The India Centre for Inclusive Growth and Sustainable Development
The India Centre for Inclusive Growth and Sustainable Development

Reducing Greenhouse Gases through Carbon Storage

Project: Greenhouse Gas Reduction Utilising Enhanced Weathering of Indian Industrial and Mine Wastes
 
Researcher: , Royal Society Newton International Fellow, School of Ocean and Earth Science, Faculty of Environment and Life Sciences


Background

Climate change is one of the greatest challenges of our time, driven largely by the relentless increase of atmospheric carbon dioxide (CO鈧). While global efforts focus on reducing emissions, it is becoming increasingly clear that complementary 鈥渘egative emission technologies鈥 will be essential to achieve net zero. One promising approach is enhanced weathering鈥攁 method that accelerates natural rock weathering to capture and permanently store CO鈧.

The project鈥檚 vision is simple yet impactful: turning industrial waste into a climate solution. Each year, India produces enormous quantities of mining tailings, overburden rocks, and industrial by-products such as steel slag and coal fly ash. These materials, often considered environmental liabilities, contain magnesium- and calcium-rich minerals capable of reacting with CO鈧 to form stable bicarbonates. By accelerating this process under controlled conditions, they can act as long-term carbon sinks.

Dr. Asmita Maitra pursued her master and doctorate degree from the Indian Institute of Technology Kharagpur (IIT KGP) India. She has pioneered research into how 滨苍诲颈补鈥檚 vast industrial and mining wastes can be harnessed for climate action. Her project is a unique testament of successful Indo鈥揢K collaboration that combines advanced laboratory science in Southampton with field samples and industrial partnerships in India.

Dr. Maitra presenting her work at the High Commission of India
Dr. Maitra presenting her work at the High Commission of India, London, 9 July, 2025


Objectives

Dr. Maitra鈥檚 research aimed to:

  1. Map and characterize the chemistry, mineralogy, and grain properties of major industrial and mine wastes in India.
  2. Evaluate their carbon dioxide removal (CDR) potential through laboratory simulations of weathering processes.
  3. Develop a methodology for a national inventory of waste streams that could support 滨苍诲颈补鈥檚 climate goals and 鈥済reen mining鈥 policies.

India offers exceptional promise for enhanced weathering: its hot climate accelerates reactions, land availability eases deployment, and the scale of waste generation creates vast feedstock reserves. She collaborates with industry partners including (iron and chromite), (SAIL), (chromite), alongside institutions such as (BARC), (ISRO) and (IIT KGP).

She carried out extensive fieldwork across India, collecting representative samples from iron, copper, and chromite mines, as well as from steel plants and coal-fired power stations. These samples were then rigorously tested in Southampton laboratories using advanced petrographic, geochemical, and reaction experiments.

Key findings

  • Certain mine wastes perform exceptionally well as carbon capture agents, showing higher CO鈧 uptake capacity than conventional basalt鈥攖he benchmark material used globally for mineral carbonation.
  • Industrial by-products such as steel slag and coal fly ash are also highly reactive, providing cost-effective pathways to integrate carbon capture within existing industries.
  • Rock chemistry, mineralogy, and grain size play decisive roles in determining performance, highlighting the importance of careful site-specific selection and processing strategies.
  • 滨苍诲颈补鈥檚 chromite and ultramafic rock waste streams emerged as particularly promising candidates, offering scalable opportunities to align mining with climate solutions.

Crucially, this work demonstrates that enhanced weathering can be integrated into current industrial and mining operations鈥攖ransforming unavoidable waste into a valuable resource for carbon management.
 

Impact

By providing a science-based framework to identify and utilize waste materials for carbon sequestration, Dr. Maitra鈥檚 project directly supports 滨苍诲颈补鈥檚 ambitions for a circular economy and green mining policies. The approach creates a 鈥渨in鈥搘in鈥: capturing CO鈧 while reducing the burden of waste disposal.

On a broader scale, the project:

  • Advances Indo鈥揢K collaboration by combining Indian field resources with UK laboratory expertise. Partnerships with Tata Steel, Coal India Ltd., Odisha Mining Corporation, and cement producers ensure industry relevance and potential for real-world application.
  • Builds capacity for future deployment in India by developing new methods and training early-career researchers in advanced geochemical experimentation.
  • Positions India as a potential global leader in enhanced weathering, with strategies adaptable across both developing and developed economies.

Perhaps most importantly, this work reframes waste as a climate ally. Instead of being seen as a liability, mining and industrial by-products can become part of the solution鈥攍ocking away millions of tonnes of CO鈧 annually if deployed at scale.
 

Future work

The outcomes of this Newton Fellowship project open the door to scalable carbon removal strategies tailored to 滨苍诲颈补鈥檚 geology and industry. The research provides policymakers and industry leaders with evidence-based insights to integrate enhanced weathering into national climate action. It also strengthens Indo鈥揢K scientific collaboration in tackling one of the greatest environmental crises of our era.

As the current project illustrates, climate action often lies not in inventing something entirely new, but in rethinking what we already have. By turning 滨苍诲颈补鈥檚 mine and industrial wastes into tools for carbon capture, this research exemplifies how science can inspire innovative, affordable, and globally impactful climate solutions.