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  • The power of mangroves over seawalls

    Why in the News?

    Cyclone Dana highlighted how Odisha’s mangroves protected coastal communities, strengthening the case for nature-based coastal defence over seawalls. This has renewed attention on India’s continued preference for spending ₹2,641 crore on hard infrastructure despite evidence that mangroves and other coastal ecosystems provide long-term, cost-effective protection to nearly 250 million coastal residents.

    Why Are India’s Coastal Regions Becoming Increasingly Vulnerable to Climate Change?

    1. Rising sea levels: The Arabian Sea and Bay of Bengal are experiencing accelerating sea-level rise, threatening low-lying coastal districts, deltas, and island territories.
    2. Intensifying cyclones: Climate change is increasing both the frequency and intensity of cyclones along India’s coast, the eastern seaboard (Odisha, Andhra Pradesh, West Bengal) is particularly exposed.
    3. Saline intrusion: Saltwater intrusion into freshwater aquifers and agricultural land is degrading livelihoods. This directly affects food security and drinking water in coastal communities.
    4. Storm surges: Storm surges linked to cyclonic events are intensifying. These cause disproportionate damage to ecologically fragile coastal landscapes and displacing communities.
    5. Compound risk: These interacting hazards do not operate independently. They multiply threats along India’s coastline, making the fragile coastal landscape both physically and economically vulnerable.
    6. Large Population Exposure: Nearly 250 million people living along India’s coastline face direct impacts of climate-related coastal risks.
    7. Extensive Coastline: India’s 11,000-km coastline increases exposure to multiple climate hazards simultaneously.

    Why Are Mangroves, Seagrasses and Coral Reefs Considered Natural Coastal Defences?

    1. Coral Reefs: The First Line of Defense
      1. Natural Breakwaters: Coral reefs sit furthest out in the ocean and absorb up to 97% of incoming wave energy before it can reach the shore.
      2. Friction and Depth: The jagged, complex structures of coral skeletons create immense bottom friction, forcing waves to break early and lose their destructive power
    2. Seagrass Meadows(The Middle Buffer): Reduce coastal erosion, trap sediments and support marine biodiversity.
      1. Erosion Control: Located in the shallow waters between reefs and the shore, seagrasses act as underwater carpets that anchor the seabed with their roots.
      2. Sediment Trapping: Their long blades slow down water currents, forcing suspended sand and organic particles to drop to the seafloor, which actively builds up the underwater terrain.
    3. Mangroves: The Intertidal Shield
      1. Storm Surge Mitigation: Mangrove forests act as the final, dense barrier against extreme weather, capable of reducing storm surge heights by up to 66%. 
      2. Energy Dissipation: Their massive networks of tangled prop roots and thick trunks create a dense obstacle course that rapidly saps the remaining power of waves and incoming floods.

    How Does Ecosystem-based Adaptation (EbA) Strengthen Climate Resilience?

    EbA uses biodiversity and ecosystem services to help people adapt to climate change. This reduces climate impacts while sustaining ecosystems that support fisheries, agriculture, and tourism.

    1. Climate Risk Reduction: Uses biodiversity and ecosystem services to help people adapt to climate change.
    2. Livelihood Protection: Supports fisheries, agriculture and tourism-dependent communities.
    3. Long-Term Sustainability: Maintains ecosystem functions while reducing climate vulnerabilities.
    4. Cost Effectiveness: Avoids repeated expenditure on expensive hard infrastructure maintenance.
    5. Disaster Risk Reduction: Reduces losses from cyclones, flooding and coastal erosion.
    6. Nature-based Solutions: Integrates conservation and restoration into adaptation planning.

    What Evidence Demonstrates the Effectiveness of Ecosystem-based Adaptation?

    Bhitarkanika Mangroves During Cyclone Dana

    1. Cyclone Protection: Mangroves in Odisha’s Bhitarkanika quietly protected communities from cyclone impacts.
    2. Natural Buffer: Reduced climate impacts while strengthening ecosystem health and livelihoods.

    Global Evidence

    1. Protection Capacity: A healthy hectare of coastal habitat protects more people per hectare than almost any other natural asset.

    Sundarbans Example

    1. Mangrove Restoration: Around 18,000 women restored 4,600 hectares of mangroves.
    2. Cyclone Mitigation: Restoration reduced impacts of Cyclones Amphan and Yaas.
    3. Livelihood Benefits: Strengthened local economic opportunities and social outcomes.

    Kerala Example

    1. Seawall Consequences: Armouring and erosion-control measures protected specific sites.
    2. Adjacent Damage: Accelerated erosion in neighbouring areas, illustrating unintended consequences of hard infrastructure.

    Why Does India Continue to Prefer Seawalls and Embankments?

    Seawalls are massive, heavy-duty structures built directly parallel to the shoreline where the sea meets the land. They are designed as a last line of defence to protect high-value coastal areas, like cities and roads, from intense wave action. Embankments are raised earthen ridges or mounds constructed along rivers, lakes, or low-lying coastlines. They focus on holding back water from flat, expansive areas rather than fighting heavy, crashing ocean waves.

    1. Engineering Bias: Adaptation planning strongly favours hard infrastructure such as seawalls, groynes, embankments and tetrapods.
    2. Political Visibility: Seawalls and embankments provide visible and immediate outputs, making them attractive for governments.
    3. Institutional Preference: Existing planning, procurement and budgeting systems are designed around construction-based projects.
    4. Administrative Familiarity: Engineers and local authorities are more experienced with hard infrastructure than ecosystem restoration.
    5. Perceived Certainty: Seawalls provide tangible and measurable protection, whereas ecosystem benefits are often viewed as less predictable.

    What does India’s coastal adaptation spending pattern reveal about institutional bias toward hard infrastructure?

    1. Hard protection dominance: Coastal States spent ₹2,641 crore on hard protection measures over the last decade. This reflects a stark preference for engineered measures such as seawalls, groynes, embankments, and tetrapods.
    2. National Coastal Mission decline: Budget fell from ₹195 crore in 2022-23 to just ₹50 crore in 2024-25.
    3. PSL and visibility bias: Fragile institutional mandates, weak monitoring, and a preference for visible infrastructure often leave ecosystem-based interventions buried within broader sectoral programmes rather than recognised as adaptation in their own right.
    4. Reporting gap: Adaptation benefits of coastal ecosystems are rarely assessed or recorded separately, making India’s coastal EbA portfolio appear much weaker than it is.

    What Prevents Ecosystem-based Adaptation from Becoming Mainstream Policy?

    1. Fragmented Terminology: EbA overlaps with Nature-based Solutions (NbS), Coastal Adaptation (EbCA), Ecosystem-based Disaster Risk Reduction (Eco-DRR) and related concepts.
    2. Classification Challenges: Similar interventions are recorded under conservation, restoration or management categories instead of adaptation.
    3. Weak Monitoring: Limited mechanisms exist to measure adaptation outcomes.
    4. Institutional Fragmentation: EbA interventions remain dispersed across multiple schemes and sectors.
    5. Inadequate Recognition: Policymakers often fail to identify adaptation benefits generated by ecosystem restoration.
    6. Limited Financing: Absence of dedicated adaptation financing restricts scale and replication.

    Why Does Classification of Ecosystem-based Adaptation Matter?

    1. Policy Recognition: Enables clear identification of adaptation actions.
    2. Monitoring Frameworks: Facilitates tracking and evaluation of adaptation outcomes.
    3. Financing Access: Strengthens eligibility for climate adaptation funding.
    4. Evidence Generation: Supports measurement of climate resilience benefits.
    5. Policy Integration: Ensures ecosystem restoration becomes part of mainstream adaptation planning.

    How Does the Mangrove Initiative for Shoreline Habitats and Tangible Incomes (MISHTI) Reflect the Potential of EbA?

    MISHTI is a dedicated central government scheme in India aimed at reviving and expanding the country’s mangrove cover while generating sustainable livelihoods for coastal communities. Announced during the Union Budget 2023-24 and officially launched on World Environment Day (5 June 2023), it serves as a core part of India’s strategy to build a nature-based “bio-shield” against climate change.

    1. Programme Objective: Targets restoration of 540 sq km of mangroves across nine States.
    2. Climate Resilience: Enhances natural protection against coastal hazards.
    3. Livelihood Support: Generates economic opportunities linked to ecosystem restoration.
    4. Current Limitation: Primarily framed as a restoration programme rather than a climate adaptation initiative.

    What Policy Reforms Are Needed to Mainstream Ecosystem-based Adaptation?

    1. Policy Integration: Embeds EbA within coastal planning and adaptation frameworks.
    2. Dedicated Financing: Expands budgetary support for ecosystem-based interventions.
    3. Outcome Monitoring: Develops indicators for adaptation benefits.
    4. Institutional Coordination: Harmonises fragmented schemes and programmes.
    5. Climate Accounting: Recognises ecosystem restoration as an adaptation investment.
    6. Natural Capital Approach: Treats ecosystems as strategic climate-resilience assets.

    Conclusion

    The choice before India is not merely between two adaptation techniques but between two development pathways. While seawalls offer localised and short-term protection, mangroves and other coastal ecosystems provide durable climate resilience, biodiversity conservation and livelihood security. Mainstreaming Ecosystem-based Adaptation will be critical for protecting India’s 250 million coastal residents in an era of accelerating climate change.

    Value Addition

    Nature-based Solutions (NbS)

    Definition: Nature-based Solutions (NbS) is an umbrella concept defined by the International Union for Conservation of Nature (IUCN) as actions to protect, sustainably manage, and restore natural or modified ecosystems. These actions address societal challenges, such as climate change, food security, water security, human health, and disaster risk, while simultaneously providing human well-being and biodiversity benefits.

    1. India’s NDC 2022 references NbS for carbon sequestration through forests.

    Ecosystem-based Adaptation (EbA)

    Definition: Use of biodiversity and ecosystem services to help people adapt to adverse impacts of climate change.

    Key Features

    1. Ecosystem conservation
    2. Ecosystem restoration
    3. Climate risk reduction
    4. Community participation
    5. Livelihood enhancement
    6. Disaster resilience

    Ecosystem-based Coastal Adaptation (EbCA)

    EbCA is a subset of Ecosystem-based Adaptation (EbA). It focuses specifically on helping coastal communities adapt to the long-term, gradual changes brought by climate change.

    1. The Core Strategy: It uses coastal biodiversity and ecosystem services to help human societies adapt to climate pressures.
    2. Primary Targets: Sea-level rise, coastal erosion, saltwater intrusion into agricultural land, and changing ocean temperatures.
    3. Example: Dynamically planting salt-tolerant mangrove species along an eroding coastline. As sea levels rise, the mangroves naturally trap sediment, raising the land.

    Ecosystem-based Disaster Risk Reduction (Eco-DRR)

    Eco-DRR focuses on using ecosystems to reduce the immediate impact, frequency, and severity of sudden natural disasters.

    1. The Core Strategy: It manages and restores ecosystems to act as physical shock absorbers against extreme physical hazards.
    2. Primary Targets: Sudden disasters like cyclones, tsunamis, massive storm surges, and flash floods.
    3. Example: Protecting an offshore coral reef. When a cyclone strikes, the reef acts as a natural breakwater, absorbing up to 97% of the wave energy before it crashes into coastal towns, directly reducing casualties and property destruction.

    Ecological Bio-Shields:

    1. A bio-shield is a dense strip of vegetation planted along a coast to act as a barrier against natural hazards. 
    2. Casuarina trees, mangroves, and coastal palms are frequently used together to create multi-tiered, living walls that trap flying debris and slow down incoming water.If

    Integrated Coastal Zone Management (ICZM): 

    1. India’s ICZM project (World Bank-assisted) aimed to address coastal erosion, pollution, and habitat loss through integrated planning. 
    2. EbA mainstreaming is its natural evolution.

    PYQ Relevance

    [UPSC 2022] Explain the causes and effects of coastal erosion in India. What are the available coastal management techniques for combating the hazard?

    Linkage: The PYQ examines coastal vulnerability and compares different coastal protection approaches, including structural and ecosystem-based measures. The article extends the PYQ by assessing whether ecosystem-based solutions such as mangroves can provide more sustainable and cost-effective coastal protection than conventional seawalls and embankments.

  • APEDA Facilitates Export of Millet Functional Foods to New Zealand

    Why in the news?

    Agricultural and Processed Food Products Export Development Authority (APEDA) facilitated the first-ever sea shipment of botanical-infused ready-to-cook millet functional foods from Karnataka to New Zealand.

    Key Highlights

    • Export consignment:
      • One metric tonne of value-added millet-based functional foods.
    • Exporter:
      • M/s Infini Agrotek LLP, Bengaluru.
    • Shipment flagged off on:
      • 3 June 2026.
    • Product category:
      • Botanical-infused ready-to-cook millet functional foods.
    • Trade promotion support:
      • Exporter participated in:
        • World Food India 2025
        • Indus Food 2025
        • Gulfood 2026
    • Outcome:
      • APEDA-supported networking helped secure export orders from New Zealand.
    • Significance:
      • Expands global market access for Indian millet products.
      • Promotes value-added agri exports.
      • Expected to improve incomes of millet-growing farmers.
      • Strengthens India’s agri-export ecosystem.

    About APEDA

    • The Agricultural and Processed Food Products Export Development Authority (APEDA) is a statutory body established by the Government of India under the Ministry of Commerce and Industry.
    • Headquartered in New Delhi, APEDA is responsible for developing, promoting, and regulating the export of agricultural and processed food products from India.

    [2018] With reference to organic farming in India, consider the following statements:
    1.‘The National ‘Programme for Organic Production’ (NPOP) is operated under the guidelines and ‘directions of the Union Ministry of Rural Development.
    2.‘The Agricultural and Processed Food Product Export Development Authority ‘(APEDA) functions as the Secretariat for the implementation of NPOP.
    3.Sikkim has become India’s first fully organic State.
    Which of the statements given above is/are correct?

    [A] 1 and 2 only

    [B] 2 and 3 only

    [C] 3 only

    [D] 1, 2 and 3

  • Catalyst that Transforms to Perform

    Why in the news?

    Scientists from the Centre for Nano and Soft Matter Sciences and collaborating institutions discovered how a catalyst changes its structure during water electrolysis for green hydrogen production. The study was published in Materials Horizons.

    Key Highlights

    • Researchers studied:
      • Molybdenum carbide (Mo₂C), an earth-abundant catalyst used in hydrogen production.
    • Molybdenum Carbide is a compound made of molybdenum and carbon that acts as an efficient catalyst in hydrogen production and other industrial chemical reactions
    • Key Features
      • Considered an earth-abundant catalyst because molybdenum is more available and cheaper than precious metals like platinum.
      • Exhibits platinum-like catalytic properties in some reactions.
      • Has high thermal stability and good electrical conductivity.
    • Role in Hydrogen Production
      • Mo₂C is widely studied for: Hydrogen Evolution Reaction (HER) in water splitting.
      • Electrochemical production of green hydrogen.
      • Improving efficiency while reducing dependence on expensive noble-metal catalysts.

    About Hydrogen Evolution Reaction (HER)

    • HER is the electrochemical reaction where hydrogen gas is produced from water during electrolysis.
    • It occurs at the cathode. (The cathode is the electrode where reduction occurs and hydrogen gas is produced.)
      • Note: Anode: The anode is the electrode where oxidation occurs. In water electrolysis, oxygen is produced at the anode through the Oxygen Evolution Reaction (OER).
    • Efficient catalysts are required to reduce energy consumption and improve hydrogen production efficiency.

    About Green Hydrogen

    • Green hydrogen is hydrogen produced using renewable energy sources through electrolysis of water.
    • It is considered a clean fuel because it emits no carbon dioxide during use.

    [2023] With reference to green hydrogen, consider the following statements:
    1. It can be used directly as a fuel for internal combustion.
    2. It can be blended with natural gas and used as fuel for heat or power generation.
    3. It can be used in the hydrogen fuel cell to run vehicles.
    How many of the above statements are correct?

    [A] Only one

    [B] Only two

    [C] All three

    [D] None

  • India’s Green Transformation

    Why in the news?

    The Government of India highlighted major achievements in environmental protection, biodiversity conservation, climate action, and sustainable development over the last 12 years.

    Forest and Green Cover

    • India’s forest and tree cover reached 8.27 lakh sq. km (25.17% of geographical area).
    • Forest carbon stock stands at 30.43 billion tonnes.
    • Compensatory Afforestation Fund Management and Planning Authority undertook over 3.2 lakh hectares of compensatory afforestation between FY 2020-21 and 2024-25.
    • “Ek Ped Maa Ke Naam” campaign planted 262.4 crore saplings till December 2025.

    River Rejuvenation

    • Namami Gange Programme launched for restoration of the River Ganga.
    • 524 projects worth ₹43,030 crore sanctioned till February 2026.
    • Industrial BOD load reduced from 26 TPD (2017) to 10.75 TPD (2024).
    • Gangetic dolphin population estimated at 6,327.

    Wetland Conservation

    • Wetland conservation strengthened under the National Plan for Conservation of Aquatic Ecosystems (NPCA).
    • India’s Ramsar sites increased from 26 in 2014 to 99 by April 2026.

    Mangrove and Coastal Ecosystems

    • Mangrove cover increased from 4,628 sq. km (2013) to 4,992 sq. km (2023).
    • Blue Flag certified beaches increased to 18 in 2025-26.

    Wildlife Conservation

    • Project Tiger: Tiger population increased from 2,226 (2014) to 3,682 (2022).
    • Project Cheetah: India’s cheetah population reached 53.
    • Asiatic lion population increased to 891 in 2025.
    • India hosts nearly 60% of the global wild Asian elephant population.

    Waste Management and Circular Economy

    • Solid waste processing increased from 17% (2014) to over 77% (2024).
    • 1,138 dumpsites remediated across 1,048 cities.
    • Extended Producer Responsibility (EPR) frameworks expanded for plastics, batteries, tyres, e-waste, and used oil.

    Climate and Global Leadership

    • India achieved its target of reducing emissions intensity by 33-35% from 2005 levels ahead of schedule.
    • Non-fossil sources account for 52.57% of installed power capacity (February 2026).
    • Major global initiatives led by India:
      • International Solar Alliance
      • Coalition for Disaster Resilient Infrastructure
      • International Big Cat Alliance
      • Mission LiFE

    [2025] Consider the following statements:
    Statement I: Circular economy reduces the emissions of greenhouse gases.
    Statement II: Circular economy reduces the use of raw materials as inputs.
    Statement III : Circular economy reduces wastage in the production process.
    Which one of the following is correct in respect of the above statements?

    [A] Both Statement II and Statement III are correct and both of them explain Statement I

    [B] Both Statement II and Statement III are correct but only one of them explains Statement I

    [C] Only one of the Statements II and III is correct and that explains Statement I

    [D] Neither Statement II nor Statement III is correct

  • Niveshak Shivir by IEPFA and SEBI

    Why in the news?

    Investor Education and Protection Fund Authority and Securities and Exchange Board of India will organise a Niveshak Shivir in Bhopal on 5 June 2026 to help investors resolve issues related to unclaimed dividends and shares.

    Key Highlights

    • Organised by:
      • IEPFA under the Ministry of Corporate Affairs
      • SEBI.
    • Objective:
      • Investor awareness
      • Grievance redressal
      • Recovery of unclaimed investments.

    Services Provided at Niveshak Shivir

    • Recovery assistance for:
      • Unclaimed dividends
      • Unclaimed shares.
    • On the spot:
      • KYC updation
      • Nomination services.
    • Resolution of:
      • Pending IEPFA claim issues.

    What is IEPFA?

    The Investor Education and Protection Fund Authority (IEPFA):

    • Functions under: Ministry of Corporate Affairs.
    • Established to:
      • Protect investor interests.
      • Promote financial literacy and investor awareness.

    Investor Education and Protection Fund (IEPF)

    • Created under: Companies Act, 2013.
    • Unclaimed: Dividends, Shares, and Deposits are transferred to the IEPF after a specified period.

    When are Shares/Dividends Transferred to IEPF?

    • If dividends remain unclaimed for Seven consecutive years, the related shares are transferred to the IEPF Authority.

    What is SEBI?

    The Securities and Exchange Board of India:

    • Is the regulator of Securities and capital markets in India.
    • Established in 1988.
    • Statutory status granted in 1992.

    Objectives of the Initiative

    • Simplify Investor claim process.
    • Promote:
      • Financial inclusion
      • Investor protection.
    • Strengthen: Transparency in financial markets.

    About RTAs

    Registrars and Transfer Agents (RTAs):

    • Maintain records of:
      • Shareholders
      • Share transfers
      • Dividend payments.
    • Assist companies in investor-related services.

    [2025] Consider the following statements:
    I. India accounts for a very large portion of all equity option contracts traded globally thus exhibiting a great boom.
    II. India’s stock market has grown rapidly in the recent past even overtaking Hong Kong’s at some point of time.
    III. There is no regulatory body either to warn the small investors about the risks of options trading or to act on unregistered financial advisors in this regard.
    Which of the statements given above are correct?

    [A] I and Il only

    [B] II and III only

    [C] I and III only

    [D] I, II and III

  • Next Generation Nanomedicine for Breast Cancer

    Why in the news?

    Scientists from Agharkar Research Institute developed a biodegradable nanomedicine platform capable of silencing cancer driving genes in breast cancer cells, offering a promising precision oncology therapy.

    Key Highlights

    • Research published in: Advanced Healthcare Materials.
    • Developed under: Department of Science and Technology.
    • Uses: Targeted gene silencing strategy.
    • Aim: Effective tumour inhibition with minimal toxicity.

    What is Nanomedicine?

    Nanomedicine refers to the use of nanoscale materials and technology for:

    • Diagnosis
    • Drug delivery
    • Treatment of diseases.

    What is Precision Nanomedicine?

    • Precision nanomedicine: Targets disease causing cells specifically.
    • Reduces:
      • Damage to healthy tissues.
      • Side effects associated with conventional therapies.

    Key Technology Used

    Mesoporous Silica Nanoparticles

    • Biodegradable nanoparticles with:
      • High drug loading capacity.
      • Tunable surface chemistry.
    • Used to deliver: Small interfering RNA (siRNA).

    What is siRNA?

    • Small interfering RNA (siRNA): Molecules that silence specific genes by preventing protein production.
    • Used in:
      • Gene therapy
      • Cancer treatment research.

    [2015] With reference to the use of nanotechnology in health sector, which of the following statements is/are correct?
    1.Targeted drug delivery is made possible by nanotechnology
    2.Nanotechnology can largely contribute to gene therapy
    Select the correct answer using the code given below.

    [A] 1 only

    [B] 2 only

    [C] Both 1 and 2

    [D] Neither 1 nor 2

  • The future of India’s chip industry

    Why in the News?

    Recently, NITI Aayog Frontier Tech Hub report was released and it assesses the country’s readiness for chip manufacturing. India has approved its first semiconductor fabrication unit at Dholera and launched a ₹76,000 crore India Semiconductor Mission. But, the report finds that the domestic ecosystem is still not equipped to meet national demand.

    How Has India Built the Foundations of a Semiconductor Ecosystem?

    1. Policy Priority: Semiconductor manufacturing has been identified as a strategic national priority.
    2. India Semiconductor Mission (ISM): Operates with a corpus of ₹76,000 crore.
    3. Financial Support: Provides incentives for fabs, compound semiconductor facilities, packaging units, design initiatives, and research.
    4. Capital Subsidies: Major projects receive capital support of up to 50%.
    5. Production Incentives: Several projects receive production-linked and output-linked incentives.
    6. Dholera Fab: India’s first semiconductor fabrication facility is expected to become operational by 2028.
    7. Ecosystem Development: Multiple packaging and testing facilities have been approved.

    India Semiconductor Mission

    1. The India Semiconductor Mission (ISM) is a specialized, independent business division within the Digital India Corporation under the Ministry of Electronics and Information Technology (MeitY). 
    2. It was launched in 2021 with an original financial outlay of ₹76,000 crore.
    3. Its core purpose is to build a vibrant, sustainable semiconductor and display ecosystem to transition India from a chip consumer into a global electronic manufacturing and design hub.

    Core Schemes & Financial Support: The initiative operates as a single-window nodal agency that evaluates proposals and distributes a 50% fiscal subsidy on a pari-passu basis across critical segments:

    1. Semiconductor Fabs: Financial backing to set up silicon-based wafer fabrication plants.
    2. Display Fabs: Incentives for building TFT LCD or AMOLED display manufacturing units.
    3. Compound Semiconductors & ATMP: Support for Silicon Photonics, Sensors, and Assembly, Testing, Marking, and Packaging (ATMP/OSAT) plants.
    4. Design Linked Incentive (DLI): Financial and infrastructure support for domestic fabless companies developing Integrated Circuits and Systems on Chips (SoCs).

    ISM 2.0

    1. Announced in the latest 2026 Union Budget, ISM 2.0 drives local supply chain self-sufficiency. 
    2. It receives a targeted ₹1,000 crore budgetary provision for FY 2026-27 alongside an overall ₹8,000 crore layout for the modified manufacturing program. 

    Key targets include:

    1. Upstream Supply Chains: Localizing production of specialty gases, chemicals, and lithography tools.
    2. Indian IP & Processors: Scaling indigenous open-source RISC-V processors like DHRUV64 under the Digital India RISC-V (DIR-V) programme to secure digital sovereignty.
    3. Talent Pyramid: Training over 85,000 to 100,000 engineers via the Chips to Startup (C2S) program and dedicated SMART Labs.
    4. NITI Aayog Roadmap: Aligning with the NITI Frontier Tech Hub’s newly released “Future of India’s Semiconductor Industry” roadmap to target a $100-110 billion domestic market by 2030.

    Why Does the Report Argue That India Remains Semiconductor-Dependent?

    1. Import Dependence: India depends almost entirely on external suppliers, importing an estimated $15+ billion in electronics hardware. Major suppliers include China, Hong Kong, Taiwan, and Singapore
    2. Domestic Supply Gap: India’s semiconductor ecosystem cannot fully meet domestic demand. The domestic semiconductor ecosystem is largely limited to Assembly, Testing, Marking, and Packaging (ATMP) rather than full-scale fabrication.
    3. Electronics Vulnerability: Growth in electronics manufacturing remains dependent on external suppliers.
    4. National Security Concerns: Defence systems rely on imported semiconductor components.
    5. Supply-Chain Risks: Geopolitical disruptions could affect access to critical technologies and components.

    What Structural Challenges Limit India’s Semiconductor Manufacturing Ambitions?

    1. Time-Intensive Manufacturing Cycle
      1. Long Gestation Period: Semiconductor fabs generally require 4-5 years before commercial production.
      2. Yield Optimisation: Reliability and quality improvement continue for several quarters after production begins.
    2. Technological Complexity
      1. Equipment Dependence: More than 50 specialised equipment categories are required.
      2. Global Supplier Concentration: Critical manufacturing tools are controlled by a limited number of international firms.
    3. Capital Intensity
      1. High Investment Requirements: Semiconductor manufacturing demands massive upfront capital expenditure.
      2. Financial Risks: Long project cycles increase uncertainty for investors.
    4. Skill Requirements
      1. Advanced Expertise: Requires highly skilled engineers, designers, and process specialists.
      2. Technology Gaps: Domestic capabilities remain under development.

    Should India Replicate the Entire Global Semiconductor Value Chain?

    India should not replicate the entire global semiconductor value chain, as doing so is financially impractical and technologically inefficient. The global semiconductor industry is highly fragmented, capital-intensive, and reliant on decades of hyper-specialization across different countries.

    1. Selective Strategy: The report discourages attempts to replicate the complete global manufacturing spectrum.
      1. Example: Instead of trying to build complex extreme ultraviolet (EUV) lithography machines (a sector monopolized by ASML in the Netherlands), India is focusing on specific nodes (like 28nm and above) that serve automotive and consumer electronics markets.
    2. Capital Efficiency: Setting up a single advanced semiconductor fabrication plant (fab) can cost upwards of $10 billion to $20 billion. Replicating the entire chain would require hundreds of billions of dollars.
      1. Example: By directing capital toward Assembly, Testing, Marking, and Packaging (ATMP) and Outsourced Semiconductor Assembly and Test (OSAT) facilities, such as the Tata Electronics facilities, India can enter the manufacturing ecosystem faster and at a fraction of the cost of a leading-edge logic fab.
    3. System-Level Differentiation: Emphasises strategic specialisation rather than broad replication.
      1. Example: India houses nearly 20% of the world’s semiconductor design engineers. By utilizing the Design-Linked Incentive (DLI) scheme, local startups can design specialized, proprietary chips for Artificial Intelligence (AI), 5G communications, and Internet of Things (IoT) devices, establishing a unique global niche.
    4. Resource Optimisation: Supports targeted investments in high-potential segments.

    Why Does the Report Advocate a Shift Towards Mature and Strategic Nodes?

    Semiconductor nodes represent the transistor size, with advanced (3-7nm) focusing on density for high-end computing and mature nodes (28nm+) offering reliability for industrial use. The report advocates shifting toward mature and strategic nodes because they cost significantly less to build, have higher market demand in India, and directly secure critical industries like defense and automotive.

    1. Technological Feasibility: India currently lacks the manufacturing ecosystem, equipment base, and process expertise required for competitive production at advanced 3-7 nanometre nodes.
    2. Capital Efficiency: Mature-node semiconductor facilities require significantly lower investment and entail lower commercial risks than cutting-edge fabrication plants.
    3. Market Demand: Mature-node chips continue to dominate demand in automobiles, industrial machinery, consumer electronics, power systems, and telecommunications equipment.
    4. Strategic Utility: Domestic production of mature semiconductors can strengthen supply-chain resilience in defence, telecom, automotive, and critical infrastructure sectors.
    5. Comparative Advantage: Compound semiconductors offer niche opportunities where India can develop specialised capabilities without directly competing in the most advanced fabrication segments.
    6. Faster Capability Creation: Focusing on mature technologies enables quicker ecosystem development, workforce training, and industrial scaling than pursuing frontier-node manufacturing.

    Why Can Semiconductor Packaging Become India’s Most Viable Entry Point into the Global Semiconductor Industry?

    1. Lower Capital Requirement: Packaging and testing facilities require substantially lower investment than semiconductor fabrication plants, making entry easier for India.
    2. Technological Accessibility: Packaging operations involve lower technological complexity than advanced-node chip fabrication, reducing entry barriers.
    3. Workforce Advantage: India’s large pool of engineers and technical professionals can support labour-intensive assembly, testing, and packaging operations.
    4. Faster Capacity Expansion: Packaging facilities can be established and scaled more quickly than fabrication units, enabling rapid ecosystem development.
    5. Import Substitution Potential: Domestic packaging capabilities can reduce dependence on foreign assembly and testing services in high-volume semiconductor segments.
    6. Global Value Chain Integration: Packaging provides a practical route for India to participate in international semiconductor supply chains without mastering frontier-node manufacturing.
    7. Foundation for Ecosystem Growth: A strong packaging industry can create demand for ancillary industries, skills, logistics networks, and future fabrication investments.

    What Does “Sovereign Design and Research Capability” Mean for India?

    1. Design Leadership: Moves beyond manufacturing toward intellectual-property creation.
    2. R&D Excellence: Strengthens indigenous innovation capabilities.
    3. AI Integration: Promotes application of Artificial Intelligence in semiconductor engineering.
    4. Deep Capabilities: Supports transition from service-led design activities to original technology creation.
    5. Architectural Innovation: Encourages development of differentiated semiconductor systems and integration technologies.

    How Should India Structure Future Semiconductor Investments?

    1. Second Phase of ISM: Future policy support is under consideration.
    2. Investment Requirement: The report estimates $45-60 billion over a ten-year period.
    3. Bankability Focus: Recommends prioritising projects with clearer commercial viability.
    4. Risk Management: Encourages investment in segments with stronger return potential.
    5. Targeted Expansion: Supports gradual ecosystem deepening rather than large-scale expansion across all segments.

    Which International Partnerships Are Critical for India’s Semiconductor Strategy?

    1. Strategic Partners: Identifies the United States, Japan, European Union, and South Korea as priority partners.
    2. Technology Access: Facilitates acquisition of critical manufacturing tools.
    3. Lifecycle Support: Strengthens equipment servicing and maintenance.
    4. Knowledge Transfer: Expands access to advanced manufacturing practices.
    5. Packaging Advantage: Leverages India’s workforce and packaging ecosystem.

    What Are the Broader Strategic Implications for India?

    1. Economic Security: Reduces dependence on external technology suppliers.
    2. Supply-Chain Resilience: Protects against geopolitical disruptions.
    3. National Security: Supports defence and critical infrastructure requirements.
    4. Industrial Competitiveness: Strengthens electronics manufacturing.
    5. Technological Sovereignty: Enhances control over critical technologies.
    6. Global Positioning: Improves India’s role in future technology ecosystems.

    Conclusion

    India’s semiconductor strategy is entering an execution phase where success will depend less on replicating the entire global value chain and more on building competitive strengths in areas aligned with domestic capabilities. The NITI Aayog report advocates a pragmatic approach centred on mature-node manufacturing, semiconductor packaging, design innovation, and strategic international partnerships. By prioritising commercially viable segments while gradually deepening technological capabilities, India can strengthen supply-chain resilience, reduce strategic vulnerabilities, and establish itself as a credible participant in the global semiconductor ecosystem.

    PYQ Relevance

    [UPSC 2025] India aims to become a semiconductor manufacturing hub. What are the challenges faced by the semiconductor industry in India? Mention the salient features of the Indian Semiconductor Mission

    Linkage: The PYQ tests understanding of high-technology manufacturing, industrial policy, technological self-reliance, and strategic sectors. The article evaluates India’s semiconductor strategy through the NITI Aayog report, highlighting challenges in fabrication, supply chains, investment, and skills while assessing the future direction of the India Semiconductor Mission

  • How land pooling solves acquisition woes

    Why in the News?

    Rajasthan has announced its first-ever land pooling scheme, signalling a major shift in the way urban land is assembled for infrastructure and development projects.

    What is land pooling?

    Land pooling is a land acquisition strategy where landowners voluntarily hand over their land parcels to a government agency or development authority. The authority consolidates (pools) the land, builds modern infrastructure and then returns a smaller but highly developed portion of the land back to the original owners.

    How does land pooling work?

    1. Pooling: Landowners voluntarily transfer their fragmented, irregular plots to a central authority to create one continuous tract.
    2. Infrastructure Development: The authority reserves a percentage of the total land to build roads, utilities, parks, and public services.
    3. Reconstitution: The authority reorganises the remaining land into a planned layout of commercial, residential, and industrial plots.
    4. Return: Each landowner receives back a physically smaller but highly developed plot equipped with modern amenities and significantly higher market value.

    Example

    Gujarat Town Planning (TP) Model

    1. Land Contribution: Landowners typically contribute about 25-40% of their land.
    2. Land Return: Approximately 60-75% of land is returned as serviced plots.
    3. Integrated Development: Combines land assembly, infrastructure provision, cost recovery, and urban planning within a single framework.

    How is land pooling governed in India?

    Land pooling in India is governed through a decentralized framework managed primarily by individual state governments, rather than a single central federal law. The structural and legal governance framework breaks down into four primary tiers:

    1. Constitutional Authority: Under the Constitution of India, Land and Colonisation fall explicitly under the State List (List II, Seventh Schedule).
    2. State-Specific Legislative Acts
      1. The Mechanism: States enact standalone Town Planning Acts or Urban Development Acts that provide the legal backbone for land pooling.
      2. Examples: Notable examples include the Gujarat Town Planning and Urban Development Act, 1976, and the Andhra Pradesh Capital Region Development Authority Act, 2014, which laid out the legal rules for building the city of Amaravati.
    3. Execution by Development Authorities
      1. The Mechanism: State governments delegate the actual implementation and policing of land pooling schemes to specialized Urban Development Authorities.
      2. The Power: Entities like the Delhi Development Authority (DDA) or the Mumbai Metropolitan Region Development Authority (MMRDA) are legally authorized to notify zones for pooling, verify land titles, collect landowner consensus, and re-allot reconstituted plots.
    4. Judicial Oversight and Grievance Redressal
      1. The Mechanism: State pooling policies mandatorily incorporate dedicated dispute resolution tribunals, appellate authorities, or arbitrators.

    How Has Traditional Land Acquisition Become a Constraint to Urban Infrastructure Development?

    1. Procedural Complexity: Land acquisition has historically been lengthy, litigation-prone, and administratively challenging.
    2. Post-2013 Cost Escalation: The Right to Fair Compensation and Transparency in Land Acquisition, Rehabilitation and Resettlement Act, 2013 increased compensation, rehabilitation, and resettlement obligations.
    3. Financial Burden: Higher compensation requirements have significantly increased project costs.
    4. Implementation Gap: Planned infrastructure often remains under-executed due to inability to mobilise land.
    5. Urbanisation Pressure: Expanding cities require large-scale land assembly for roads, public facilities, housing, and economic infrastructure.

    Why Is Land Pooling Considered More Equitable Than Compulsory Acquisition?

    1. Participatory Planning: Landowners remain stakeholders rather than losing ownership entirely.
    2. Reduced Displacement: Limits physical displacement compared to conventional acquisition.
    3. Value Capture: Landowners benefit from appreciation in land value after infrastructure development.
    4. Financial Sustainability: Infrastructure costs are recovered through incremental development charges rather than large upfront expenditure.
    5. Social Acceptance: Voluntary participation reduces resistance and legal disputes.
    6. Environmental Protection: Facilitates planned development while preserving environmentally sensitive areas.

    Why Is Gujarat Considered India’s Most Successful Land Pooling Model?

    1. Historical Evolution: Land pooling was introduced nearly 100 years ago.
    2. Legal Foundation: Formalised under the Gujarat Town Planning and Urban Development Act, 1976.
    3. Large-Scale Implementation: More than 1,000 sq. km. has been planned through TP schemes.
    4. Geographical Coverage: Implemented across Ahmedabad, Surat, Rajkot, Vadodara, and Gandhinagar.
    5. Institutional Continuity: Strong legal backing and administrative experience enabled long-term success.
    6. Urban Expansion: Facilitated orderly peripheral growth and infrastructure provision.

    Why Has Maharashtra Recently Revived Interest in Land Pooling?

    1. Statutory Limitations: Existing legal provisions were not adequately updated for TP schemes.
    2. Recent Adoption: The model has gained momentum in Pune and the Mumbai Metropolitan Region Development Authority (MMRDA).
    3. Peripheral Development: Supports infrastructure creation and serviced land development in expanding urban regions.
    4. Growth Management: Provides an alternative to fragmented urban expansion.

    Why Land Pooling Initiatives like Guwahati Face Difficulties?

    1. Institutional Challenges
      1. Legal Gaps: The Guwahati Metropolitan Development Authority Act, 1985 lacked clarity on land appropriation percentages and institutional responsibilities.
      2. Implementation Ambiguity: Development scheme preparation procedures remained inadequately specified.
    2. Land Records Challenges
      1. Manual Records: Land records were not digitised.
      2. Record Mismatch: Discrepancies existed between revenue records and actual ground conditions.
    3. Administrative Solutions
      1. Existing Map Utilisation: Authorities retained existing maps instead of conducting extensive joint surveys.
      2. Revenue-Based Allocation: Final plot allocation was based on land area recorded in revenue documents.
      3. Time Efficiency: Reduced scheme preparation time.
    4. Contribution Adjustment
      1. Reduced Contribution: Private landowners contributed only 12-15% of land.
      2. Comparison: Conventional schemes generally require 35–45% land contribution.
      3. Infrastructure Focus: Contributed land was primarily used for road development.

    How Is Rajasthan Attempting to Make Land Pooling More Viable?

    1. Statutory Recognition: Land pooling provisions already existed since 2016.
    2. Implementation Push: Rajasthan is now operationalising the framework.
    3. Land Value Reforms: Modifications are being made to land-value calculations.
    4. Cost Sharing: Government has absorbed part of the development cost.
    5. Financial Equity: Reduces burden on participating landowners.
    6. Stakeholder Acceptance: Makes participation more attractive.

    What Factors Will Determine the Success of Future Land Pooling Schemes?

    1. Stakeholder Trust: Requires convincing landowners of long-term benefits.
    2. Legislative Clarity: Ensures certainty regarding rights, obligations, and compensation.
    3. Digital Land Records: Improves transparency and reduces disputes.
    4. Flexible Contribution Models: Allows adaptation to local realities.
    5. Institutional Capacity: Strengthens planning authorities and implementation agencies.
    6. Equitable Financial Models: Distributes costs and benefits fairly.
    7. Context-Specific Design: Avoids one-size-fits-all approaches.

    Conclusion

    Land pooling represents a shift from a compensation-centric model of land acquisition to a partnership-based model of urban development. The experiences of Gujarat, Maharashtra, Guwahati, and Rajasthan demonstrate that success depends less on the concept itself and more on institutional capacity, legal clarity, digitised land records, and equitable benefit-sharing. As India’s urbanisation accelerates, land pooling can become a critical instrument for balancing infrastructure needs with property rights and inclusive development.

    Value Addition

    Land Pooling vs Land Acquisition

    DimensionLand AcquisitionLand Pooling
    OwnershipGovernment acquires landLandowners retain stake
    CompensationMonetary paymentReconstituted serviced plots
    ParticipationCompulsoryVoluntary
    DisplacementHigherLower
    LitigationHighRelatively lower
    Cost BurdenUpfront government expenditureShared through value capture
    Benefit SharingLimitedBroader and participatory

    PYQ Relevance

    [UPSC 2024] What were the factors responsible for the successful implementation of land reforms in some parts of the country? Elaborate.

    Linkage: The question focuses on land governance, fair land distribution, and factors that make land reforms successful. Land pooling is a modern land reform approach that uses voluntary participation, clear land records, and shared benefits to support planned development.

  • VYOMA Innovation Challenge

    Why in the news?

    The Digital India BHASHINI Division, under the Ministry of Electronics and Information Technology, launched the VYOMA Innovation Challenge to promote multilingual, voice first, offline AI solutions for India.

    Key Highlights

    • Initiative launched in collaboration with:
      • Current AI
      • Kalpa Impact.
    • Objective:
      • Promote open source multilingual AI systems that can function in:
        • Offline environments
        • Low connectivity regions.

    About Sunno Sutra

    The challenge is based on:

    • Sunno Sutra: A multilingual voice first handheld AI reference device.
    • Developed jointly by: BHASHINI and Current AI.

    Features of Sunno Sutra

    • Supports: Conversational AI in Indian languages.
    • Works: Without cloud dependence.
    • Uses: On device AI capabilities.
    • Suitable for: Rural and low resource environments.

    Objectives of the VYOMA Innovation Challenge

    • Encourage development of:
      • Multilingual AI applications.
      • Voice based technologies.
    • Improve:
      • Digital accessibility.
      • Language inclusion.
    • Promote: Edge AI innovation in India.

    What is Edge AI?

    Edge AI refers to: Artificial Intelligence processing directly on local devices instead of remote cloud servers.

    Advantages:

    • Faster processing
    • Offline functionality
    • Better privacy
    • Reduced internet dependence

    Sectors Targeted

    Potential applications include:

    • Education
    • Agriculture
    • Healthcare
    • Governance
    • Public service delivery

    [2020] With the print state of development, Artificial Intelligence can effectively do which of the following?
    1. Bring down electricity consumption in industrial units
    2. Create meaningful short stories and songs
    3. Disease diagnosis
    4. Text -to -Speech Conversion
    5. Wireless transmission of electrical energy
    Select the correct answer using the code given below:

    [A] 1, 2, 3 and 5 only

    [B] 1, 3 and 4 only

    [C] 2, 4 and 5 only

    [D] 1, 2, 3, 4 and 5

  • Prime Minister Research Chair (PMRC) Scheme 2026

    Why in the news?

    The Department of Higher Education under the Ministry of Education launched applications for the Prime Minister Research Chair (PMRC) Scheme 2026 to attract global Indian talent into India’s research and innovation ecosystem.

    Key Highlights

    • The scheme aims to connect:
      • Indian origin researchers and professionals working abroad
        with:
      • India’s higher education and research institutions.
    • Focus areas include:
      • Research
      • Innovation
      • Technology development.

    Objectives of PMRC Scheme

    • Strengthen: India’s research ecosystem.
    • Promote: International academic collaboration.
    • Enhance: Innovation in strategic sectors.
    • Support: Mission oriented research in national priority areas.

    Thematic Areas Covered

    The scheme focuses on 13 national priority sectors including:

    • Artificial Intelligence
    • Quantum Computing
    • Semiconductors
    • Cybersecurity
    • Biotechnology
    • Healthcare and MedTech
    • Space and Defence
    • Advanced Materials
    • Blue Economy
    • Atomic Energy
    • Climate Change and Sustainability.

    [2018] Consider the following statements :
    Human capital formation as a concept is better explained in terms of a process which enables
    1. individuals of a country to accumulate more capital.
    2. increasing the knowledge, skill levels and capacities of the people of the country.
    3. accumulation of tangible wealth.
    4. accumulation of intangible wealth.
    Which of the statements given above is/are correct?

    [A] 1 and 2

    [B] 2 only

    [C] 2 and 4

    [D] 1, 3 and 4