Researchers at IISER Tirupati developed an efficient method of hydrogen generation from methanol and formaldehyde combination developed for moving towards ‘Hydrogen economy’


azadi ka amrit mahotsav

Researchers have developed an innovative synthetic method to produce hydrogen gas from a mixture of methanol and paraformaldehyde under mild conditions. This method has proven particularly effective for the transfer hydrogenation of alkynes to alkenes and the combination could be a promising hydrogen carrier, paving the way for advancements in chemical synthesis and sustainable energy solutions.

The rapid depletion of fossil fuels has spurred the search for alternative energy sources, highlighting the need for sustainable and renewable resources. Hydrogen gas generation is particularly important due to its potential to replace fossil fuels in energy storage, transportation, and various chemical processes. Methanol and paraformaldehyde, both produced on a large scale, have emerged as viable candidates for hydrogen carriers. Their abundance and widespread manufacture make them valuable for the storage and transportation of hydrogen, offering significant advantages over free hydrogen itself.

The research led by Prof. Ekambaram Balaraman at IISER Tirupati has utilized commercially available nickel catalysts to produce hydrogen from methanol and paraformaldehyde without the need for bases or activators. This efficient catalytic system has demonstrated remarkable efficiency under mild conditions, and the generated hydrogen was successfully employed in chemo- and stereo-selective partial transfer hydrogenation of alkynes. This process enabled access to bioactive molecules with enhanced synthetic value. This research was supported by ANRF (erstwhile SERB, a statutory body of the Department of Science and Technology (DST).

This research, accepted for publication in the journal Catalysis Science & Technology, opens a new avenue for COx-free hydrogen generation, contributing to the advancement of a ‘Hydrogen economy.’ The ability to harness methanol and paraformaldehyde as hydrogen carriers offers significant potential to address the challenges posed by the increasing global energy demands. This development marks a significant step forward in the quest for sustainable energy solutions.

Publication link: https://pubs.rsc.org/en/content/articlelanding/2024/cy/d3cy01699d

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