nanophotonics&nbsp; (2024). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Phase-change-material-based-tunable-Fano-resonant-optical-coatings-and-their-applications.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>S. Trajtenberg-Mills et al. (2023) GHz speed 1D light modulation in a scalable resonant Lithium Niobite platform. in Digital Holography and Three-Dimensional Imaging (Optica Publishing Group), p HW5C. 5.<\/strong><\/li>\n\n\n\n<li><mark style=\"background-color:#17ff00\" class=\"has-inline-color\">S. Trajtenberg-Mills et al. (2023) Lithium Niobite on Silicon High Speed Spatial Light Modulator. in CLEO: Science and Innovations (Optica Publishing Group), p SF1E. 4. <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Lithium-Niobite-on-Silicon-High-Speed-Spatial-Light-Modulator.pdf\">PDF<\/a><\/mark><\/li>\n\n\n\n<li><strong>K. J. Lee et al., Gigantic suppression of recombination rate in 3D lead-halide perovskites for enhanced photodetector performance. Nature Photonics 17, 236-243 (2023).<\/strong><\/li>\n\n\n\n<li>Y. Kiasat et al., Epsilon-near-zero (ENZ)-based optomechanics. Communications Physics 6, 69 (2023). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Epsilon-near-zero-ENZ-based-optomechanics.pdf\">PDF<\/a><\/li>\n\n\n\n<li>M. ElKabbash et al., Fano resonant optical coatings platform for full gamut and high purity structural colors. Nature Communications 14, 3960 (2023). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Fano-resonant-optical-coatings-platform-for-full-gamut-and-high-purity-structural-colors.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#ffe200\" class=\"has-inline-color\">M. ElKabbash et al. (2023) Zero-Change CMOS Nanophotonics: Converting Foundry Semiconductor Chips to Plasmonic Electro-optic Modulators. in 2023 Conference on Lasers and Electro-Optics (CLEO) (IEEE), pp 1-2.<\/mark><\/strong><\/li>\n\n\n\n<li>C. Cong et al., &#8220;Imaging Dynamics of Femtosecond Laser-Induced Surface Nanostructuring&#8221; in Ultrafast Laser Nanostructuring: The Pursuit of Extreme Scales. (Springer, 2023), pp. 355-376. <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Imaging-Dynamics-of-Femtosecond-Laser-Induced-Surface-Nanostructuring.pdf\">PDF<\/a><\/li>\n\n\n\n<li>C. Brabec, S. T. Mills, M. ElKabbash, I. Christen, D. Englund (2023) Fast Phase Retrieval: Unique and Stable Complex Object Recovery in O (NLogN) Time. in CLEO: Applications and Technology (Optica Publishing Group), p AW4I. 5. <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Fast-Phase-Retrieval-Unique-and-Stable-Complex-Object-Recovery-in-O-NLogN-Time.pdf\">PDF<\/a><\/li>\n\n\n\n<li>A. Roman, A. Hassan, M. ElKabbash, Measuring gravitational force from Femto-gram source masses. arXiv preprint arXiv:2212.06970\u00a0 (2022). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Measuring-gravitational-force-from-Femto-gram-source-masses.pdf\">PDF<\/a><\/li>\n\n\n\n<li><mark style=\"background-color:#fff300\" class=\"has-inline-color\">M. Elkabbash, C. Guo, M. Hinczewski, G. Strangi (2022) Fano resonant optical coating.\u00a0 (Google Patents). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Fano-resonant-optical-coating.pdf\">PDF<\/a><\/mark><\/li>\n\n\n\n<li><mark style=\"background-color:#fff300\" class=\"has-inline-color has-black-color\">M. ElKabbash et al. (2022) High-speed electro-optic guided resonance spatial light modulator. in Active Photonic Platforms 2022 (SPIE), p PC1219616.<\/mark><\/li>\n\n\n\n<li>M. ElKabbash, Radiative cooling with angular shields: Mitigating atmospheric radiation and parasitic heating. arXiv preprint arXiv:2208.03797\u00a0 (2022). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Radiative-cooling-with-angular-shields-Mitigating-atmospheric-radiation-and-parasitic-heating.pdf\">PDF<\/a><\/li>\n\n\n\n<li>S. K. Chamoli, W. Li, C. Guo, M. ElKabbash, Angularly selective thermal emitters for deep subfreezing daytime radiative cooling. Nanophotonics 11, 3709-3717 (2022). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Angularly-selective-thermal-emitters-for-deep-subfreezing-daytime-radiative-cooling.pdf\">PDF<\/a><\/li>\n\n\n\n<li>S. K. Chamoli, M. ElKabbash, C. Guo, Switchable Gratings for Ultracompact and Ultrahigh Modulation Depth Plasmonic Switches. Plasmonics 17, 1361-1368 (2022). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Switchable-Gratings-for-Ultracompact-and-Ultrahigh-Modulation-Depth-Plasmonic-Switches.pdf\">PDF<\/a><\/li>\n\n\n\n<li>A. Alquliah, M. ElKabbash, J. Cheng, W. Li, C. Guo, Integrated Metasurface-based Wavelengths Division Demultiplexers. arXiv preprint arXiv:2208.03825\u00a0 (2022). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Integrated-Metasurface-based-Wavelengths-Division-Demultiplexers.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>M. Qin et al., Nature Sustainability. Criteria Pollutant Impacts of Volatile Chemical Products Informed by Near-Field Modelling. 4, 129-137 (2021).<\/strong><\/li>\n\n\n\n<li><strong>S. A. Jalil et al., Controlling Voronoi partitions on femtosecond-laser-superheated metal surfaces. Applied Surface Science 568, 150913 (2021).<\/strong><\/li>\n\n\n\n<li>M. ElKabbash et al., Fano-resonant ultrathin film optical coatings. Nature Nanotechnology 16, 440-446 (2021). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Fano-resonant-Ultrathin-Film-Optical-Coatings.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>M. Elkabbash et al., Fano resonance in thin-film optical coatings. NATURE NANOTECHNOLOGY 16, xx-1 (2021).<\/strong><\/li>\n\n\n\n<li>M. ElKabbash et al., Imaging nanostructure phase transition through ultrafast far-field optical ultramicroscopy. Cell Reports Physical Science 2 (2021). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Imaging-nanostructure-phase-transition-through-ultrafast-far-field-optical-ultramicroscopy.pdf\">PDF<\/a><\/li>\n\n\n\n<li>A. Alquliah, M. Elkabbash, J. Zhang, J. Cheng, C. Guo, Ultrabroadband, compact, polarization independent and efficient metasurface-based power splitter on lithium niobate waveguides. Optics Express 29, 8160-8170 (2021). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Ultrabroadband-compact-polarization-independent-and-efficient-metasurface-based-power-splitter-on-lithium-niobate-waveguides.pdf\">PDF<\/a><\/li>\n\n\n\n<li>A. Alquliah et al., Reconfigurable metasurface-based 1\u00d7 2 waveguide switch. Photonics Research 9, 2104-2115 (2021). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Reconfigurable-metasurface-based-1\u00d7-2-waveguide-switch.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>Z. Zheng, M. Elkabbash, J. Zhang, C. Guo, Plasmonic analogue of geometric diodes realizing asymmetric optical transmission. Optics Letters 45, 3937-3940 (2020).<\/strong><\/li>\n\n\n\n<li><strong>J. Zhang, R. Wei, M. ElKabbash, E. M. Campbell, C. Guo, Thin-film perfect infrared absorbers over single-and dual-band atmospheric windows. Optics Letters 45, 2800-2803 (2020).<\/strong><\/li>\n\n\n\n<li><mark style=\"background-color:#fff300\" class=\"has-inline-color\">G. Strangi et al. (2020) Optical sensor platform employing hyperbolic metamaterials.\u00a0 (Google Patents). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Optical-sensor-platform-employing-hyperbolic-metamaterials.pdf\">PDF<\/a><\/mark><\/li>\n\n\n\n<li><strong>G. Strangi, K. Sreekanth, U. Gurkan, M. Hinczewski, M. Elkabbash, Optical sensor platform employing hyperbolic metamaterials.\u00a0 (2020).<\/strong><\/li>\n\n\n\n<li>S. C. Singh et al., Solar-trackable super-wicking black metal panel for photothermal water sanitation. Nature Sustainability 3, 938-946 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Solar-trackable-super-wicking-black-metal-panel.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>S. C. Singh et al., Superwicking black metal surface for solar-thermal water sanitation. Optics and Photonics News 31, 60-60 (2020).<\/strong><\/li>\n\n\n\n<li>V. Mitra, E. M. Garcell, M. ElKabbash, A. Neogi, C. Guo, Multifractal characterization of femtosecond laser-induced herringbone patterns. Journal of Physics: Photonics 3, 015001 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Multifractal-characterization-of-femtosecond-laser-induced-herringbone-patterns.pdf\">PDF<\/a><\/li>\n\n\n\n<li><mark style=\"background-color:#00ff03\" class=\"has-inline-color\">K. J. Lee et al., Exciton dynamics in two-dimensional Mo S 2 on a hyperbolic metamaterial-based nanophotonic platform. Physical Review B 101, 041405 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Exciton-dynamics-in-two-dimensional-Mo-S-2-on-a-hyperbolic-metamaterial-based-nanophotonic-platform.pdf\">PDF<\/a><\/mark><\/li>\n\n\n\n<li>B. Lam, M. ElKabbash, J. Zhang, C. Guo, Spatial Wavefunction Characterization of Femtosecond Pulses at Single-Photon Level. Research\u00a0 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Spatial-Wavefunction-Characterization-of-Femtosecond-Pulses-at-Single-Photon-Level.pdf\">PDF<\/a><\/li>\n\n\n\n<li>S. A. Jalil et al., Spectral absorption control of femtosecond laser-treated metals and application in solar-thermal devices. Light: Science &amp; Applications 9, 14 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Spectral-absorption-control-of-femtosecond-laser-treated-metals-and-application-in-solar-thermal-devices.pdf\">PDF<\/a><\/li>\n\n\n\n<li>S. A. Jalil et al., Multipronged heat-exchanger based on femtosecond laser-nano\/microstructured Aluminum for thermoelectric heat scavengers. Nano Energy 75, 104987 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Multipronged-heat-exchanger-based-on-femtosecond-laser-nanomicrostructured-Aluminum-for-thermoelectric-heat-scavengers.pdf\">PDF<\/a><\/li>\n\n\n\n<li>S. A. Jalil et al., Creating superhydrophobic and antibacterial surfaces on gold by femtosecond laser pulses. Applied surface science 506, 144952 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Creating-superhydrophobic-and-antibacterial-surfaces-on-gold-by-femtosecond-laser-pulses.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>M. ElKabbash et al., Ultrathin-film optical coating for angle-independent remote hydrogen sensing. Measurement Science and Technology 31, 115201 (2020).<\/strong><\/li>\n\n\n\n<li><strong>S. K. Chamoli, M. ElKabbash, J. Zhang, C. Guo, Dynamic control of spontaneous emission rate using tunable hyperbolic metamaterials. Optics Letters 45, 1671-1674 (2020).<\/strong><\/li>\n\n\n\n<li>M. Asad, S. A. Jalil, M. ElKabbash, C. Guo, Ultra-smooth ultrathin silver films deposited on acid treated Silicon substrates. Nano Express 1, 020012 (2020). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Ultra-smooth-ultrathin-silver-films-deposited-on-acid-treated-Silicon-substrates.pdf\">PDF<\/a><\/li>\n\n\n\n<li>J. Zhang et al., Plasmonic metasurfaces with 42.3% transmission efficiency in the visible. Light: Science &amp; Applications 8, 53 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Plasmonic-metasurfaces-with-42.3-transmission-efficiency-in-the-visible.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>Z. Zhan et al., Creating Superhydrophobic Polymer Surfaces with Superstrong Resistance to Harsh Cleaning and Mechanical Abrasion Fabricated by Scalable One\u2010Step Thermal\u2010Imprinting. Advanced Materials Interfaces 6, 1900240 (2019).<\/strong><\/li>\n\n\n\n<li>Z. Zhan et al., Enhancing thermoelectric output power via radiative cooling with nanoporous alumina. Nano Energy 65, 104060 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Enhancing-thermoelectric-output-power-via-radiative-cooling-with-nanoporous-alumina.pdf\">PDF<\/a><\/li>\n\n\n\n<li>Z. Zhan et al., Highly floatable superhydrophobic metallic assembly for aquatic applications. ACS applied materials &amp; interfaces 11, 48512-48517 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Highly-floatable-superhydrophobic-metallic-assembly-for-aquatic-applications.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>C. Yao et al., Quasi-rhombus metasurfaces as multimode interference couplers for controlling the propagation of modes in dielectric-loaded waveguides. Optics letters 44, 1654-1657 (2019).<\/strong><\/li>\n\n\n\n<li><mark style=\"background-color:#17ff00\" class=\"has-inline-color\">K. Valiyaveedu Sreekanth et al., Generalized Brewster-angle effect in thin-film optical absorbers and its application for graphene hydrogen sensing. arXiv e-prints, arXiv: 1904.10075 (2019).<\/mark> <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Generalized-Brewster-angle-effect-in-thin-film-optical-absorbers-and-its-application-for-graphene-hydrogen-sensing.pdf\">PDF<\/a><\/li>\n\n\n\n<li>K. V. Sreekanth et al., Phase\u2010change\u2010material\u2010based low\u2010loss visible\u2010frequency hyperbolic metamaterials for ultrasensitive label\u2010free biosensing. Advanced Optical Materials 7, 1900081 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Phase-change-material-based-low-loss-visible-frequency-hyperbolic-metamaterials-for-ultra-sensitive-label-free-biosensing_manuscript.pdf\">PDF<\/a><\/li>\n\n\n\n<li><mark style=\"background-color:#17ff00\" class=\"has-inline-color\">K. V. Sreekanth et al., Generalized brewster angle effect in thin-film optical absorbers and its application for graphene hydrogen sensing. ACS photonics 6, 1610-1617 (2019).<\/mark> <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Generalized-Brewster-angle-effect-in-thin-film-optical-absorbers-and-its-application-for-graphene-hydrogen-sensing.pdf\">PDF<\/a><\/li>\n\n\n\n<li>K. Sreekanth et al. (2019) New Directions in Thin Film Nanophotonics.\u00a0 (Springer Singapore). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/New-Directions-in-Thin-Film-Nanophotonics.pdf\">PDF<\/a><\/li>\n\n\n\n<li>T. Letsou, M. ElKabbash, S. Iram, M. Hinczewski, G. Strangi, Heat-induced perfect light absorption in thin-film metasurfaces for structural coloring. Optical Materials Express 9, 1386-1393 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Heat-induced-perfect-light-absorption-in-thin-film-metasurfaces-for-structural-coloring.pdf\">PDF<\/a><\/li>\n\n\n\n<li><mark style=\"background-color:#29ff00\" class=\"has-inline-color\">K. J. Lee et al., Controlling exciton dynamics in two-dimensional MoS2 on hyperbolic metamaterial-based nanophotonic platform. arXiv preprint arXiv:1903.09568\u00a0 (2019).<\/mark> <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Controlling-exciton-dynamics-in-two-dimensional-MoS2-on-hyperbolic-metamaterial-based-nanophotonic-platform.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Phase Change Material-Based Nanophotonic Cavities for Reconfigurable Photonic Device Applications. New Directions in Thin Film Nanophotonics, 45-58 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Dielectric Singularities in Hyperbolic Metamaterials. New Directions in Thin Film Nanophotonics, 81-101 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Sub-wavelength Nanopatterning Using Thin Metal Films. New Directions in Thin Film Nanophotonics, 59-78 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Metal\/Photoemissive-Blend Hyperbolic Metamaterials for Controlling the Topological Transition. New Directions in Thin Film Nanophotonics, 117-128 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Perfect Light Absorption in Thin and Ultra-Thin Films and Its Applications. New Directions in Thin Film Nanophotonics, 3-27 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Graphene and topological insulator-based active THz hyperbolic metamaterials. New Directions in Thin Film Nanophotonics, 159-172 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Realization of Point-of-Darkness and Extreme Phase Singularity in Nanophotonic Cavities. New Directions in Thin Film Nanophotonics, 29-44 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Resonant Gain Singularities in Hyperbolic Metamaterials. New Directions in Thin Film Nanophotonics, 103-115 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., Guided Modes of Hyperbolic Metamaterial and Their Applications. New Directions in Thin Film Nanophotonics, 129-158 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong><mark style=\"background-color:#e84747\" class=\"has-inline-color\">S. KV et al., New directions in thin film nanophotonics. (No Title)\u00a0 (2019).<\/mark><\/strong><\/li>\n\n\n\n<li><strong>S. A. Jalil, J. Yang, M. ElKabbash, S. C. Singh, C. Guo, Maskless formation of uniform subwavelength periodic surface structures by double temporally-delayed femtosecond laser beams. Applied Surface Science 471, 516-520 (2019).<\/strong><\/li>\n\n\n\n<li><strong>S. A. Jalil et al., Formation of uniform two-dimensional subwavelength structures by delayed triple femtosecond laser pulse irradiation. Optics Letters 44, 2278-2281 (2019).<\/strong><\/li>\n\n\n\n<li><strong>S. A. Jalil, J. Yang, M. ElKabbash, C. Cong, C. Guo, Formation of controllable 1D and 2D periodic surface structures on cobalt by femtosecond double pulse laser irradiation. Applied Physics Letters 115 (2019).<\/strong><\/li>\n\n\n\n<li>C.-H. Fann et al., Broadband infrared plasmonic metamaterial absorber with multipronged absorption mechanisms. Optics Express 27, 27917-27926 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Broadband-infrared-plasmonic-metamaterial-absorber-with-multipronged-absorption-mechanisms.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>M. ElKabbash et al., Hydrogen sensing using thin-film perfect light absorber. ACS Photonics 6, 1889-1894 (2019).<\/strong><\/li>\n\n\n\n<li>M. ElKabbash et al., Cooperative energy transfer controls the spontaneous emission rate beyond field enhancement limits. Physical Review Letters 122, 203901 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Cooperative-energy-transfer-controls-the-spontaneous-emission-rate-beyond-field-enhancement-limits.pdf\">PDF<\/a><\/li>\n\n\n\n<li>M. Akram et al., Femtosecond laser induced periodic surface structures for the enhancement of field emission properties of tungsten. Optical Materials Express 9, 3183-3192 (2019). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Femtosecond-laser-induced-periodic-surface-structures-for-the-enhancement-of-field-emission-properties-of-tungsten.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>K. V. Sreekanth et al., Large-area silver\u2013stibnite nanoporous plasmonic films for label-free biosensing. ACS applied materials &amp; interfaces 10, 34991-34999 (2018).<\/strong><\/li>\n\n\n\n<li><strong>M. ElKabbash, S. Iram, T. Letsou, M. Hinczewski, G. Strangi, Designer perfect light absorption using ultrathin lossless dielectrics on absorptive substrates. Advanced Optical Materials 6, 1800672 (2018).<\/strong><\/li>\n\n\n\n<li>G. Strangi, K. Sreekanth, M. Elkabbash, Hyperbolic metamaterial-based ultrasensitive plasmonic biosensors for early-stage cancer detection. Next Generation Point-of-Care Biomedical Sensors Technologies for Cancer Diagnosis, 155-172 (2017). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Hyperbolic-metamaterial-based-ultrasensitive-plasmonic-biosensors-for-early-stage-cancer-detection.pdf\">PDF<\/a><\/li>\n\n\n\n<li>K. V. Sreekanth et al., Hyperbolic metamaterials-based plasmonic biosensor for fluid biopsy with single molecule sensitivity. EPJ Applied Metamaterials 4 (2017). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Hyperbolic-Metamaterials-Based-Plasmonic-Biosensor-for-Fluid-Biop.pdf\">PDF<\/a><\/li>\n\n\n\n<li><mark style=\"background-color:#ffeb00\" class=\"has-inline-color\">K. V. Sreekanth et al., Erratum to: Hyperbolic metamaterials-based plasmonic biosensor for fluid biopsy with single molecule sensitivity. EPJ Applied Metamaterials 4, 4 (2017).<\/mark> <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Erratum-to-Hyperbolic-metamaterials-based-plasmonic-biosensor-for-fluid-biopsy-with-single-molecule-sensitivity.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>M. ElKabbash et al., Tunable black gold: controlling the near\u2010field coupling of immobilized au nanoparticles embedded in mesoporous silica capsules. Advanced Optical Materials 5, 1700617 (2017).<\/strong><\/li>\n\n\n\n<li><strong>M. ElKabbash et al., Ultrafast transient optical loss dynamics in exciton\u2013plasmon nano-assemblies. Nanoscale 9, 6558-6566 (2017).<\/strong><\/li>\n\n\n\n<li>M. ElKabbash et al., Iridescence-free and narrowband perfect light absorption in critically coupled metal high-index dielectric cavities. Optics Letters 42, 3598-3601 (2017). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Iridescence-free-and-narrowband-perfect-light-absorption-in-critically-coupled-metal-high-index-dielectric-cavities.pdf\">PDF<\/a><\/li>\n\n\n\n<li>M. ElKabbash, Active Plasmonics and Metamaterials (Case Western Reserve University, 2017). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Active-plasmonics-and-metamaterials.pdf\">PDF<\/a><\/li>\n\n\n\n<li>K. V. Sreekanth et al., A multiband perfect absorber based on hyperbolic metamaterials. Scientific reports 6, 26272 (2016). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/A-multiband-perfect-absorber-based-on-hyperbolic-metamaterials.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>K. V. Sreekanth et al., Enhancing the angular sensitivity of plasmonic sensors using hyperbolic metamaterials. Advanced optical materials 4, 1767-1772 (2016).<\/strong><\/li>\n\n\n\n<li><mark style=\"background-color:#fff300\" class=\"has-inline-color\">K. V. Sreekanth et al., Biosensing: Enhancing the Angular Sensitivity of Plasmonic Sensors Using Hyperbolic Metamaterials (Advanced Optical Materials 11\/2016). Advanced Optical Materials 4, 1659-1659 (2016).<\/mark><\/li>\n\n\n\n<li>K. V. Sreekanth et al., Extreme sensitivity biosensing platform based on hyperbolic metamaterials. Nature materials 15, 621-627 (2016). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Extreme-Sensitivity-Biosensing-Platform-Based-on-Hyperbolic-Metamaterials.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>R. Dhama et al., Broadband Optical Transparency Via Exciton-Plasmon Coupling In Plexcitonic Nanocomposite Polymer Films. OPTICS EXPRESS 24 (2016).<\/strong><\/li>\n\n\n\n<li>K. V. Sreekanth, A. R. Rashed, A. Veltri, M. ElKabbash, G. Strangi, Optical bistability in Ag-Al2O3 one-dimensional photonic crystals. Europhysics Letters 112, 14005 (2015). <a href=\"http:\/\/wp.optics.arizona.edu\/melkabbash\/wp-content\/uploads\/sites\/123\/2024\/07\/Optical-bistability-in-Ag-Al2O3-one-dimensional-photonic-crystals.pdf\">PDF<\/a><\/li>\n\n\n\n<li><strong>K. V. Sreekanth, A. R. Rashed, A. Veltri, M. ElKabbash, G. Strangi, Optical bistability in Agext\u2212 Al2O3 one-dimensional photonic crystals.<\/strong><\/li>\n\n\n\n<li><strong>A. Rashed, M. Elkabbash, A. De Luca, G. Strangi, Investigating Ultrafast Dynamics of the Exciton\u2013Plasmon Interplay in Gain-Plasmon Hybrid Systems.<\/strong><\/li>\n\n\n\n<li><strong>A. De Luca, A. Rashed, M. Elkabbash, K. Sreekanth, G. Strangi, Plasmon-Exciton Dynamics: Across Scales Approach for Low-Loss Optical Metamaterials.<\/strong><\/li>\n<\/ol>\n","protected":false},"excerpt":{"rendered":"","protected":false},"author":640,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"template-fullwidth.php","meta":{"footnotes":""},"class_list":["post-175","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/pages\/175","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/users\/640"}],"replies":[{"embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/comments?post=175"}],"version-history":[{"count":18,"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/pages\/175\/revisions"}],"predecessor-version":[{"id":334,"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/pages\/175\/revisions\/334"}],"wp:attachment":[{"href":"https:\/\/wp.optics.arizona.edu\/melkabbash\/wp-json\/wp\/v2\/media?parent=175"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}