Publications

  1. S. Trajtenberg-Mills et al., Metal-Optic Nanophotonic Modulators in Standard CMOS Technology.  (2024). PDF
  2. S. Trajtenberg-Mills et al., LNoS: Lithium Niobate on Silicon Spatial Light Modulator. arXiv preprint arXiv:2402.14608  (2024). PDF
  3. K. V. Sreekanth, S. Jana, M. ElKabbash, R. Singh, J. Teng, Phase change material-based tunable Fano resonant optical coatings and their applications. Nanophotonics  (2024). PDF
  4. 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.
  5. 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. PDF
  6. 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).
  7. Y. Kiasat et al., Epsilon-near-zero (ENZ)-based optomechanics. Communications Physics 6, 69 (2023). PDF
  8. M. ElKabbash et al., Fano resonant optical coatings platform for full gamut and high purity structural colors. Nature Communications 14, 3960 (2023). PDF
  9. 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.
  10. C. Cong et al., “Imaging Dynamics of Femtosecond Laser-Induced Surface Nanostructuring” in Ultrafast Laser Nanostructuring: The Pursuit of Extreme Scales. (Springer, 2023), pp. 355-376. PDF
  11. 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. PDF
  12. A. Roman, A. Hassan, M. ElKabbash, Measuring gravitational force from Femto-gram source masses. arXiv preprint arXiv:2212.06970  (2022). PDF
  13. M. Elkabbash, C. Guo, M. Hinczewski, G. Strangi (2022) Fano resonant optical coating.  (Google Patents). PDF
  14. M. ElKabbash et al. (2022) High-speed electro-optic guided resonance spatial light modulator. in Active Photonic Platforms 2022 (SPIE), p PC1219616.
  15. M. ElKabbash, Radiative cooling with angular shields: Mitigating atmospheric radiation and parasitic heating. arXiv preprint arXiv:2208.03797  (2022). PDF
  16. S. K. Chamoli, W. Li, C. Guo, M. ElKabbash, Angularly selective thermal emitters for deep subfreezing daytime radiative cooling. Nanophotonics 11, 3709-3717 (2022). PDF
  17. S. K. Chamoli, M. ElKabbash, C. Guo, Switchable Gratings for Ultracompact and Ultrahigh Modulation Depth Plasmonic Switches. Plasmonics 17, 1361-1368 (2022). PDF
  18. A. Alquliah, M. ElKabbash, J. Cheng, W. Li, C. Guo, Integrated Metasurface-based Wavelengths Division Demultiplexers. arXiv preprint arXiv:2208.03825  (2022). PDF
  19. M. Qin et al., Nature Sustainability. Criteria Pollutant Impacts of Volatile Chemical Products Informed by Near-Field Modelling. 4, 129-137 (2021).
  20. S. A. Jalil et al., Controlling Voronoi partitions on femtosecond-laser-superheated metal surfaces. Applied Surface Science 568, 150913 (2021).
  21. M. ElKabbash et al., Fano-resonant ultrathin film optical coatings. Nature Nanotechnology 16, 440-446 (2021). PDF
  22. M. Elkabbash et al., Fano resonance in thin-film optical coatings. NATURE NANOTECHNOLOGY 16, xx-1 (2021).
  23. M. ElKabbash et al., Imaging nanostructure phase transition through ultrafast far-field optical ultramicroscopy. Cell Reports Physical Science 2 (2021). PDF
  24. 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). PDF
  25. A. Alquliah et al., Reconfigurable metasurface-based 1× 2 waveguide switch. Photonics Research 9, 2104-2115 (2021). PDF
  26. Z. Zheng, M. Elkabbash, J. Zhang, C. Guo, Plasmonic analogue of geometric diodes realizing asymmetric optical transmission. Optics Letters 45, 3937-3940 (2020).
  27. 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).
  28. G. Strangi et al. (2020) Optical sensor platform employing hyperbolic metamaterials.  (Google Patents). PDF
  29. G. Strangi, K. Sreekanth, U. Gurkan, M. Hinczewski, M. Elkabbash, Optical sensor platform employing hyperbolic metamaterials.  (2020).
  30. S. C. Singh et al., Solar-trackable super-wicking black metal panel for photothermal water sanitation. Nature Sustainability 3, 938-946 (2020). PDF
  31. S. C. Singh et al., Superwicking black metal surface for solar-thermal water sanitation. Optics and Photonics News 31, 60-60 (2020).
  32. 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). PDF
  33. 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). PDF
  34. B. Lam, M. ElKabbash, J. Zhang, C. Guo, Spatial Wavefunction Characterization of Femtosecond Pulses at Single-Photon Level. Research  (2020). PDF
  35. S. A. Jalil et al., Spectral absorption control of femtosecond laser-treated metals and application in solar-thermal devices. Light: Science & Applications 9, 14 (2020). PDF
  36. S. A. Jalil et al., Multipronged heat-exchanger based on femtosecond laser-nano/microstructured Aluminum for thermoelectric heat scavengers. Nano Energy 75, 104987 (2020). PDF
  37. S. A. Jalil et al., Creating superhydrophobic and antibacterial surfaces on gold by femtosecond laser pulses. Applied surface science 506, 144952 (2020). PDF
  38. M. ElKabbash et al., Ultrathin-film optical coating for angle-independent remote hydrogen sensing. Measurement Science and Technology 31, 115201 (2020).
  39. 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).
  40. 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). PDF
  41. J. Zhang et al., Plasmonic metasurfaces with 42.3% transmission efficiency in the visible. Light: Science & Applications 8, 53 (2019). PDF
  42. Z. Zhan et al., Creating Superhydrophobic Polymer Surfaces with Superstrong Resistance to Harsh Cleaning and Mechanical Abrasion Fabricated by Scalable One‐Step Thermal‐Imprinting. Advanced Materials Interfaces 6, 1900240 (2019).
  43. Z. Zhan et al., Enhancing thermoelectric output power via radiative cooling with nanoporous alumina. Nano Energy 65, 104060 (2019). PDF
  44. Z. Zhan et al., Highly floatable superhydrophobic metallic assembly for aquatic applications. ACS applied materials & interfaces 11, 48512-48517 (2019). PDF
  45. 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).
  46. 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). PDF
  47. K. V. Sreekanth et al., Phase‐change‐material‐based low‐loss visible‐frequency hyperbolic metamaterials for ultrasensitive label‐free biosensing. Advanced Optical Materials 7, 1900081 (2019). PDF
  48. 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). PDF
  49. K. Sreekanth et al. (2019) New Directions in Thin Film Nanophotonics.  (Springer Singapore). PDF
  50. 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). PDF
  51. K. J. Lee et al., Controlling exciton dynamics in two-dimensional MoS2 on hyperbolic metamaterial-based nanophotonic platform. arXiv preprint arXiv:1903.09568  (2019). PDF
  52. S. KV et al., Phase Change Material-Based Nanophotonic Cavities for Reconfigurable Photonic Device Applications. New Directions in Thin Film Nanophotonics, 45-58 (2019).
  53. S. KV et al., Dielectric Singularities in Hyperbolic Metamaterials. New Directions in Thin Film Nanophotonics, 81-101 (2019).
  54. S. KV et al., Sub-wavelength Nanopatterning Using Thin Metal Films. New Directions in Thin Film Nanophotonics, 59-78 (2019).
  55. S. KV et al., Metal/Photoemissive-Blend Hyperbolic Metamaterials for Controlling the Topological Transition. New Directions in Thin Film Nanophotonics, 117-128 (2019).
  56. 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).
  57. S. KV et al., Graphene and topological insulator-based active THz hyperbolic metamaterials. New Directions in Thin Film Nanophotonics, 159-172 (2019).
  58. 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).
  59. S. KV et al., Resonant Gain Singularities in Hyperbolic Metamaterials. New Directions in Thin Film Nanophotonics, 103-115 (2019).
  60. S. KV et al., Guided Modes of Hyperbolic Metamaterial and Their Applications. New Directions in Thin Film Nanophotonics, 129-158 (2019).
  61. S. KV et al., New directions in thin film nanophotonics. (No Title)  (2019).
  62. 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).
  63. 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).
  64. 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).
  65. C.-H. Fann et al., Broadband infrared plasmonic metamaterial absorber with multipronged absorption mechanisms. Optics Express 27, 27917-27926 (2019). PDF
  66. M. ElKabbash et al., Hydrogen sensing using thin-film perfect light absorber. ACS Photonics 6, 1889-1894 (2019).
  67. M. ElKabbash et al., Cooperative energy transfer controls the spontaneous emission rate beyond field enhancement limits. Physical Review Letters 122, 203901 (2019). PDF
  68. 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). PDF
  69. K. V. Sreekanth et al., Large-area silver–stibnite nanoporous plasmonic films for label-free biosensing. ACS applied materials & interfaces 10, 34991-34999 (2018).
  70. 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).
  71. 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). PDF
  72. K. V. Sreekanth et al., Hyperbolic metamaterials-based plasmonic biosensor for fluid biopsy with single molecule sensitivity. EPJ Applied Metamaterials 4 (2017). PDF
  73. 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). PDF
  74. M. ElKabbash et al., Tunable black gold: controlling the near‐field coupling of immobilized au nanoparticles embedded in mesoporous silica capsules. Advanced Optical Materials 5, 1700617 (2017).
  75. M. ElKabbash et al., Ultrafast transient optical loss dynamics in exciton–plasmon nano-assemblies. Nanoscale 9, 6558-6566 (2017).
  76. 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). PDF
  77. M. ElKabbash, Active Plasmonics and Metamaterials (Case Western Reserve University, 2017). PDF
  78. K. V. Sreekanth et al., A multiband perfect absorber based on hyperbolic metamaterials. Scientific reports 6, 26272 (2016). PDF
  79. K. V. Sreekanth et al., Enhancing the angular sensitivity of plasmonic sensors using hyperbolic metamaterials. Advanced optical materials 4, 1767-1772 (2016).
  80. 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).
  81. K. V. Sreekanth et al., Extreme sensitivity biosensing platform based on hyperbolic metamaterials. Nature materials 15, 621-627 (2016). PDF
  82. R. Dhama et al., Broadband Optical Transparency Via Exciton-Plasmon Coupling In Plexcitonic Nanocomposite Polymer Films. OPTICS EXPRESS 24 (2016).
  83. 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). PDF
  84. K. V. Sreekanth, A. R. Rashed, A. Veltri, M. ElKabbash, G. Strangi, Optical bistability in Agext− Al2O3 one-dimensional photonic crystals.
  85. A. Rashed, M. Elkabbash, A. De Luca, G. Strangi, Investigating Ultrafast Dynamics of the Exciton–Plasmon Interplay in Gain-Plasmon Hybrid Systems.
  86. A. De Luca, A. Rashed, M. Elkabbash, K. Sreekanth, G. Strangi, Plasmon-Exciton Dynamics: Across Scales Approach for Low-Loss Optical Metamaterials.