Pradnya A. Bharad scite author profile

A rational approach was employed to enhance the solar water splitting (SWS) efficiency by systematically combining various important factors that helps to increase the photocatalytic activity. The rational approach includes four important parameters, namely, charge generation through simulated sunlight absorption, charge separation and diffusion, charge utilization through redox reaction, and the electronic integration of all of the above three factors. The complexity of the TiO2 based catalyst and its SWS activity was increased systematically by adding reduced graphene oxide (RGO) or N-doped RGO and/or nanogold. Au-N-RGO-TiO2 shows the maximum apparent quantum yield (AQY) of 2.46% with a H2 yield (525 μmol g(-1) h(-1)) from aqueous methanol, and overall water splitting activity (22 μmol g(-1) h(-1); AQY = 0.1%) without any sacrificial agent under one sun conditions. This exercise helps to understand the factors which help to enhance the SWS activity. Activity enhancement was observed when there is synergy among the components, especially the simulated sunlight absorption (or one sun conditions), charge separation/conduction and charge utilization. Electronic integration among the components provides the synergy for efficient solar light harvesting. In our opinion, the above synergy helps to increase the overall utilization of charge carriers towards the higher activity.

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Is there any Real Effect of Low Dimensional Morphologies towards Light Harvesting? A Case Study of Au–rGO‐TiO₂ Nanocomposites

Melvin

Bharad

Illath

et al. 2016

ChemistrySelect

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Nanotube and nanosheet morphologies have been celebrated for their electron transport properties. Present work has been explored to exploit the same by combining 1D TiO2 nanotube (1D‐TN) with 2D reduced graphene oxide (rGO) along with nano gold for visible light sensitization for photocatalytic H2 generation under one sun condition and visible light (λ≥ 400 nm). Vertical and horizontal electron transport in 1D‐TN and rGO, respectively, is combined with the visible light absorption capability of Au nanoparticle. H2 yield (HY) varies between 100 and 655 µmol/g.h with an apparent quantum yield between 0.45 and 3.2 %, respectively, depending on Au/rGO/1D‐TN preparation method and reaction conditions. It has been demonstrated that interfacial contact between rGO/1D‐TN and Au is crucial for high photocatalytic HY. Preparation method influences charge utilization, and hence HY, to a large extent. Nonetheless, the maximum HY reported in the present work is just comparable to HY reported in literature with the most commonly found spherical morphology, and this leads to a question of, is there any real influence of 1D and/or 2D materials, particularly, towards light harvesting applications?

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Direct solar-to-hydrogen generation by quasi-artificial leaf approach: possibly scalable and economical device

et al. 2019

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Pradnya A. Bharad

Why the thin film form of a photocatalyst is better than the particulate form for direct solar-to-hydrogen conversion: a poor man's approach

A rational approach towards enhancing solar water splitting: a case study of Au–RGO/N-RGO–TiO₂

Is there any Real Effect of Low Dimensional Morphologies towards Light Harvesting? A Case Study of Au–rGO‐TiO₂ Nanocomposites

Direct solar-to-hydrogen generation by quasi-artificial leaf approach: possibly scalable and economical device

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Pradnya A. Bharad

Why the thin film form of a photocatalyst is better than the particulate form for direct solar-to-hydrogen conversion: a poor man's approach

A rational approach towards enhancing solar water splitting: a case study of Au–RGO/N-RGO–TiO2

Is there any Real Effect of Low Dimensional Morphologies towards Light Harvesting? A Case Study of Au–rGO‐TiO2 Nanocomposites

Direct solar-to-hydrogen generation by quasi-artificial leaf approach: possibly scalable and economical device

Contact Info

Product

Resources

About

A rational approach towards enhancing solar water splitting: a case study of Au–RGO/N-RGO–TiO₂

Is there any Real Effect of Low Dimensional Morphologies towards Light Harvesting? A Case Study of Au–rGO‐TiO₂ Nanocomposites