Your search keyword '"Evgenia Kontoleta"' showing total 7 results

1. Localized photodeposition of catalysts using nanophotonic resonances in silicon photocathodes

Author

Evgenia Kontoleta, Sven H. C. Askes, Lai-Hung Lai, and Erik C. Garnett

Subjects

catalysts, nanomaterials, nanophotonics, photodeposition, solar fuels, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

Nanostructured semiconductors feature resonant optical modes that confine light absorption in specific areas called “hot spots”. These areas can be used for localized extraction of the photogenerated charges, which in turn could drive chemical reactions for synthesis of catalytic materials. In this work, we use these nanophotonic hot spots in vertical silicon nanowires to locally deposit platinum nanoparticles in a photo-electrochemical system. The tapering angle of the silicon nanowires as well as the excitation wavelength are used to control the location of the hot spots together with the deposition sites of the platinum catalyst. A combination of finite difference time domain (FDTD) simulations with scanning electron microscopy image analysis showed a reasonable correlation between the simulated hot spots and the actual experimental localization and quantity of platinum atoms. This nanophotonic approach of driving chemical reactions at the nanoscale using the optical properties of the photo-electrode, can be very promising for the design of lithography-free and efficient hierarchical nanostructures for the generation of solar fuels.

Published

2018

2. Over 65% sunlight absorption in a 1 mu m Si slab with hyperuniform texture

Author

Nasim Tavakoli, Richard Spalding, Alexander Lambertz, Pepijn Koppejan, Georgios Gkantzounis, Chenglong Wan, Ruslan Röhrich, Evgenia Kontoleta, A. Femius Koenderink, Riccardo Sapienza, Marian Florescu, and Esther Alarcon-Llado

Subjects

Technology, EFFICIENCY, Materials Science, 0205 Optical Physics, Materials Science, Multidisciplinary, SILICON SOLAR-CELLS, Physics, Applied, WAVE-GUIDES, LIMITS, DESIGN, COLOR, Electrical and Electronic Engineering, Nanoscience & Nanotechnology, THIN, 0206 Quantum Physics, Science & Technology, Physics, Optics, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, hyperuniform correlated, 0906 Electrical and Electronic Engineering, LIGHT, Physics, Condensed Matter, DENSITY, Physical Sciences, ultrathin photovoltaics, Science & Technology - Other Topics, light trapping, Biotechnology

Abstract

Thin, flexible, and invisible solar cells will be a ubiquitous technology in the near future. Ultrathin crystalline silicon (c-Si) cells capitalize on the success of bulk silicon cells while being lightweight and mechanically flexible, but suffer from poor absorption and efficiency. Here we present a new family of surface texturing, based on correlated disordered hyperuniform patterns, capable of efficiently coupling the incident spectrum into the silicon slab optical modes. We experimentally demonstrate 66.5% solar light absorption in free-standing 1 μm c-Si layers by hyperuniform nanostructuring for the spectral range of 400 to 1050 nm. The absorption equivalent photocurrent derived from our measurements is 26.3 mA/cm2, which is far above the highest found in literature for Si of similar thickness. Considering state-of-the-art Si PV technologies, we estimate that the enhanced light trapping can result in a cell efficiency above 15%. The light absorption can potentially be increased up to 33.8 mA/cm2 by incorporating a back-reflector and improved antireflection, for which we estimate a photovoltaic efficiency above 21% for 1 μm thick Si cells.

Published

2022

3. Self-Optimized Catalysts: Hot-Electron Driven Photosynthesis of Catalytic Photocathodes

Author

Erik C. Garnett, Sven H. C. Askes, and Evgenia Kontoleta

Subjects

Materials science, Photoelectrochemistry, chemistry.chemical_element, Nanoparticle, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Chemical reaction, photoelectrochemistry, hot-electron chemistry, General Materials Science, Surface plasmon resonance, Plasmon, Plasmonic nanoparticles, Au/TiO2, 021001 nanoscience & nanotechnology, 0104 chemical sciences, plasmonic nanoparticles, Pt photodeposition, chemistry, Chemical engineering, Photocatalysis, 0210 nano-technology, Platinum, photocatalysis, Research Article

Abstract

Photogenerated hot electrons from plasmonic nanostructures are very promising for photocatalysis, mostly due to their potential for enhanced chemical selectivity. Here, we present a self-optimized fabrication method of plasmonic photocathodes using hot-electron chemistry, for enhanced photocatalytic efficiencies. Plasmonic Au/TiO2 nanoislands are excited at their surface plasmon resonance to generate hot electrons in an aqueous bath containing a platinum (cocatalyst) precursor. Hot electrons drive the deposition of Pt cocatalyst nanoparticles, without any nanoparticle functionalization and negligible applied bias, close to the hotspots of the plasmonic nanoislands. The presence of TiO2 is crucial for achieving higher chemical reaction rates. The Au/TiO2/Pt photocathodes synthesized using hot-electron chemistry show a photocatalytic activity of up to 2 times higher than that of a control made with random electrodeposited Pt nanoparticles. This light-driven positioning of the cocatalyst close to the same positions where hot electrons are most efficiently generated and transferred represents a novel and simple method for synthesizing complex, self-optimized photocatalytic nanostructures with improved efficiency and selectivity.

Published

2019

4. Over 65% sunlight absorption in a 1 μm Si slab with hyperuniform texture

Author

Riccardo Sapienza, Evgenia Kontoleta, Ruslan Röhrich, Esther Alarcon-Llado, Pepijn Koppejan, A. Femius Koenderink, Chenglong Wang, Georgio Gkantzounis, Richard J. Spalding, Marian Florescu, and Nasim Tavakoli

Subjects

Sunlight, Materials science, Slab, Analytical chemistry, Texture (crystalline), Absorption (electromagnetic radiation)

Abstract

Thin, flexible and invisible solar cells will be an ubiquitous technology in the near future. Ultrathin crystalline silicon (c-Si) cells capitalise on the success of bulk silicon cells while being light-weight and mechanically flexible, but suffer from poor absorption and efficiency. Here we present a new family of surface texturing, based on correlated disordered hyperuniform patterns, capable of efficiently coupling the incident spectrum into the silicon slab optical modes. We experimentally demonstrate 66.5% solar light absorption in free-standing 1 µm c-Si layers by hyperuniform nanostructuring. The absorption equivalent photocurrent derived from our measurements is 26.3 mA/cm2, which is far above the highest found in literature for Si of similar thickness. Considering state-of-the-art Si PV technologies, the enhanced light trapping translates to a record efficiency above 15%. The light absorption can potentially be increased up to 33.8 mA/cm2 by incorporating a back-reflector and improved anti-reflection, for which we estimate a photovoltaic efficiency above 21% for 1 µm thick Si cells.

Published

2020

5. Using Hot Electrons and Hot Holes for Simultaneous Cocatalyst Deposition on Plasmonic Nanostructures

Author

Sven H. C. Askes, Erwin Zoethout, Evgenia Kontoleta, Erik C. Garnett, Eitan Oksenberg, Harshal Agrawal, and Alexandra Tsoukala

Subjects

photodeposition of cocatalysts, Materials science, Nanostructure, manganese oxides, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Chemical reaction, Nanomaterials, chemistry.chemical_compound, hot-hole chemistry, General Materials Science, Surface plasmon resonance, Plasmon, business.industry, plasmon-driven chemical reactions, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Titanium dioxide, Photocatalysis, Optoelectronics, hot carriers, 0210 nano-technology, business, Platinum, photocatalysis, Research Article

Abstract

Hot electrons generated in metal nanoparticles can drive chemical reactions and selectively deposit cocatalyst materials on the plasmonic hotspots, the areas where the decay of plasmons takes place and the hot electrons are created. While hot electrons have been extensively used for nanomaterial formation, the utilization of hot holes for simultaneous cocatalyst deposition has not yet been explored. Herein, we demonstrate that hot holes can drive an oxidation reaction for the deposition of the manganese oxide (MnOx) cocatalyst on different plasmonic gold (Au) nanostructures on a thin titanium dioxide (TiO2) layer, excited at their surface plasmon resonance. An 80% correlation between the hot-hole deposition sites and the simulated plasmonic hotspot location is showed when considering the typical hot-hole diffusion length. Simultaneous deposition of more than one cocatalyst is also achieved on one of the investigated plasmonic systems (Au plasmonic nanoislands) through the hot-hole oxidation of a manganese salt and the hot-electron reduction of a platinum precursor in the same solution. These results add more flexibility to the use of hot carriers and open up the way for the design of complex photocatalytic nanostructures.

Published

2020

6. The Role of Size and Dimerization of Decorating Plasmonic Silver Nanoparticles on the Photoelectrochemical Solar Water Splitting Performance of BiVO4Photoanodes

Author

Ibadillah A. Digdaya, Andreas Schmidt-Ott, George Biskos, Evgenia Kontoleta, Wilson A. Smith, Magnus P. Jonsson, and Marco Valenti

Subjects

Plasmonic nanoparticles, Materials science, Renewable Energy, Sustainability and the Environment, business.industry, Energy Engineering and Power Technology, Ag nanoparticles, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Light scattering, Silver nanoparticle, 0104 chemical sciences, Solar water, Biomaterials, Semiconductor, Materials Chemistry, Water splitting, 0210 nano-technology, business, Plasmon

Abstract

Ag nanoparticles (NPs) are deposited on BiVO4 photoanodes to study their effect on the photoelectrochemical (PEC) water splitting performance of the semiconductor. 15 nm light-absorbing NPs and 65 ...

Published

2016

7. Integrating Sphere Microscopy for Direct Absorption Measurements of Single Nanostructures

Author

Huiyun Liu, Erik C. Garnett, Evgenia Kontoleta, Beniamino Sciacca, Jia Wang, Yunyan Zhang, Sander A. Mann, Centre Interdisciplinaire de Nanoscience de Marseille (CINaM), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Centre for Materials and Processes (CERI MP), Ecole nationale supérieure Mines-Télécom Lille Douai (IMT Lille Douai), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT), Centre for Materials and Processes (CERI MP - IMT Nord Europe), and Ecole nationale supérieure Mines-Télécom Lille Douai (IMT Nord Europe)

Subjects

absorption spectroscopy, Materials science, Nanostructure, Absorption spectroscopy, Nanowire, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, 01 natural sciences, Article, Nanomaterials, Computer Science::Emerging Technologies, 0103 physical sciences, plasmon resonance, General Materials Science, 010306 general physics, Absorption (electromagnetic radiation), quantitative spectroscopy, ComputingMilieux_MISCELLANEOUS, Mie resonances, General Engineering, 021001 nanoscience & nanotechnology, Optical phenomena, Integrating sphere, nanowires, Absorptance, [SPI.OPTI]Engineering Sciences [physics]/Optics / Photonic, nanoparticles, 0210 nano-technology

Abstract

Nanoscale materials are promising for optoelectronic devices because their physical dimensions are on the order of the wavelength of light. This leads to a variety of complex optical phenomena that, for instance, enhance absorption and emission. However, quantifying the performance of these nanoscale devices frequently requires measuring absolute absorption at the nanoscale, and remarkably, there is no general method capable of doing so directly. Here, we present such a method based on an integrating sphere but modified to achieve submicron spatial resolution. We explore the limits of this technique by using it to measure spatial and spectral absorptance profiles on a wide variety of nanoscale systems, including different combinations of weakly and strongly absorbing and scattering nanomaterials (Si and GaAs nanowires, Au nanoparticles). This measurement technique provides quantitative information about local optical properties that are crucial for improving any optoelectronic device with nanoscale dimensions or nanoscale surface texturing.

Published

2017