Artificial photosynthesis

Context:

Researchers from the Jawaharlal Nehru Centre for Advanced Scientific Research (JNCASR) have developed an integrated system that can capture carbon dioxide (CO2) and convert it into solar fuel.

They have named this process as artificial photosynthesis (AP) — which they feel can aid mitigate effects of emissions made by use of fossil fuels.

About Artificial photosynthesis

Scientists have found a method to mimic nature’s own process of reducing carbon dioxide in the atmosphere, namely photosynthesis, to capture excess carbon dioxide in the atmosphere. This artificial photosynthesis (AP) harnesses solar energy and converts the captured carbon dioxide to carbon monoxide (CO), which can be used as a fuel for internal combustion engines.

In artificial photosynthesis (AP), scientists are essentially conducting the same fundamental process in natural photosynthesis but with simpler nanostructures. However, there are plenty of hurdles to overcome as a successful catalyst to carry out AP.

A team of Scientists from Jawaharlal Nehru Centre for Advanced Scientific Research, an autonomous institute of the Department of Science & Technology (DST), Government of India, designed and fabricated an integrated catalytic system based on a metal-organic framework (MOF-808) comprising of a photosensitizer (molecules which absorb light and transfer the electron from the incident light into another nearby molecule) that can harness solar power and a catalytic centre that can eventually reduce CO₂. The work described above has been accepted for publication in the journal ‘Energy & Environmental Science’ of Royal Society of Chemistry, UK.

The scientists have immobilized a photosensitizer, which is a chemical called ruthenium bipyridyl complex ([Ru(bpy)₂Cl₂]) and a catalytic part which is another chemical called rhenium carbonyl complex ([Re(CO)₅Cl]), inside the nanospace of metal-organic framework for artificial photosynthesis. Both these molecular entities stay in close proximity in the confined nano-space of a porous metal-organic framework system resulting in excellent CO₂ uptake capability at room temperature. This synthetic strategy empowers efficient solar light-driven photocatalysis.

The developed catalyst exhibited excellent visible-light-driven CO₂ reduction to CO with more than 99% selectivity. The catalyst also oxidizes water to produce oxygen (O₂). The photocatalytic assembly, when assessed for CO₂ reduction under direct sunlight in a water medium without any additives, showed superior performance of CO production. Being heterogeneous, the integrated catalytic assembly can be reused for several catalytic cycles without losing its activity.