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India Needs 1.3 to 1.5 Billion Tonnes of Coal by 2030

  Due consultations were held for finalizing India's approach for negotiations at COP 21 and prior to signing the Paris Agreement.   As per Economic Survey, the demand for coal is expected to remain in the range of 1.3-1.5 billion tonnes by 2030. Coal is the most important and abundant fossil fuel in India and accounts for 55% of the country's energy need. Commercial primary energy consumption in India has grown by about 700% in the last four decades. The current per capita commercial primary energy consumption in India is about 350 kgoe/year. Coal is not only the primary source of energy in the country but is also used as an intermediary by many industries such as steel, sponge iron, cement, paper, brick-kilns etc. Similarly, with increase in growth of industries using coal, their demand for coal has also been increasing; hence, there has been an overall increase in the demand of coal over the years. Being an affordable source of energy with substantial reserve, coal is going

New method can efficiently transform phenol to a key ingredient for manufacturing food preservatives, pharmaceuticals & polymers

 Indian researchers have found that electrolysis using surface-modified electrodes for efficient large-scale transformation of phenol to 1,4 hydroquinone used as intermediate in the manufacturing of food preservatives, pharmaceuticals, dyes, polymers. India currently imports 1,4 hydroquinone at a heavy cost due to lack of efficient processes for conversion of phenol to 1,4 hydroquinone.

Phenol and it’s oxidized products like 1,4-hydroquinone, catechol, or resorcinol are vital and primary building blocks used in the synthesis of many medicinal and industrially used organic compounds. Especially products like 1,4 hydroquinone are used as intermediates in the manufacturing of food preservatives, pharmaceuticals, dyes, polymers, etc. In addition, oxidation of phenol leads to a huge value addition. India imports phenol worth 23.6 million USD while India spends US$56.5M for importing 1,4-hydroquinone. Conventionally, phenol oxidation is carried out by chemical methods using catalysts involving precious metals, metal oxides, and enzymes along with hazardous oxidants. But these methods suffer from many disadvantages, including incomplete conversion of starting material and lack of product selectivity along with environmental hazards.

In this background, researchers from the Centre for Nano and Soft Matter Sciences led by Dr. Bhagavatula Prasad and CSIR-National Chemical Laboratory regarded electrolysis as an effective way to carry out the oxidative transformation of phenol to 1,4 hydroquinone. This work has been published in the New Journal of Chemistry’ recently.

Electrochemical organic transformations are being looked at with great interest these days because of the economic and environmental advantages they offer over conventional chemical transformation methods. As these transformations are typically carried out in an aqueous medium by just passing electricity through the substrate (in this case phenol), no environmentally hazardous oxidants/reductants are involved in this process. Though electrochemical transformations offer so many advantages, there are several practical issues, especially with respect to phenol oxidation.

For example, the conventional metal-based electrodes could not be used for this transformation as they start losing the activity over time due to the adsorption of the oxidized products on their surfaces. Furthermore, many times they lead to over oxidation of phenol resulting in lack of product selectivity and unwanted product formation (tar). Additionally, some of the electrodes also suffer with issues like physical stability and durability of the electrodes with time.

Through detailed cyclic voltammetric studies, the NCL and CeNS researchers established all these difficulties could be overcome using electrodes having disordered graphene-like structures with desired number of oxygen-bearing surface functional groups such as hydroxyl (-C-OH), carboxyl (-COOH), and carbonyl (-C=O) groups. The surface modification could be achieved again by electrochemical treatment of the electrode in an acidic environment. Based on systematic studies using techniques like Raman spectroscopy and X-ray photoelectron spectroscopy, the researchers established optimum conditions for this surface modification. With such appropriately surface-modified carbonaceous electrodes, the conversion of phenol was excellent (99%) with 87% selectivity to 1,4-hydroquinone.

The researchers are currently looking at other industrially relevant processes that could be accomplished by such environmentally benign electro-organic transformations.



Publication link:

DOI: 10.1039/d1nj04640c

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