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  • Coral Reefs in the Gulf of Eilat recover after a ‘Shutdown’

    Why in the News?

    Researchers have discovered a significant pause in coral reef growth in the Gulf of Eilat/Aqaba during the late Holocene period.

    Key Highlights of the Study:

    • The study identified a 4,400 – 1,000-year hiatus in coral growth, similar to events observed in Mexico, Brazil, and Australia.
    • Scientists attribute this temporary halt to a sea-level drop caused by tectonic activity and cooling events, which exposed coral reefs and disrupted their development.
    • Despite this, the reef recovered by recolonizing from deeper coral communities, showcasing its natural resilience.

    Coral Reefs in the Gulf of Eilat recover after a ‘Shutdown'

    About Gulf of Eilat

    • Also known as the Gulf of Aqaba, it is a narrow extension of the Red Sea, located between the Sinai Peninsula (Egypt) and the Arabian Peninsula.
    • It connects to the Red Sea through the Strait of Tiran and borders Egypt, Israel, Jordan, and Saudi Arabia.
    • The city of Eilat (Israel) and Aqaba (Jordan) lie along its shores, making it a strategic trade and tourism hub.

    Geographical and Political Significance:

    • Strategic Trade Route: Provides access to the Indian Ocean via the Red Sea, critical for Israel and Jordan’s maritime trade.
    • Bordering Multiple Nations: Shares coastlines with Egypt, Israel, Jordan, and Saudi Arabia, making it a key area for regional diplomacy and security.
    • Tourism & Marine Biodiversity: Known for coral reefs and marine life, attracting divers and boosting the economies of Eilat and Aqaba.
    • Geopolitical Sensitivity: The Strait of Tiran has been historically significant in Arab-Israeli conflicts, especially during the Six-Day War (1967) when Egypt blocked Israeli access.
    • Energy & Trade Importance: It is an alternative route for oil shipments and goods trade, reducing reliance on the Suez Canal.

    PYQ:

    [2014] Which of the following have coral reefs?

    1. Andaman and Nicobar Islands

    2. Gulf of Kachchh

    3. Gulf of Mannar

    4. Sunderbans

    Select the correct answer using the code given below:

    (a) 1, 2 and 3 only

    (b) 2 and 4 only

    (c) 1 and 3 only

    (d) 1, 2, 3 and 4

     

  • Loggerhead Turtles use Geomagnetic Field to navigate large Distances

    Loggerhead Turtles use Geomagnetic Field to navigate large Distances

    Why in the News?

    A new study in Nature reveals that loggerhead turtles can learn and remember the magnetic signature of an area, using Earth’s geomagnetic field for navigation during long migrations.

    About Loggerhead Sea Turtles (Caretta caretta)

    • Loggerhead Sea Turtles belong to the Cheloniidae family, widely distributed across the world’s oceans.
    • They are commonly found in Atlantic, Pacific, Indian Oceans, and the Mediterranean Sea.
    • They Spends most of its life in saltwater and estuarine habitats, coming ashore only to nest.
    • They are omnivorous, feeding primarily on bottom-dwelling invertebrates.
    • It is listed as Vulnerable by the International Union for Conservation of Nature (IUCN).
    • International trade banned under CITES Appendix I.

    Significance of the study

    • Loggerhead turtles travel thousands of kilometers across oceans and return to the same feeding and nesting sites.
    • Their ability to store magnetic memories helps them navigate vast distances, reinforcing the hypothesis that other migratory species may also rely on Earth’s magnetic field.

    PYQ:

    [2019] Consider the following statements:

    1. Some species of turtles are herbivores.
    2. Some species of fish are herbivores.
    3. Some species of marine mammals are herbivores.
    4. Some species of snakes are viviparous.

    Which of the statements given above are correct?

    (a) 1 and 3 only
    (b) 2, 3 and 4 only
    (c) 2 and 4 only
    (d) 1, 2, 3 and 4

     

  • What is the Cancer Vaccine Russia is offering?

    Why in the News?

    In December 2024, Russia announced the development of a new mRNA-based personalized cancer vaccine, with plans to make it available for free to patients by early 2025.

    What is mRNA (Messenger RNA)?

    • mRNA is a type of RNA that transports genetic information from DNA to ribosomes, guiding the production of proteins.
    • It tells the cell which proteins to make by providing the exact sequence of amino acids.
    • Unlike DNA, mRNA does not stay in the cell permanently; it gets degraded after protein synthesis.
    • mRNA-based vaccines (like COVID-19 vaccines) teach cells to produce harmless viral proteins, triggering an immune response.

    What is an mRNA Cancer Vaccine?

    • Unlike traditional vaccines, mRNA vaccines provide genetic instructions to train the immune system to detect and attack cancer cells.
    • This technology gained prominence with the COVID-19 vaccines (Pfizer-BioNTech, Moderna) and is now being adapted for cancer treatment.
    • These vaccines are therapeutic, designed for patients who already have cancer, not for prevention.

    How do mRNA Cancer Vaccines Work?

    • Cancer cells evade the immune system by suppressing immune responses.
      • Immunotherapy works by enhancing the body’s natural ability to detect and destroy these cancerous cells.
    • Unlike chemotherapy, which kills both healthy and cancerous cells, immunotherapy selectively targets only cancer cells, reducing harmful side effects.
    • mRNA cancer vaccines are customized for each patient, targeting specific tumor antigens, making them highly personalized and potentially more effective.
    • While traditional infectious disease vaccines prevent illness, mRNA cancer vaccines are therapeutic, meaning they are administered to patients who already have cancer to help their immune system fight the disease.

    PYQ:

    [2019] RNA interference (RNAi)’ technology has gained popularity in the last few years. Why?

    1. It is used in developing gene silencing therapies.
    2. It can be used in developing therapies for the treatment of cancer.
    3. It can be used to develop hormone replacement therapies.
    4. It can be used to produce crop plants that are resistant to viral pathogens.

    Select the correct answer using the codes given below:

    (a) 1, 2 and 4

    (b) 2 and 3

    (c) 1 and 3

    (d) 1 and 4 only

     

  • Sṛjanam- India’s first indigenous Automated Bio Medical Waste Treatment Plant

    Why in the News?

    Union Ministry of Science & Technology has launched India’s first indigenous Automated Biomedical Waste Treatment Plant, named “Sṛjanam,” at AIIMS, New Delhi.

    About Sṛjanam

    • Sṛjanam is India’s first indigenously developed Automated Biomedical Waste Treatment Rig, designed by CSIR-NIIST, Thiruvananthapuram.
    • It provides a sustainable, non-incineration-based solution for biomedical waste disposal, aligning with India’s Waste to Wealth vision.
    • Key Features:
      • Eco-Friendly & Non-Incineration-Based: Eliminates the need for incineration, reducing toxic emissions.
      • High-Efficiency Pathogen Elimination: Disinfects blood, urine, sputum, and lab disposables, with third-party validated antimicrobial action.
      • Safe & Fully Automated: Minimizes human exposure, reducing the risk of infections and spills.
      • Capacity & Scalability: Processes 400 kg of biomedical waste daily, with 10 kg/day degradable waste capacity in phase one.
      • Odor Neutralization: Eliminates foul smells, ensuring safer surroundings.
      • Supports Circular Economy: Enhances waste segregation and recyclability, reducing landfill burden.

    PYQ:

    [2019] In India, ‘extended producer responsibility’ was introduced as an important feature in which of the following?

    (a) The Bio-medical Waste (Management and Handling) Rules, 1998

    (b) The Recycled Plastic (Manufacturing and Usage) Rules, 1999

    (c) The e-Waste (Management and Handling) Rules, 2011

    (d) The Food Safety and Standard Regulations, 2011

     

  • Scientists discover ‘Einstein Ring’

    Why in the News?

    The European Space Agency’s (ESA) Euclid Space Telescope has captured a rare Einstein Ring around a galaxy nearly 590 million light-years away from Earth.

    Scientists discover ‘Einstein Ring’

    What is an Einstein Ring?

    • An Einstein Ring is a circular ring of light caused by gravitational lensing, a phenomenon predicted by Einstein’s General Theory of Relativity.
    • It occurs when a massive celestial object (like a galaxy) bends and magnifies light from a more distant background galaxy that lies directly behind it.
    • The recent discovery by ESA’s Euclid telescope identified an Einstein Ring around NGC 6505, located 590 million light-years away, acting as a lens for a distant galaxy 4.42 billion light-years away.
    • Features of an Einstein Ring:
      • Perfect circular shape (only if source, lens, and observer align precisely).
      • Example of strong gravitational lensing, distorting background light.
      • Extremely rare (found in less than 1% of galaxies).
      • Not visible to the naked eye, observed only with advanced space telescopes like Euclid or Hubble.

    Significance of the Discovery:

    • Reveals Dark Matter: Helps indirectly map dark matter, which makes up 85% of the universe.
    • Magnifies Hidden Galaxies: Makes faint, distant galaxies visible for study.
    • Measures Universe’s Expansion: Tracks how light stretches over time, refining cosmological models.
    • Confirms Einstein’s Theory: Proves light bends in curved space-time, supporting gravitational lensing theory.
    • Demonstrates Euclid’s Capabilities: Shows Euclid’s high-resolution potential, promising more discoveries.

    PYQ:

    [2018] Consider the following phenomena:

    1. Light is affected by gravity.
    2. The Universe is constantly expanding.
    3. Matter warps its surrounding space-time.

    Which of the above is/are the prediction/predictions of Albert Einstein’s General Theory of Relativity, often discussed in media?

    (a) 1 and 2 only
    (b) 3 only
    (c) 1 and 3 only
    (d) 1, 2 and 3

     

  • Prime Minister Dhan-Dhaanya Krishi Yojana (PMDKY)

    Why in the News?

    Finance Minister while presenting the Union Budget announced the launch of the Prime Minister Dhan-Dhaanya Krishi Yojana (PMDKY).

    About the Prime Minister Dhan-Dhaanya Krishi Yojana (PMDKY):

    • The PMDKY aims to enhance agricultural productivity, crop diversification, storage infrastructure, irrigation, and credit access.
    • Key Features
      • Identifies 100 districts with low productivity, moderate cropping intensity, and below-average credit access.
      • Develops panchayat/block-level storage and expands irrigation coverage.
      • Ensures affordable short-term & long-term loans for farmers.
      • Uses data-driven governance & district rankings.
    • Structural Mandate:
      • Implementation: Jointly executed by Central & State Governments.
      • Funding: Drawn from existing schemes under the Ministry of Agriculture & Farmers’ Welfare and the Ministry of Fisheries, Animal Husbandry & Dairying.
      • Evaluation: Assessed based on yield improvements, credit flow, and irrigation expansion.

    PYQ:

    [2015] ‘Pradhan Mantri Jan-Dhan Yojana’ has been launched for:

    (a) providing housing loan to poor people at cheaper interest rates

    (b) promoting women’s Self-Help Groups in backward areas

    (c) promoting financial inclusion in the country

    (d) providing financial help to the marginalized communities

     

  • PARAS-2 Spectrograph

    Why in the News?

    Scientists at PRL, Ahmedabad, discovered the exoplanet TOI-6038A b, a dense sub-Saturn-sized planet with a mass of 78.5 Earth masses and a radius of 6.41 Earth radii, using the PARAS-2 spectrograph at Mount Abu Observatory.

    About TOI-6038A b

    • TOI-6038A b is a dense sub-Saturn-sized planet with a mass of 78.5 Earth masses and a radius of 6.41 Earth radii, orbiting a bright, metal-rich F-type star every 5.83 days in a circular orbit.
    • This is the 2nd exoplanet discovery using the PARAS-2 spectrograph.
    • It is also the 5th exoplanet detection combining efforts of PARAS-1 and PARAS-2, showcasing India’s growing expertise in astronomical instrumentation.

    About PARAS-2 Spectrograph:

    • PARAS-2 (PRL Advanced Radial-velocity All-sky Search-2) is a state-of-the-art high-resolution spectrograph designed for exoplanet detection.
    • The development of PARAS-2 began in mid-2018 and was successfully installed at the telescope site in mid-2022.
    • It is the highest-resolution stabilized radial velocity (RV) spectrograph in Asia, operating at a precision level of 30 cm/s.
    • It is installed at PRL’s 2.5-meter telescope at the Mount Abu Observatory, benefiting from high-altitude, clear sky conditions.
    • Key Features of PARAS-2:
      • Operates in the 380-690 nm waveband, making it suitable for studying a wide range of celestial objects.
      • Resolution of ~107,000, the highest in Asia, enabling ultra-precise exoplanetary studies.
      • Ultra-stable temperature and pressure environment: Maintained at 24 ± 0.001 °C and 0.005 ± 0.0005 mbar, ensuring minimal instrumental drift.
      • Uses a Uranium Argon Hollow Cathode Lamp (UAr HCL) for calibration, achieving a velocity precision of better than 2 m/s.
      • Advanced optical fiber system for capturing stellar light and spectral calibration data simultaneously.
    • It uses the radial velocity method, which detects tiny wobbles in a star’s motion caused by the gravitational pull of an orbiting planet.
    • These wobbles cause shifts in the star’s light spectrum, allowing scientists to determine a planet’s presence, mass, and orbital period.
    • It can detect minute stellar movements, making it ideal for finding low-mass exoplanets like super-Earths.

    PYQ:

    [2015] The term ‘Goldilocks Zone’ is often seen in the news in the context of:

    (a) the limits of habitable zone above the surface of the Earth
    (b) regions inside the Earth where shale gas is available
    (c) search for the Earth-like planets in outer space
    (d) search for meteorites containing precious metals

     

  • New Fishing Grounds discovered in Arabian Sea 

    Why in the News?

    A deep-sea fishing expedition conducted by the Fishery Survey of India (FSI) has uncovered several highly productive and previously unexplored fishing grounds in the Arabian Sea.

    Key Findings of the Deep-Sea Survey:

    • Fishing was conducted at depths between 300-540 meters using deep-sea trawlers.
    • The survey was funded under the Pradhan Mantri Matsya Sampada Yojana (PMMSY).
    • It mapped potential deep-sea fishing zones 100-120 nautical miles off India’s western coast, stretching from Kollam in Kerala to Goa.

    About Fishery Survey of India (FSI)

    • FSI was established in 1983, under the Ministry of Fisheries, Animal Husbandry & Dairying.
    • It conducts fisheries research, resource surveys, and sustainable fishing assessments.
    • It operates annual Fishery Resource Surveys to guide:
      • Traditional fishermen
      • Small and medium boat operators
      • Deep-sea longlining tuna fleet
    • History of FSI:
      • Originated from the “Deep Sea Fishing Station” project (1946).
      • Renamed “Exploratory Fisheries Project” (1974) and later “Fishery Survey of India” (1983).
      • In 2005, Marine Engineering Division was integrated into FSI.
      • In 2017, PM Narendra Modi launched the Deep-Sea Fishing Project to promote sustainable fishing practices.
    • Capabilities of FSI:
      • Operates 11 ocean survey vessels across six major Indian ports.
      • Employs 752 personnel, conducting deep-sea research and data collection.

    India’s Marine Fishing Industry

    • India ranks second in global fish production after China.
    • Contributes 9.58 million tonnes of total fish production, with:
      • 70% from the west coast
      • 30% from the east coast
    • Major fish-producing states: Andhra Pradesh (20%), West Bengal (15%), Gujarat (8%), Kerala (7%), Maharashtra (6%), Tamil Nadu (6%).
    • Exports and Global Trade:
      • India exports 1.05 million tonnes of marine fish, generating ₹334.4 billion ($5.57 billion) in revenue.
      • Major export markets: USA (26%), ASEAN nations (26%), EU (20%), Japan (9%), Middle East (6%), China (4%).

     

    PYQ:

    [2018] Defining blue revolution, explain the problems and strategies for pisciculture development in India.

    [2022] What is Integrated Farming System? How is it helpful to small and marginal farmers in India?

     

  • Brahmagiri Wildlife Sanctuary

    Why in the News?

    The Karnataka government’s move to build a tribal village in Brahmagiri Wildlife Sanctuary’s buffer zone has sparked debates on environmental conservation, tribal rights, and human-wildlife conflict.

    Brahmagiri Wildlife Sanctuary

    About Brahmagiri Wildlife Sanctuary:

    • The Brahmagiri WLS is located in Kodagu District, Karnataka, within the Western Ghats.
    • It serves as a crucial ecological corridor, facilitating wildlife movement between Nagarhole National Park and Wayanad Wildlife Sanctuary.
    • Geographical Location and Features
      • It is situated approximately 250 km from Bengaluru and derives its name from the Brahmagiri Peak, the highest point in the region.
      • The sanctuary was declared a protected area on June 5, 1974, to conserve its unique flora and fauna.
      • The terrain consists of evergreen and semi-evergreen forests, grasslands, and shola forests, which provide a habitat for various species.
    • Flora:
      • Bamboo species are widely spread across the region, providing food for herbivores like elephants and deer.
      • The diverse vegetation supports a wide range of faunal species by offering food, shelter, and nesting sites.
    • Fauna:
      • Carnivores: Tigers, jungle cats, leopard cats, wild dogs, and sloth bears.
      • Herbivores: Indian elephants, gaurs, sambars, spotted deer, barking deer, mouse deer, and wild pigs.
      • Primates: Lion-tailed macaques, Nilgiri langurs, slender loris, bonnet macaques, and common langurs.
      • Small Mammals & Rodents: Malabar giant squirrels, giant flying squirrels, Nilgiri martens, common otters, brown mongooses, civets, porcupines, and pangolins.
      • Reptiles: King cobras, Indian cobras, pythons, Malabar pit vipers.
      • Birds: Emerald doves, square-tailed bulbuls, and Malabar trogons.

    PYQ:

    [2020] Which one of the following protected areas is well-known for the conservation of a sub-species of the Indian swamp deer (Barasingha) that thrives well on hard ground and is exclusively graminivorous?

    (a) Kanha National Park

    (b) Manas National Park

    (c) Mudumalai Wildlife Sanctuary

    (d) Tal Chhapar Wildlife Sanctuary

     

  • [13th February 2025] The Hindu Op-ed: Nuclear energy — dangerous concessions on liability

    PYQ Relevance:

    Q) Give an account of the growth and development of nuclear science and technology in India. What is the advantage of a fast breeder reactor programme in India? (UPSC CSE 2017)

     

    Mentor’s Comment: UPSC mains have always focused on nuclear science and technology (2017), and atomic energy (2013).

    In the Union Budget speech on February 1, Finance Minister Nirmala Sitharaman announced plans to amend the Atomic Energy Act and the Civil Liability for Nuclear Damage (CLND) Act. This move is likely to be welcomed by the U.S., where past governments have opposed India’s law because it holds nuclear manufacturers partly responsible for accidents. However, in India, removing supplier liability could be a major concern, as it might weaken nuclear safety measures.

     

    Today’s editorial talks about the Atomic Energy Act and the Civil Liability for Nuclear Damage (CLND) Act. This content will help in GS papers 2 and 3 in mains answer writing.

    _

    Let’s learn!

    Why in the News?

    The mention of plans to amend the Civil Liability for Nuclear Damage Act in the Union Budget is a serious issue that needs attention.

    What is the Atomic Energy Act?

    • The Atomic Energy Act, 1962 is an Indian law that regulates the development, production, and use of nuclear energy for peaceful purposes while ensuring national security. It gives the government exclusive control over nuclear materials, plants, and research and allows the establishment of nuclear power projects. The Act also covers radiation safety, uranium mining, reactor operations, and waste disposal to prevent misuse and ensure public safety.

    What is the Civil Liability for Nuclear Damage Act? 

    • The Civil Liability for Nuclear Damage (CLND) Act, 2010 is an Indian law that defines liability in case of a nuclear accident. It ensures compensation for victims while holding nuclear plant operators accountable.

    Key Features:

    • Operator Liability: The primary financial responsibility for any nuclear accident rests with the plant operator (NPCIL in India), not the supplier.
    • Right of Recourse: Unlike many other countries, India allows operators to seek compensation from suppliers if defective equipment or services cause an accident (Section 17).
    • Liability Cap: Operator liability is capped at ₹1,500 crore (~$180 million), with the government covering additional costs if needed.
    • Exclusion from Global Regimes: India has not joined international nuclear liability agreements like the Convention on Supplementary Compensation (CSC), meaning financial responsibility remains domestic.

    What are the safety and liability concerns related to nuclear energy?

    • Risk of Catastrophic Accidents: Nuclear plant failures can lead to massive radiation leaks, environmental destruction, and long-term health impacts.Example: The Fukushima Daiichi disaster (2011, Japan) resulted from a tsunami, causing multiple reactor meltdowns and widespread radioactive contamination.
    • Design Flaws and Negligence: Suppliers may overlook or downplay safety risks in reactor designs, leading to vulnerabilities. Example: The Three Mile Island accident (1979, USA) occurred due to a known reactor design flaw that the supplier failed to address.
    • Limited Liability for Suppliers: In many countries, nuclear suppliers are indemnified, placing financial liability entirely on plant operators and governments.Example: General Electric (GE), which designed the Fukushima reactors, faced no financial consequences due to Japan’s liability laws.
    • Insufficient Compensation for Victims: Liability caps limit compensation for victims, despite the high costs of nuclear disasters. Example: India’s Civil Liability for Nuclear Damage (CLND) Act caps liability at ₹1,500 crore, whereas Fukushima’s cleanup costs are estimated at ₹20-46 lakh crore.
    • Radioactive Waste and Long-Term Risks: Safe disposal of nuclear waste remains a major challenge, with risks of leaks and contamination lasting thousands of years.Example: The Chernobyl disaster (1986, USSR) left a radioactive exclusion zone that remains uninhabitable nearly 40 years later.

    How does India’s approach to nuclear liability differ from global standards?

    • Operator Liability with Limited Supplier Responsibility: India’s Civil Liability for Nuclear Damage (CLND) Act, 2010, places primary liability on the operator (NPCIL), but allows it to seek compensation from suppliers in case of defective equipment or services (Right of Recourse, Section 17).
      • Global Standard: Most countries fully indemnify suppliers, meaning they bear no financial responsibility after supplying reactors.
      • Example: In Japan, General Electric (GE) faced no liability for the Fukushima disaster (2011), while in India, foreign suppliers fear financial risks if an accident occurs.
    • Liability Cap vs. Unlimited Liability in Some Countries: India caps operator liability at ₹1,500 crore (~$180 million), with additional compensation coming from the government if needed.
      • Global Standard: Some countries, like Germany, impose unlimited liability on operators to ensure full compensation. The U.S. Price-Anderson Act establishes a large industry-backed fund for damages beyond a certain limit.
      • Example: After the Chernobyl disaster (1986, USSR), the Soviet government bore the entire cost (~$235 billion), whereas an Indian accident beyond ₹1,500 crore would shift the financial burden to taxpayers.
    • India is Not Part of Global Nuclear Liability Regimes: India has not signed the Convention on Supplementary Compensation for Nuclear Damage (CSC), which standardizes liability norms and creates an international compensation pool.
      • Global Standard: Most nuclear-powered nations, including the U.S. and Japan, are CSC members, ensuring global financial support for nuclear accidents.
      • Example: If a nuclear accident occurs in France, CSC members contribute to compensation, but in India, all financial burdens remain domestic.

    What are the reasons behind the government’s plan to amend the Atomic Energy Act and the Civil Liability for Nuclear Damage (CLND) Act?

    • Attracting Foreign Investment and Suppliers – The existing CLND Act allows India’s nuclear operator (NPCIL) to seek compensation from foreign suppliers in case of faulty equipment, discouraging companies from supplying reactors. Amendments could limit supplier liability, making India a more attractive market for nuclear investments from countries like the U.S., France, and Russia.
    • Expanding Nuclear Energy Capacity – India aims to increase its nuclear power generation to meet rising energy demands and climate goals. Simplifying liability laws could accelerate agreements with international partners and facilitate the construction of new nuclear plants under deals such as the India-U.S. Civil Nuclear Agreement.

    What are the other implications of increasing nuclear energy reliance?

    • High Economic Costs and Project Delays: Nuclear power plants require massive upfront investments, long construction periods, and frequent cost overruns.
      • Example: The AP1000 reactors in Georgia, USA, were initially estimated at $14 billion but were completed at $36.8 billion—a 250% cost overrun. Similarly, India’s Kudankulam Nuclear Power Plant faced significant delays and cost escalations.
    • Nuclear Waste Management and Environmental Risks: Nuclear energy produces radioactive waste that remains hazardous for thousands of years, requiring secure disposal and long-term monitoring.
      • Example: The Fukushima disaster (2011) led to the release of radioactive material, contaminating land and water, with cleanup costs estimated between ¥35-80 trillion (~₹20-46 lakh crore). India lacks permanent storage facilities for high-level nuclear waste.
    • Geopolitical and Security Concerns: Expanding nuclear energy means higher dependence on foreign suppliers, leading to strategic vulnerabilities and potential external influence.
      • Example: India’s civil nuclear deal with the U.S. (2008) opened doors for technology transfer, but suppliers now demand liability protection before delivering reactors, creating diplomatic pressure.

    Way forward:

    • Strengthen Liability and Safety Frameworks: The government should Amend the Civil Liability for Nuclear Damage (CLND) Act to ensure fair risk-sharing between operators and suppliers.
      • Need to invest in advanced reactor safety technologies (e.g., Small Modular Reactors – SMRs) and strengthen independent regulatory oversight.
    • Develop Robust Waste Management and Indigenous Capabilities: The government should establish permanent disposal sites for high-level nuclear waste with stringent monitoring.
      • Need to enhance domestic nuclear technology (e.g., Thorium-based reactors) to reduce reliance on foreign suppliers and improve energy security.