Delhi recorded severe air pollution with AQI over 400 

Why in News?

• Delhi recorded severe air pollution with AQI over 400 on November 12, 2025, prompting public protests.
• Recent environmental studies and disasters, including acid rain trends, glacial lake floods in Uttarkashi, and Cyclone Montha impacts, highlight the growing threat of climate-induced extremes.
• Climate attribution science is increasingly used to link local events to global warming, raising both scientific and policy implications.

Relevance:

• GS 3: Environment & Ecology — climate change attribution, extreme events, disaster-linked pollution.
• GS 3: Disaster Management — GLOFs, cyclone intensification, early warning systems.
• GS 3: Pollution Control — acid rain trends, urban AQI crisis, point vs non-point source emissions.

Background:

• Air Pollution in Delhi:
  • Contributing factors: vehicle emissions, crop residue burning in neighbouring states, Diwali firecrackers, seasonal wind patterns.
  • Health impacts: respiratory ailments, cardiovascular stress, public protests highlighting citizen concern.
• Acid Rain:
  • Studies (IMD & IITM, Pune) show increasing acidity in rainwater over three decades.
  • Local examples: Visakhapatnam (fossil fuel and port emissions), Dhanbad (coal mining emissions, chemical reactions forming secondary pollutants).
• Glacial Lake Outburst Floods (GLOFs):
  • Uttarkashi flash floods (2025) reminiscent of 2013 Kedarnath disaster.
  • Cause: glacier melt, climate change influencing intensity of rainfall and snow melt.
• Cyclone Intensification:
  • Cyclone Montha (October 2025) impacted Andhra Pradesh, with warming seas increasing moisture and storm intensity.

Climate Attribution Science:

• Purpose: Estimates how human-induced climate change alters frequency, intensity, and probability of extreme events.
• Methodology:
  • Models simulate the world without anthropogenic greenhouse gases and compare to observed events.
  • Attribution more accurate for heat waves than extreme rainfall or floods.
  • Uses satellite observations, chemical transport modelling, and historical trends.
• Examples:
  • Kedarnath floods: increased June rainfall linked to rising greenhouse gases and aerosols.
  • Acid rain: linked to specific point sources (power plants, industrial clusters).

Key Observations:

• Point vs Non-Point Sources:
  • Point sources: concentrated emissions (e.g., power plants).
  • Non-point sources: dispersed emissions (vehicles, agriculture).
• Global vs Local Responsibility:
  • India’s cumulative CO2 since 1850 <6%.
  • Developed nations bear larger historical responsibility for climate change.
• Legal and Economic Implications:
  • Advances in climate economics and attribution raise the possibility of climate litigation against major fossil fuel companies.
  • Potential for monetary/injunctive relief for climate-induced damages.

Policy and Strategic Implications:

• Urban Air Quality Management:
  • Strengthen monitoring, regulate vehicular emissions, manage seasonal crop burning.
• Disaster Preparedness:
  • Early warning systems for GLOFs and cyclones.
  • Community awareness and climate-resilient infrastructure.
• Energy Transition:
  • Continue expansion of solar, wind, and battery storage to reduce future emissions.
• Climate Justice:
  • Developed countries may need to compensate developing nations for historical emissions.
• Research & Modelling:
  • Improve climate models for better event attribution, particularly for rainfall and flood events.