Your search keyword '"Mubeen, Syed"' showing total 6 results

1. Earth‐Abundant Tin Sulfide‐Based Photocathodes for Solar Hydrogen Production

Author

Cheng, Wei, Singh, Nirala, Elliott, Will, Lee, Joun, Rassoolkhani, Alan, Jin, Xuejun, McFarland, Eric W, and Mubeen, Syed

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Engineering, Materials Engineering, Nanotechnology, Affordable and Clean Energy, artificial photosynthesis, electrocatalyst, hydrogen production, photocathode, tin sulfide

Abstract

Tin-based chalcogenide semiconductors, though attractive materials for photovoltaics, have to date exhibited poor performance and stability for photoelectrochemical applications. Here, a novel strategy is reported to improve performance and stability of tin monosulfide (SnS) nanoplatelet thin films for H2 production in acidic media without any use of sacrificial reagent. P-type SnS nanoplatelet films are coated with the n-CdS buffer layer and the TiO2 passivation layer to form type II heterojunction photocathodes. These photocathodes with subsequent deposition of Pt nanoparticles generate a photovoltage of 300 mV and a photocurrent density of 2.4 mA cm-2 at 0 V versus reversible hydrogen electrode (RHE) for water splitting under simulated visible-light illumination (λ > 500 nm, Pin = 80 mW cm-2). The incident photon-to-current efficiency at 0 V versus RHE for H2 production reach a maximum of 12.7% at 575 nm with internal quantum efficiency of 13.8%. The faradaic efficiency for hydrogen evolution remains close to unity after 6000 s of illumination, confirming the robustness of the heterojunction for solar H2 production.

Published

2018

2. Anisotropic Growth of TiO2 onto Gold Nanorods for Plasmon-Enhanced Hydrogen Production from Water Reduction

Author

Wu, Binghui, Liu, Deyu, Mubeen, Syed, Chuong, Tracy T, Moskovits, Martin, and Stucky, Galen D

Subjects

Affordable and Clean Energy, Chemical Sciences, General Chemistry

Abstract

Plasmonic metal/semiconductor heterostructures show promise for visible-light-driven photocatalysis. Gold nanorods (AuNRs) semi-coated with TiO2 are expected to be ideally structured systems for hydrogen evolution. Synthesizing such structures by wet-chemistry methods, however, has proved challenging. Here we report the bottom-up synthesis of AuNR/TiO2 nanodumbbells (NDs) with spatially separated Au/TiO2 regions, whose structures are governed by the NRs' diameter, and the higher curvature and lower density of CnTAB surfactant at the NRs' tips than on their lateral surfaces, as well as the morphology's dependence on concentration, and alkyl chain length of CnTAB. The NDs show plasmon-enhanced H2 evolution under visible and near-infrared light.

Published

2016

3. Panchromatic Photoproduction of H2 with Surface Plasmons

Author

Mubeen, Syed, Lee, Joun, Liu, Deyu, Stucky, Galen D, and Moskovits, Martin

Subjects

Affordable and Clean Energy, Plasmons, water splitting H-2 production, sold nanorods, photocatalysis, H2 production, gold nanorods, water splitting, Nanoscience & Nanotechnology

Abstract

The optical resonances of plasmonic nanostructures depend critically on the geometrical details of the absorber. We show that this unique property of plasmons can potentially be used to create panchromatic absorbers covering most of the useful solar spectrum, by measuring the light-to-hydrogen conversion capabilities of a series multielectrode photocatalytic devices, based on functionalized gold nanorods of appropriately chosen aspect ratios. Judiciously combining nanorods of various aspect ratios almost doubles the H2 production of the device over what is optimally possible with a device using gold nanorods of a single aspect ratio (all other key parameters being equal). The estimated quantum efficiency (absorbed photons-to-hydrogen) averaged over the entire solar spectrum of the best performing plasmonic multielectrode array was approximately 0.1%, and the measured H2 production rate for all of the devices was found to be approximately proportional to the hot electron generation. The device was monitored continuously for over 200 hr of operation without measurable diminution in the rate.

Published

2015

4. On the Plasmonic Photovoltaic

Author

Mubeen, Syed, Lee, Joun, Lee, Woo-ram, Singh, Nirala, Stucky, Galen D, and Moskovits, Martin

Subjects

photovoltaics, surface plasmons, gold nanorods, Schottky barrier, TiO2, Nanoscience & Nanotechnology

Abstract

The conversion of sunlight into electricity by photovoltaics is currently a mature science and the foundation of a lucrative industry. In conventional excitonic solar cells, electron-hole pairs are generated by light absorption in a semiconductor and separated by the "built in" potential resulting from charge transfer accompanying Fermi-level equalization either at a p-n or a Schottky junction, followed by carrier collection at appropriate electrodes. Here we report a stable, wholly plasmonic photovoltaic device in which photon absorption and carrier generation take place exclusively in the plasmonic metal. The field established at a metal-semiconductor Schottky junction separates charges. The negative carriers are high-energy (hot) electrons produced immediately following the plasmon's dephasing. Some of the carriers are energetic enough to clear the Schottky barrier or quantum mechanically tunnel through it, thereby producing the output photocurrent. Short circuit photocurrent densities in the range 70-120 μA cm(-2) were obtained for simulated one-sun AM1.5 illumination with devices based on arrays of parallel gold nanorods, conformally coated with 10 nm TiO2 films and fashioned with a Ti metal collector. For the device with short circuit currents of 120 μA cm(-2), the internal quantum efficiency is ∼2.75%, and its wavelength response tracks the absorption spectrum of the transverse plasmon of the gold nanorods indicating that the absorbed photon-to-electron conversion process resulted exclusively in the Au, with the TiO2 playing a negligible role in charge carrier production. Devices fabricated with 50 nm TiO2 layers had open-circuit voltages as high as 210 mV, short circuit current densities of 26 μA cm(-2), and a fill factor of 0.3. For these devices, the TiO2 contributed a very small but measurable fraction of the charge carriers.

Published

2014

5. Synthesis of Chemicals Using Solar Energy with Stable Photoelectrochemically Active Heterostructures

Author

Mubeen, Syed, Singh, Nirala, Lee, Joun, Stucky, Galen D, Moskovits, Martin, and McFarland, Eric W

Subjects

Affordable and Clean Energy, Artificial photosynthesis, anodic aluminum oxide, H-2 production, solar cell, electrocatalyst, Nanoscience & Nanotechnology

Abstract

Efficient and cost-effective conversion of solar energy to useful chemicals and fuels could lead to a significant reduction in fossil hydrocarbon use. Artificial systems that use solar energy to produce chemicals have been reported for more than a century. However the most efficient devices demonstrated, based on traditionally fabricated compound semiconductors, have extremely short working lifetimes due to photocorrosion by the electrolyte. Here we report a stable, scalable design and molecular level fabrication strategy to create photoelectrochemically active heterostructure (PAH) units consisting of an efficient semiconductor light absorber in contact with oxidation and reduction electrocatalysts and otherwise protected by alumina. The functional heterostructures are fabricated by layer-by-layer, template-directed, electrochemical synthesis in porous anodic aluminum oxide membranes to produce high density arrays of electronically autonomous, nanostructured, corrosion resistant, photoactive units (~10(9)-10(10) PAHs per cm(2)). Each PAH unit is isolated from its neighbor by the transparent electrically insulating oxide cellular enclosure that makes the overall assembly fault tolerant. When illuminated with visible light, the free floating devices have been demonstrated to produce hydrogen at a stable rate for over 24 h in corrosive hydroiodic acid electrolyte with light as the only input. The quantum efficiency (averaged over the solar spectrum) for absorbed photons-to-hydrogen conversion was 7.4% and solar-to-hydrogen energy efficiency of incident light was 0.9%. The fabrication approach is scalable for commercial manufacturing and readily adaptable to a variety of earth abundant semiconductors which might otherwise be unstable as photoelectrocatalysts.

Published

2013

6. High‐Efficiency Panchromatic Hybrid Schottky Solar Cells

Author

Lee, Joun, Mubeen, Syed, Hernandez‐Sosa, Gerardo, Sun, Yanming, Toma, Francesca M, Stucky, Galen D, and Moskovits, Martin

Subjects

Affordable and Clean Energy, Cadmium Compounds, Electric Power Supplies, Polymers, Selenium Compounds, Solar Energy, hybrid solar cells, cadmium selenide, poly(3, 4-ethylenedioxythiophene):poly(styrenesulfonate), Schottky barrier, internal quantum efficiency, Physical Sciences, Chemical Sciences, Engineering, Nanoscience & Nanotechnology

Abstract

Nanostructured Schottky inorganic-organic solar cells provide overall power conversion efficiencies exceeding 3%, with extremely large short-circuit photocurrents. The device EQE faithfully tracks the absorptance of the CdSe nanorods, and the IQE is approximately constant over the entire visible spectrum as opposed to a p-n junction hybrid solar cell fabricated with a highly absorbing organic polymer.

Published

2013