Abstract
Two series of hybrid inorganic-organic derivatives, obtained via the modification of protonated Ruddlesden–Popper phases H2Ln2Ti3O10 (Ln = La, Nd) with intercalated n-alkylamines and grafted n-alkoxy groups, have been systematically investigated in relation to photocatalytic hydrogen production from a model of 1 mol % aqueous solution of methanol for the first time. Photocatalytic measurements were performed both for bare samples and for their composites with Pt nanoparticles as a cocatalyst using an advanced scheme, including dark stages, monitoring of the volume concentration of the sample in the reaction suspension during the experiment, shifts of its pH and possible exfoliation of layered compounds into nanolayers. It was found that the incorporation of organic components into the interlayer space of the titanates increases their photocatalytic activity up to 117 times compared with that of the initial compounds. Additional platinization of the hybrid samples’ surface allowed for achieving apparent quantum efficiency of hydrogen evolution of more than 40%. It was established that the photocatalytic activity of the hybrid samples correlates with the hydration degree of their interlayer space, which is considered a separate reaction zone in photocatalysis, and that hydrogen indeed generates from the aqueous methanol solution rather than from organic components of the derivatives.
Highlights
The global environmental problems associated with the active industrial growth and the widespread use of fossil fuels over the last centuries are forcing humankind to develop waste-free technologies and alternative energy sources such as hydrogen fuel
Due to its undeniable eco-friendliness and high calorific value, hydrogen is a potential substitute for petroleum products and natural gas in various engines, which is of high significance in light of the impending energy crisis [1,2]
Heterogeneous photocatalysis is a promising method for hydrogen production from water and aqueous solutions of various organic compounds, including products of primary biomass processing [3]
Summary
The global environmental problems associated with the active industrial growth and the widespread use of fossil fuels over the last centuries are forcing humankind to develop waste-free technologies and alternative energy sources such as hydrogen fuel. Since water and solar energy are widely available free natural resources, their use for hydrogen generation appears to be efficient both in environmental and economic aspects [4,5]. There is a need to search for other available substrates such as bioalcohols, carbohydrates and related biomass processing products. Their photocatalytic decomposition followed by the use of the hydrogen produced as fuel is expected to be much more energy efficient than direct biomass combustion due to a relatively low calorific value of the latter [8,9,10,11,12,13,14,15,16]. Photocatalysis may serve as a destructive method for aqueous media purification if the organic substances being decomposed are water contaminants [17,18,19,20]
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