Direct Air Capture Technology (DAC)

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Direct Air Capture Technology (DAC)

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Last year, global carbon dioxide (CO2) emissions hit a record 37 billion metric tons. Consequently, direct air capture technology is gaining traction as governments use it to meet climate goals and combat climate change.

 

Direct Air Capture Technology (DAC)

  • DAC technologies remove CO2 from the atmosphere for storage or utilisation
  • This captured CO2 can be permanently stored in geological formations or used to produce fuels, chemicals, and building materials
  • These methods can contribute to achieving net-zero or net-negative emissions.
  • DAC is being recognised as a crucial technology in the fight against climate change, with over 20 operational plants and 130 more under construction globally.

 

 

Direct Air Capture Technology (DAC)

 

 

Challenges and Solutions:

  • Capturing CO2 from the air is costly because atmospheric CO2 is much more dilute than CO2 in flue gas from power stations or cement plants.
  • This contributes to DAC’s higher energy needs and costs relative to these applications.
  • A study from University of Colorado Boulder highlighted that common methods to reduce energy costs in DAC may not be practical. 
  • The study proposed an alternative method called reactive capture, which involves using electricity to regenerate solutions used for capturing CO2. 
  • However, research found that this method would not effectively regenerate capturing solution in industrial conditions, leading to minimal CO2 capture after multiple cycles.
  • Researchers suggested incorporating electrodialysis into the reactive capture process. 
  • This addition could help maintain the solution’s ability to absorb CO2 and utilise renewable energy sources
  • Furthermore, the process could potentially convert captured CO2 into useful products, such as strengthening concrete, thus addressing multiple environmental challenges simultaneously.

 

Electrodialysis: It is a membrane-based process involving transport of ions through semipermeable membranes using an applied electric field. 

  • The process splits additional water into acidic and basic ions, helping to maintain the basic liquid’s ability to absorb more CO2. 
  • Electrodialysis can run on renewable electricity, making it a potentially sustainable way to turn captured CO2 into useful products.

 

Steps Taken by Government: 

  • India has developed a roadmap and a strategy for a Bio-based economy which is inching towards 150 billion USD by the year 2025
      • This will facilitate infrastructure for Bio-manufacturing of low-carbon bio-based products
  • National Action Plan on Climate Change (NAPCC)
  • Commitment to Net Zero: India is committed to achieve the Net Zero emissions target by 2070. 
  • Energy Conservation (Amendment) Act,2022, aims to accelerate the decarbonisation of the economy.

 

Way Forward: 

  • Innovation in CO2 use opportunities, including synthetic fuels, could drive down costs and provide a market for DAC. 
  • Early commercial efforts to develop synthetic aviation fuels using air-captured CO2 and hydrogen have started, reflecting the important role that these fuels could play in the sector.
  • A start-up based in Mumbai has created an aqueous-based CO2 capture technology featuring a novel catalyst that is durable, cost-efficient, and scalable.
  • This innovation enables the capture of CO2 from industrial wastewater, representing a noteworthy advancement in India’s adoption of eco-friendly technologies.
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