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Subject: Environment

  • Blue Button (Porpita porpita) 

    Why in the News

    Large numbers of Porpita porpita, commonly called Blue Button, were recently found washed ashore at Girgaon Chowpatty. This phenomenon is often observed before the onset of the monsoon.

    What is Blue Button

    • A marine organism found floating on the sea surface
    • Not a single organism but a colonial species
    • Composed of multiple zooids working together as one unit
    • Often mistaken for jellyfish

    Key Characteristics

    • Small, disc shaped body with tentacles
    • Free floating organism
    • Each zooid performs specific functions: Feeding, Digestion, and Movement

    Comparison with Similar Species

    • Blue Button (Porpita porpita)
      • Harmless to humans
      • Mild or no sting
    • Portuguese Man o’ War
      • Venomous
      • Can cause painful stings

    Why They Appear on Shores

    • Linked to monsoon onset
    • Caused by:
      • Changes in sea temperature
      • Shifts in ocean currents
      • Strong winds pushing them ashore
    [2021] Which of the following have species that can establish symbiotic relationship with other organisms? 
    1. Cnidarians 
    2. Fungi 
    3. Protozoa 
    Select the correct answer using the code given below. 
    [A] 1 and 2 only [B] 2 and 3 only [C] 1 and 3 only [D] 1, 2 and 3
  • India’s First Green Methanol Plant 

    Why in the News

    India is set to establish its first green methanol plant at Kandla using the invasive plant Prosopis juliflora as feedstock. The project aims to produce clean marine fuel and support India’s transition to green shipping.

    About Prosopis juliflora

    • A Mexican-origin invasive species
    • Known locally as:
      • Vilayati Keekar (North India)
      • Gando Baval (Gujarat)
    • Introduced in India:
      • 1920s by British
      • Later in 1961 in Gujarat to check desertification
    • Problem:
      • Replaces native grasses
      • Harms biodiversity in Banni grasslands (Kutch)

    About Green Methanol

    • Methanol produced using renewable biomass instead of fossil fuels
    • Used as marine fuel replacing bunker oil
    • Helps reduce emissions significantly

    Key Features of the Project

    • Location: Deendayal Port Authority
    • Production capacity: 5 tonnes per day
    • Developed by: Thermax and Ankur Scientific
    • Feedstock:
      • Prosopis juliflora
      • Other biomass like bagasse and cotton stalk
    [2018] Why is a plant called Prosopis juliflora often mentioned in news? 
    (a) Its extract is widely used in cosmetics. 
    (b) It tends to reduce the biodiversity in the area in which it grows. 
    (c) Its extract is used in the synthesis of pesticides. 
    (d) None of the above.
  • Barbary Macaque

    Why in the News

    Scientists studying the Barbary Macaque population in Gibraltar have observed geophagy (soil eating) behavior. This is believed to help them counter the harmful effects of tourist provided junk food.

    About Barbary Macaque

    • One of the 25 species of macaques worldwide
    • The only macaque species found outside Asia
    • The only non human primate in Europe and North Africa

    Distribution

    • Native range:
      • Atlas Mountains in Algeria and Morocco
    • Introduced population: Gibraltar
    • IUCN Red List: Endangered
    [2013] In which of the following states is lion-tailed macaque found in its natural habitat? 
    1 Tamil Nadu
    2 Kerala 
    3 Karnataka 
    4 Andhra Pradesh 
    Select the correct answer using the codes given below: 
    (a) 1, 2 and 3 only (b) 2 only (c) 1, 3 and 4 only (d) 1, 2, 3 and 4
  • Light Pollution Threatens the World’s Clearest Skies

    Why in the News

    Rising Light Pollution and proposed energy projects have raised concerns about the degradation of the pristine night skies in the Atacama Desert, one of the world’s most important hubs for astronomical research.

    What is Light Pollution

    • Light pollution refers to excessive or misdirected artificial light that brightens the night sky and interferes with astronomical observations and ecosystems.

    Key Facts

    • The Atacama Desert is located in Chile
    • Known as the driest place on Earth
    • Receives over 300 clear nights per year
    • High altitude often exceeding 3000 metres
    • Covers around 105000 sq km

    Why is Atacama ideal for Astronomy?

    • Extremely dry climate reduces atmospheric disturbance
    • High altitude ensures clearer observation
    • Minimal light pollution due to isolation
    • Hosts some of the world’s largest ground based telescopes

    Major Astronomical Facilities

    • European Southern Observatory operates key observatories
    • Paranal Observatory is a major site
    • Extremely Large Telescope
      • Cost about 1.5 billion dollars
      • Expected completion by 2030
      • Features 798 mirrors
      • Around 20 times more powerful than current telescopes
    • Compared with Hubble Space Telescope
      • Around 15 times sharper resolution
    [2017] What is the purpose of ‘evolved Laser Interferometer Space Antenna (eLISA)’ project? 
    (a) To detect neutrinos 
    (b) To detect gravitational waves 
    (c) To detect the effectiveness of missile defence system 
    (d) To study the effect of solar flares on our communication systems
  • Why below average-rains don’t rule out flood threats

    Why in the News?

    India’s monsoon narrative is undergoing a structural shift: even below-average seasonal rainfall (92% of normal) no longer guarantees safety from floods. The real concern is the sharp rise in short-duration, high-intensity rainfall events, with extreme rainfall incidents increasing to 181 in 2024 (from 160 in 2023). This marks a decisive break from earlier patterns where floods were linked to overall excess rainfall.

    Why do below-average monsoons no longer reduce flood risks?

    1. Rainfall variability: Seasonal averages conceal intra-seasonal fluctuations, allowing extreme events despite overall deficit rainfall.
    2. Short-duration intensity: Rainfall now occurs in short, intense bursts, increasing runoff and flood risk.
    3. Historical evidence: Major disasters (e.g., 2015 Chennai floods, 2018 Kerala floods, 2023 Himachal floods) occurred even in relatively normal or deficit rainfall years.

    How has the frequency and intensity of extreme rainfall changed over time?

    1. Rising frequency: Extreme rainfall events increased from ~89 (2016) to 181 (2024).
    2. Threshold revision: IMD reduced extreme rainfall threshold from 244.5 mm to 204.5 mm (2016), reflecting changing climate patterns.
    3. Spatial spread: Events are now geographically widespread, affecting both coastal and inland regions.

    What explains the increasing unpredictability of rainfall patterns?

    1. Climate change impact: Warmer atmosphere holds more moisture, leading to intense precipitation events.
    2. Chaotic weather systems: Small initial changes lead to large deviations, limiting forecast accuracy.
    3. Forecast limitations: Even with improved models, predicting exact rainfall intensity (250 mm vs 500 mm) remains difficult.

    Why are Indian cities increasingly vulnerable to rainfall-induced disasters?

    1. Urban flooding: Cities like Delhi, Mumbai, Chennai, Bengaluru face repeated flooding due to poor drainage systems.
    2. Unplanned development: Construction on floodplains, wetlands, and water bodies reduces natural absorption capacity.
    3. Population density: High-density urban clusters amplify economic and human losses.

    What role do past disasters play in understanding current risks?

    1. Disaster clustering: India has experienced at least one major rainfall disaster every year since 2013 (e.g., Kedarnath 2013, Uttarakhand 2021, Assam 2022).
    2. Record-breaking events:
      1. Jammu & Kashmir (2014): Highest rainfall in 100 years.
      2. Kerala (2018): Worst floods in a century.
    3. Trend shift: Disasters are no longer rare but structural features of the monsoon system.

    How has the nature of rainfall-related disasters evolved?

    1. From scarcity to extremes: Earlier focus on rainfall deficiency has shifted to extreme variability.
    2. Urban-centric risks: Flooding increasingly affects urban agglomerations rather than only rural areas.
    3. Economic consequences: States spent over 55% of disaster expenditure on floods (2019-2023), indicating high fiscal burden.

    Conclusion

    India’s monsoon is no longer defined by total rainfall but by distribution, intensity, and timing. The growing disconnect between seasonal averages and disaster outcomes highlights the urgent need for climate-resilient urban planning, improved forecasting systems, and adaptive governance frameworks. The challenge lies not in managing scarcity alone, but in navigating climate-induced volatility.

    PYQ Relevance

    [UPSC 2020] Account for the huge flooding of million cities in India including the smart ones like Hyderabad and Pune. Suggest lasting remedial measures

    Linkage: Increasing extreme rainfall events despite normal/below-normal monsoon directly explain rising urban flooding trends in Indian cities. This PYQ links climatology (monsoon variability) with urban geography issues, making it relevant for both Mains (GS1/GS3) and Prelims (extreme rainfall, IMD classification).

  • Hindu Kush Himalaya (HKH) 

    Why in the News?

    • A report by the International Centre for Integrated Mountain Development highlights a record 27% decline in snow persistence in the HKH region.
    • Indicates accelerating climate change impacts on Asian water systems.

    About Hindu Kush Himalaya (HKH)

    • A vast mountain system extending about 3,500 km
    • Spans 8 countries: Afghanistan, Bangladesh, Bhutan, China, India, Nepal, Myanmar, and Pakistan.

    Why Called “Third Pole”?

    • Largest ice reserves outside Arctic and Antarctic
    • Critical for:
      • Global climate regulation
      • Freshwater supply

    Major Rivers Originating from HKH

    • Indus
    • Ganga
    • Brahmaputra
    • Amu Darya
    • Mekong
    • Yangtze
    • Yellow River
    • Irrawaddy
    • Salween
    • Tarim
    [2012] When you travel in Himalayas, you will see the following: 
    1 Deep gorges 
    2 U-turn river courses 
    3 Parallel mountain ranges 
    4 Steep gradients causing land sliding 
    Which of the above can be said to be the evidence for Himalayas being young fold mountains? 
    (a) 1 and 2 only (b) 1, 2 and 4 only (c) 3 and 4 only (d) 1, 2, 3 and 4
  • [24th April 2026] The Hindu OpED: Scaling climate adaptation from policy to grassroots

    PYQ Relevance[UPSC 2017] Climate change is a global problem. How will India be affected by climate change? How will Himalayan and coastal states of India be affected?Linkage: This is a core GS-III question linking climate vulnerability, sectoral impacts, and regional disparities. It directly tests understanding of adaptation and resilience frameworks.

    Mentor’s Comment

    India’s climate adaptation framework is under scrutiny due to a widening gap between ambitious policy commitments and weak on-ground implementation, especially as the country faces over 430 extreme weather events (1995-2024) costing $180 billion. While adaptation is gaining prominence globally, India’s budgetary tilt towards mitigation over adaptation and fragmented institutional mechanisms make this a critical policy challenge.

    What is climate adaptation?

    1. Climate adaptation is the process of adjusting to the current and expected effects of climate change to minimize harm and take advantage of new opportunities. 
    2. While mitigation focuses on tackling the causes of climate change by reducing greenhouse gas emissions, adaptation focuses on managing its impacts, such as rising sea levels, extreme heatwaves, and erratic rainfall. 
    3. In essence, it is about building resilience to live with a changing climate that is already “in the pipeline” due to historical emissions.

    Why is climate adaptation critical for India’s development trajectory?

    Climate adaptation is critical for India because climate change is no longer just an environmental issue; it is a direct threat to national economic stability and poverty reduction.

    1. Climate Vulnerability: India ranks among the most climate-vulnerable nations with 430 extreme events (1995-2024) causing $180 billion losses; demonstrates systemic risk to growth and livelihoods.
      1. GDP Protection: Heatwaves alone are projected to put 4.5% of India’s GDP at risk by 2030 due to lost labor hours in outdoor sectors like construction and mining.
    2. Policy Recognition: India’s updated NDCs (2022, under Paris Agreement framework) emphasize climate resilience, adaptation mainstreaming, and integration into development planning; align national priorities with evolving global climate commitments.
    3. Sectoral Exposure:Agriculture, infrastructure, biodiversity, water systems face direct climate risks;
      1. Example: National Innovations in Climate Resilient Agriculture (NICRA) targets climate-resilient agriculture in 151 districts.
      2. Water Scarcity: Adaptation involves revitalizing traditional water harvesting (like Amrit Sarovar) to manage the erratic rainfall patterns that currently swing between extreme drought and flash floods.
    4. Livelihood Impact: Vulnerable populations face income instability due to climate shocks; adaptation ensures socio-economic stability.
      1. Preventing Debt Traps: When a climate event (like a crop failure or a destroyed home) occurs, it often pushes families back into poverty. Adaptation measures, like the expansion of climate-indexed insurance, provide a safety net that keeps families socio-economically stable.
      2. Migration Management: Climate adaptation in rural areas reduces “distress migration” to already overcrowded cities, allowing for more planned and sustainable urbanization.

    How effective are India’s existing adaptation initiatives?

    1. Flagship Programme:National Innovations in Climate Resilient Agriculture): By covering 448 villages, it has successfully built a “technology bank” for farmers. Its strength lies in capacity building, teaching farmers to use custom-hiring centres for climate-smart machinery and weather-based crop insurance.
      1. Success Metrics: In the 2024-25 cycle, NICRA’s Technology Demonstration Component (TDC) showed that practices like mulching and zero-tillage increased yields by 13% to 26% even during drought years.
      2. Impact: It has successfully built “climate literacy” for over 3,000 farmers per cluster. It has established local seed banks and community nurseries that allow villages to recover faster after floods or droughts.
    2. Tamil Nadu Climate Resilient Villages (CRV): The Tamil Nadu Climate Resilient Villages (CRV) program is a cornerstone of India’s sub-national climate action. Managed by the Tamil Nadu Green Climate Company (TNGCC), it is often cited as a more holistic model than traditional sector-specific programs because it treats the village as an integrated ecosystem rather than just a farming unit.
      1. Holistic Reach: This model is noted for its community-driven design. By 2025, it helped nearly 2.7 million people across 11 districts by integrating solar energy with practical infrastructure, such as restoring canals to reduce urban/rural flooding.
      2. Outcome: It has shifted from just “agriculture” to “livelihood resilience,” creating green jobs in waste management and coastal restoration (e.g., mangrove touring and hatcheries).
    3. The Integrated “Mitigation-Adaptation” Synergy: India is increasingly using a dual-purpose strategy. For example:
      1. Solar Pumps: These reduce carbon emissions (mitigation) while providing farmers with reliable irrigation during erratic monsoons (adaptation).
      2. Afforestation: Large-scale planting acts as a carbon sink while simultaneously preventing soil erosion and cooling local micro-climates.
    4. Key Shortcomings: The “Scaling” Gap: Despite these successes, the overall effectiveness is hampered by several structural issues:
      1. Fragmented Efforts: Adaptation projects are often spread across different ministries (Agriculture, Water, Environment) with poor inter-departmental coordination, leading to overlapping or conflicting actions.
      2. Lack of Mainstreaming: While 151 districts have NICRA interventions, India has over 700 districts. The transition from pilot projects to national policy is slow.
      3. Funding Constraints: Most initiatives rely on government grants. There is a lack of private sector investment and scalable financial models (like climate bonds) to take these models to every village.
      4. Data Gaps: Real-time monitoring of how these initiatives actually reduce “climate-risk” over a decade is still in its infancy, making it hard to refine strategies.

    What are the financial constraints in scaling adaptation?

    1. Global Finance Gap: Developing countries face $215-387 billion annual gap (UNEP Adaptation Gap Report 2023); indicates structural underfunding.
    2. Domestic Budget Bias: India’s Union Budget prioritizes mitigation over adaptation; reduces resilience-building capacity.
      1. High-visibility projects like Green Hydrogen, solar parks, and EV subsidies receive the bulk of climate-related funding because they have clearer revenue models and private sector appeal.
    3. Return on Investment: According to the World Resources Institute (WRI), every $1 invested in adaptation can yield $2 to $10 in net benefits.
    4. Institutional Financing Gap: Lack of dedicated adaptation financing frameworks at state and district levels.
      1. Grant Dependency: Most adaptation work relies on one-time government grants. There is a critical lack of blended finance (mixing public and private funds) or “Climate Bonds” specifically designed for resilience projects in rural India.

    How can governance and institutional mechanisms be strengthened?

    1. Policy Integration: Aligns adaptation with national and state budgets; ensures institutional accountability.
      1. Climate-Tagged Budgeting: Introducing “Green Budgeting” at the state level ensures that every development rupee spent, whether on roads or schools, accounts for climate resilience.
    2. Revitalizing Planning Frameworks: While National Action Plans (NAP) exist, the real action happens at the sub-national level.
      1. Dynamic SAPCCs: State Action Plans on Climate Change (SAPCCs) must be updated to version 2.0, moving beyond broad goals to specific, actionable, and bankable projects.
      2. Decentralized Implementation: Shifting the focus from state capitals to District and Block-level planning, as climate impacts (like a localized cloudburst) are highly specific to geography.
    3. Precision Data Systems: Promotes climate vulnerability assessments at district/block levels; ensures evidence-based policymaking.
      1. Open-Access Climate Data: Creating a unified national portal for climate data allows local governments, NGOs, and the private sector to use the same scientific baseline for their resilience planning.
    4. Monitoring Mechanisms: Introduces standardized indicators and periodic reviews; ensures outcome tracking.
      1. Standardized Indicators: Introducing a “Resilience Index” for districts to track progress across water security, agricultural yield stability, and disaster recovery times.
      2. Third-Party Audits: Periodic reviews by independent scientific bodies to ensure that “adaptation” projects aren’t just “greenwashed” infrastructure.
    5. Capacity Building: Strengthens institutional and technical capacity; example: climate cells at state/district levels.

    Why is locally led adaptation crucial for climate resilience?

    1. Decentralized Governance: Empowers urban local bodies and Panchayati Raj Institutions; ensures context-specific interventions.
    2. Community Ownership: Enhances participation and accountability; example: CRV consultations with local communities.
    3. Localized Solutions: Adapts interventions to geography; example: flood vs drought-prone regions require different strategies.
    4. Behavioral Change: Builds resilience through awareness and capacity building; ensures long-term sustainability.

    What systemic changes are required to scale adaptation effectively?

    1. Whole-of-System Approach: Integrates governance across sectors and levels; ensures policy coherence.
    2. Cross-Sectoral Coordination: Links agriculture, water, infrastructure, and energy sectors.
    3. Private Sector Role: Encourages investment in adaptation projects; expands financial base.
    4. Continuous Data Collection: Enables real-time monitoring and adaptive policymaking.

    Conclusion

    India’s climate adaptation challenge is not one of policy absence but of execution gaps. Scaling adaptation requires financial prioritization, institutional convergence, and decentralized governance. Integrating local knowledge with national frameworks remains critical for achieving resilience at scale.

  • What are safer fireworks alternatives

    Why in the News?

    There were recent dangerous incidents at Thrissur Pooram, where noise levels reached 122.4 decibels. These exceeded safe limits and triggered animal distress, hospital risks, and infant health concerns. Despite regulations prohibiting firecrackers above 125 dB at 4 metres, enforcement gaps persist. The scale of the problem is significant, noise pollution ranks as the third most hazardous environmental threat, while repeated accidents and fires expose systemic failures in safety management.

    What risks do traditional fireworks pose to health, environment, and safety?

    1. Noise Pollution: Reaches 122.4 dB (Thrissur Pooram), close to legal ceiling of 125 dB; causes hearing damage and stress.
    2. Health Impact: Noise identified as 3rd most hazardous environmental threat; affects cardiovascular health and infant brain development.
    3. Hospital Risk: Proximity to ICUs and neonatal units increases vulnerability due to sudden high-decibel bursts.
    4. Animal Distress: Elephants exhibit disorientation and aggression; example: rampage incidents injuring 42 people.
    5. Fire Hazards: Fireworks units prone to industrial fires; example: April 2025 Mundathikode blaze killing workers.

    What are the existing noise regulations related to firecrackers in India?

    In India, noise standards for firecrackers are primarily governed by Rule 89 of Schedule I of the Environment (Protection) Rules, 1986. These regulations strictly control the manufacture, sale, and use of sound-emitting firecrackers based on specific decibel thresholds and situational bans.

    Permissible Noise Levels: The law categorizes firecrackers into two main types with different noise limits: 

    1. Individual Firecrackers: The maximum noise level must not exceed 125 dB(AI) or 145 dB(C)pk when measured at a distance of 4 metres from the point of bursting.
    2. Joined Firecrackers (Garlands/Laris): The limit for a series of crackers is more stringent. It is calculated using the formula 125 – 5 log10(N) dB. In this formula, N stands for the total number of firecrackers joined together in the series.
    3. Colour & Light Emitting Crackers: These typically have a much lower threshold, with guidelines from the Petroleum and Explosive Safety Organization (PESO) suggesting a limit of 90 dB(AI).

    Why are existing noise regulations insufficient in controlling firecracker hazards?

    1. Regulatory Gap: CPCB norms prohibit >125 dB at 4m, but festival-level bursts exceed ambient limits (45-55 dB). However, the Noise Pollution (Regulation and Control) Rules, 2000, set the ambient residential limit at only 55 dB during the day.
    2. The Failure of “Individual” Metrics: Regulations suffer from a Context Mismatch:
      1. Unit vs. Event: Standards are tested on a single cracker in a controlled environment. They do not account for synchronized bursts (like laris or garlands) or the cumulative noise of thousands of people bursting crackers simultaneously.
      2. Echo Effect: In dense urban “canyons,” sound reflects off buildings, magnifying the decibel level far beyond the 125 dB limit measured in open-field tests.
    3. Enforcement Failure:
      1. Real-Time Absence: Most high-risk zones lack automated, real-time decibel monitoring. Data is often collected manually and analyzed weeks later, rendering it useless for immediate intervention.
    4. The Green Cracker Myth: While Green Crackers are meant to reduce noise by 30%, local testing laboratories often lack the specialized equipment to verify these claims at the point of sale.

    What are ‘cold spark’ or noiseless fireworks and how do they work?

    ‘Cold spark’ fireworks (often called Cold Spark Machines or Sparkulars) are a high-tech, pyrotechnic-free alternative to traditional fireworks. Unlike traditional displays that rely on gunpowder and combustion, these machines use chemistry and physics to create a fountain of sparks that is safe to touch.

    1. Technology Base: Instead of black powder, the machines use a special “granule” or fine alloy powder, typically made of titanium and zirconium.
    2. Mechanism: The machine feeds these granules into a heating chamber. The powder reacts with oxygen as it is blown upward by a fan, creating bright, glowing sparks through incandescence rather than a chemical explosion.
    3. Temperature Control: This is the “cold” part, traditional sparklers burn at a dangerous 1000-1200°C. Cold spark jets operate between 60°C and 100°C. The sparks cool down almost instantly as they hit the air, making them safe for indoor use and proximity to people.

    Key Visual & System Features

    1. Noiseless Performance: Because there is no explosive “boom” or sudden expansion of gases, the only sound produced is the whirring of the internal fan.
    2. Adjustable Displays: Users can control the height (usually 2 to 5 metres) and duration of the sparks via a DMX controller, similar to stage lighting.
    3. Deployment: They are designed to be used in arrays or clusters. By syncing multiple machines, operators can create “waves” or “curtains” of sparks that mimic the look of traditional silver fountains.

    Are noiseless fireworks a viable substitute for traditional pyrotechnics?

    1. Safety Advantage: Eliminates explosion risk, burn injuries, and high-decibel noise.
    2. Environmental Benefit: Reduces smoke and particulate pollution significantly.
    3. Operational Flexibility: Can be used indoors and near sensitive zones like hospitals.
    4. Cost Constraint: High cost-₹400 per cold anar; limits mass adoption.
    5. Import Dependence: Majority manufactured in China, indicating lack of domestic production capacity.

    What challenges hinder large-scale adoption of safer alternatives?

    1. Economic Barrier: High costs discourage use in mass public festivals.
    2. Technological Gap: Limited indigenous R&D and manufacturing ecosystem.
    3. Cultural Resistance: Traditional fireworks linked with heritage festivals like Pooram.
    4. Skill Deficit: Requires professional management and technical expertise.
    5. Policy Vacuum: No clear transition roadmap or incentives for safer alternatives.

    What transition strategy is being proposed for events like Thrissur Pooram?

    1. Incremental Shift: Gradual replacement rather than immediate ban on fireworks.
    2. Pilot Implementation: Testing large-scale spark-based displays in Thrissur.
    3. Hybrid Models: Combining visual spectacle with reduced noise emissions.
    4. Institutional Responsibility: Local bodies like Thrissur Corporation tasked with transition.
    5. Urban Application: Potential expansion to cities like Delhi (post high-noise Diwali concerns).

    Conclusion

    The debate reflects a structural shift from tradition-centric celebration to safety-centric innovation. While cold spark technology offers a viable pathway, its success depends on policy support, cost reduction, and cultural adaptation. The challenge lies not in eliminating fireworks, but in redefining them sustainably.

    PYQ Relevance

    [UPSC 2024] Industrial pollution of river water is a significant environmental issue in India. Discuss the various mitigation measures to deal with this problem and also the government’s initiatives in this regard.

    Linkage: The PYQ highlights pollution mitigation frameworks, directly applicable to managing noise and air pollution from fireworks. It reinforces need for technological and regulatory interventions (e.g., cold spark alternatives) similar to industrial pollution control strategies.

  • Extreme heat threatens global food systems, UN agencies warn

    Why in the News?

    A new joint report released for Earth Day 2026 by the Food and Agriculture Organization (FAO) and the World Meteorological Organization (WMO) confirms that extreme heat has become a “systemic risk multiplier” pushing global agri-food systems to the brink. The report, titled “Extreme Heat and Agriculture,” warns that these conditions now threaten the livelihoods and health of over one billion people.

    How is extreme heat reshaping global agri-food systems?

    Critical physiological limits are already being breached in major global breadbaskets: 

    1. Thermal stress thresholds: Exceeding critical temperature levels triggers crop failure, reduced yields, and ecosystem imbalance.
      1. Major Crops: Yields for staples like wheat, potatoes, and barley begin a sharp decline once temperatures exceed 30 degree celsius
      2. Livestock: Physiological stress starts at 25 degree celsius. Pigs and poultry are most vulnerable because they cannot sweat, leading to reduced dairy yields, growth issues, and mortality.
    2. System disruption: Alters crop cycles, fish migration, and forest productivity.
      1. Compound Hazards: Heat accelerates “flash droughts,” intensifies wildfires, and fosters the rapid spread of pests and diseases, such as locust swarms.
      2. Fisheries and Oceans: In 2024, 91% of the world’s oceans experienced at least one marine heatwave. This depletes oxygen levels, causing cardiac failure in fish and leading to economic losses in fisheries valued at over 6 billion.
      3. Forestry and Ecosystems: Extreme heat disrupts photosynthesis and has suppressed forest productivity by up to 50% in some regions. 
    3. Livelihood impact: Threatens over 1 billion people dependent on agriculture and allied sectors.
      1. Labour Loss: Heat already causes the loss of roughly 500 billion working hours annually.
      2. Unsafe Working Conditions: In regions like South Asia and sub-Saharan Africa, the number of days “too hot to work” could rise to 250 per year.
      3. Economic Vulnerability: Poor households lose an average of 5% of their annual income to heat stress, with female-headed households in rural low-income countries suffering losses up to 8%. 

    What are the impacts on crop production and food security?

    1. Yield reduction: The 6 percent rule: Each 1°C temperature rise reduces maize, rice, soy, and wheat yields by ~6%
    2. Economic Toll: In low-income countries alone, heat stress causes an average annual loss of $37 billion in crop production.
    3. Photosynthesis disruption: Heat doesn’t just stop growth; it forces plants to burn through their own energy:
      1. Night-time Stress: High night temperatures are particularly damaging because they increase respiration rates. Instead of storing energy for grain production, the plant consumes its carbon reserves just to survive the night.
      2. Energy Depletion: This metabolic imbalance leads to stunted plants and significantly smaller, less nutritious grains and fruits.
    4. Reproductive failure: Extreme heat acts as a “biological kill switch” during the most sensitive stage of a plant’s life: flowering.
      1. Pollen Sterility: In crops like rice and maize, temperatures exceeding critical thresholds during flowering cause pollen to dry out or become sterile.
      2. Empty Husks: This leads to a phenomenon known as “blanking” or “blindness,” where the plant appears healthy but produces empty husks or pods because fertilization never occurred. Even a few hours of extreme heat at the wrong time can wipe out an entire season’s potential.
    5. Compounding Food Security Risks: These biological failures create a domino effect on global food stability:
      1. Nutritional Insecurity: Beyond volume, heat stress reduces the protein and micronutrient content in staples like wheat and rice.
      2. Price Volatility: As major “breadbasket” regions hit these thermal ceilings simultaneously, global markets face supply shocks and rapid food price inflation.

    How does extreme heat affect livestock productivity?

    1. Heat stress: Triggered by high thermal humidity index levels.
    2. Milk production decline: Drops by up to 15-25% in dairy cattle.
    3. Fertility reduction: Significant decrease in reproductive efficiency.
      1. Reduced Conception: High Temperature Humidity Index (THI) levels lead to poor estrus expression and hormonal imbalances, with conception rates dropping to nearly 0% in severe conditions.
      2. Embryonic Mortality: Heat causes direct damage to developing embryos and oocytes, leading to higher rates of early embryonic loss and smaller, weaker offspring.
      3. Male Fertility: Spikes in temperature cause sperm deformity and reduced motility, sometimes resulting in temporary or permanent infertility in bulls and boars. 
    4. Poultry mortality: The report warns of an escalation in “mass mortality events”. Extreme temperature spikes cause mass deaths in farms lacking climate control.
    5. Disease and Immune Suppression: Heat stress compromises the immune system, making livestock more susceptible to existing and emerging pathogens. Altered temperature patterns also expand the range of disease-carrying vectors, such as those responsible for Foot and Mouth disease.

    Why are marine ecosystems increasingly vulnerable?

    1. Marine heatwaves: Marine heatwaves (MHWs) are now more frequent, longer-lasting, and more intense. By 2024, nearly the entire global ocean surface was impacted, compared to only 60% in 2021.
      1. Systemic Exposure: These events are no longer restricted to surface waters; they are reaching depths of 30-50 metres and even the seafloor, leaving sedentary species like coral and kelp with no “thermal refuge
    2. Ocean stress: 91% of oceans experienced at least one marine heatwave in 2024.
    3. Oxygen depletion: Reduces fish survival and productivity.
      1. Deoxygenation: Warmer water holds less dissolved oxygen. This creates hypoxic (low-oxygen) conditions that can lead to cardiac failure and mass mortality in fish populations.
      2. Metabolic Strain: Heat increases the metabolic rates of marine animals, meaning they require more food to survive exactly when their food supply, like plankton, is being disrupted by the same heat stress. 
    4. Fish stock decline: Around 15% of global fisheries have already been significantly impacted by extreme heat incidents.
    5. Disruption of Foundation Species
      1. Ecosystem Collapse: MHWs are “biological wildfires” that decimate foundation species such as coral reefs, kelp forests, and seagrass meadows.
      2. Habitat Loss: The loss of these “nurseries” triggers a domino effect, stripping away the shelter and food sources for thousands of other species.

    How does extreme heat act as a risk multiplier?

    The FAO and WMO joint report defines extreme heat as a “risk multiplier” because it does not just act alone; it creates a domino effect by magnifying existing vulnerabilities and triggering compound climate hazards. 

    1. Drought intensification: Reduces water availability for crops.
      1. Evaporative Stress: Heat-driven evaporation significantly reduces irrigation capacity. For example, a 2025 heat event in Kyrgyzstan saw temperatures 10 degree celsius above normal, which slashed irrigation and contributed to a 25% decline in cereal harvests.
      2. Case Study: In Brazil (2023-2024), extreme heat combined with drought cut soybean yields by up to 20%.
    2. Wildfires escalation: There is a direct, strong correlation between heatwaves and more catastrophic fire seasons:
      1. Vegetation Drying: Prolonged heat dries out forests and rangelands, turning them into highly combustible fuel.
      2. Case Study: Portugal’s 2017 fire season, driven by extreme heat, burned a record 540,000 hectares and caused over 1.2 billion in losses.
      3. Carbon Feedback: Wildfires triggered by heat turn natural carbon sinks (forests) into net carbon sources, accelerating global warming further. 
    3. Pest outbreaks:
      1. Increased Survival: Warm winters and extreme summer heat often increase the survival and reproduction rates of pests.
      2. Pest Migrations: Heatwaves have been specifically linked to sudden outbreaks, such as locust swarms in Central Asia following thermal shocks to crops.
    4. Combined impact: Amplifies food insecurity risks across regions.
      1. Cascading Failures: A single heat event can simultaneously wither crops, kill livestock, dry forests, and make it fatal for agricultural labourers to work outdoors, who may face up to 250 “unworkable” days per year in South Asia and sub-Saharan Africa.
      2. Market Volatility: By triggering simultaneous failures across different sectors (crops, fisheries, and forests), extreme heat overwhelms local economies and drives global food price spikes. 

    Why are current policy responses inadequate?

    1. Fragmented governance: Lack of integrated climate-agriculture strategies.
    2. Insufficient early warning systems: Limits preparedness for farmers and fishers.
    3. The “Relief vs. Resilience” Trap: Most funding is currently locked into a reactive cycle:
      1. Post-Disaster Focus: Significant resources are spent on emergency food aid and disaster relief after a crop failure has already occurred.
      2. Underinvestment in Prevention: There is a chronic lack of funding for long-term adaptation, such as developing heat-tolerant seed varieties, building sustainable irrigation, or establishing heat-indexed insurance that pays out before the crop dies.

    What solutions are suggested for mitigation and adaptation?

    1. Risk governance: Strengthens institutional response frameworks.
      1. National Heat Action Plans: Moving beyond urban areas to include specific agricultural protocols.
    2. Early warning systems: Enables preventive action for climate shocks.
      1. The Last Mile: Using SMS, radio, and local cooperatives to deliver hyper-local forecasts.
    3. Climate-resilient agriculture: Promotes heat-resistant crop varieties.
      1. Adaptive Breeding: Investing in “orphan crops” (like millets or sorghum) that are naturally heat-tolerant and developing new varieties of staples that can survive temperatures above 30 degree celsius
      2. Nature-Based Solutions: Expanding agroforestry (planting trees among crops) to create micro-climates that reduce ambient temperatures by several degrees.
      3. Livestock Management: Retrofitting farms with solar-powered ventilation and shifting grazing cycles to cooler night-time hours.
    4. Technological and financial integration: Supports forecasting and adaptive farming.
      1. Digital Twins: Using satellite data to create digital models of farms to predict where “flash droughts” are most likely to hit.
      2. Anticipatory Finance: Expanding weather-indexed insurance. These programs trigger automatic cash payouts to farmers as soon as a temperature threshold is crossed, providing the liquidity needed to buy extra water or cooling equipment before the crop fails.

    Conclusion

    Extreme heat is transitioning from an environmental issue to a systemic economic and food security crisis. Addressing it requires integrated climate governance, technological intervention, and proactive adaptation strategies.

    PYQ Relevance

    [UPSC 2017] Climate Change’ is a global problem. How will India be affected by climate change? How Himalayan and coastal states of India are affected by climate change?

    Linkage: The PYQ directly connects to climate-induced extreme heat impacts on agriculture, livestock, and fisheries, central to the article. It provides contemporary data (yield loss, marine heatwaves, heat stress) to enrich answers on regional vulnerability (Himalayan, coastal, agrarian systems).

  • Extreme Heat & Global Food Systems 

     Why in the News?

    • A joint report by the Food and Agriculture Organization and World Meteorological Organization warns that extreme heat is threatening global agrifood systems, impacting over a billion people.

    Key Findings

    • Heatwaves are: More frequent, More intense, and Longer-lasting
    • Crop yields decline sharply beyond: ~30°C threshold
      • Example: Morocco saw 40% fall in cereal yield
    • Impact on Major Crops: Every 1°C rise in temperature leads to:
      • ~6% reduction in yields of: Maize, Rice, Wheat, and Soybean
    • Marine Impact: Marine heatwaves: Reduce oxygen in oceans and Threaten fish stocks
      • In 2024: 91% of oceans experienced marine heatwaves
    • Risk Escalation:
      • 2°C warming → heat intensity doubles
      • 3°C warming → heat intensity quadruples
    • Livestock Impact
      • 15–25% drop in milk production
      • Reduced fertility
      • Poultry mortality
    [2014] The scientific view is that the increase in global temperature should not exceed 2°C above pre-industrial level. If the global temperature increases beyond 3°C above the pre-industrial level, what can be its possible impact/impacts on the world? 
    1 Terrestrial biosphere tends toward a net carbon source. 
    2 Widespread coral mortality will occur. 
    3 All the global wetlands will permanently disappear. 
    4 Cultivation of cereals will not be possible anywhere in the world. 
    Select the correct answer using the code given below. 
    a) 1 only b) 1 and 2 only c) 2, 3 and 4 only d) 1, 2, 3 and 4