PM IAS NOV 09 UPSC CURRENT AFFAIRS

SC Verdict on  AMU’s Minority Status

Syllabus: GS 2/Governance 

In News 

• The Supreme Court ruled that an institution founded by a minority community retains its minority status even when recognized by statute.

Case Background

• The judgment was in response to petitions seeking minority status for Aligarh Muslim University (AMU).
  • AMU’s minority status, established in 1875, was restored by the AMU (Amendment) Act in 1981.
• Petitioners challenged the 1967 S. Azeez Basha v. Union of India case, which had held that AMU could not be considered a minority institution.

Supreme Court’s Observations

• Chief Justice D.Y. Chandrachud held that a minority institution could claim minority status, but the community must prove it was established to preserve its cultural identity.
• Interpretation of Article 30(1): Article 30(1) allows religious and linguistic minorities to establish and manage educational institutions.
  • The Chief Justice classified Article 30(1) as anti-discriminatory and a “special rights” provision for minorities.
  • Legislation or actions that discriminate against minority institutions are invalid under Article 30(1).
  • Minority institutions are guaranteed autonomy in administration under this provision.
• Scope of Minority Status: The protection under Article 30(1) also applies to universities established before the Constitution.
  • Institutions need not be exclusively for the minority community, but “predominantly” benefit them.
• State Regulation: State regulation of minority institutions is allowed but must not infringe on their minority character.
• Right to Administer: An institution’s minority character is not lost if management is not directly run by the founding community.
  • Minority institutions can appoint others to manage the institution, especially in specialized fields like law or medicine, to ensure educational values are emphasized.

Scheme for Strengthening the Medical Device Industry

Syllabus: GS2/Government Policy and Intervention; Health

Context

• Recently, the Union Minister Health & Family Welfare launched the Scheme for Strengthening the Medical Device Industry to enhance the manufacturing capabilities, infrastructure, and overall growth of the medical device industry in India.

About the Medical Device Industry in India

• Medical devices are integral to healthcare delivery, from diagnostic machines to surgical instruments to stents and prosthetics.

• India’s medical device market is currently valued at approximately $14 billion and is expected to grow to $30 billion by 2030 which is fueled by rising healthcare demands, increased investment in healthcare infrastructure, and a growing focus on innovation and technology.
• It is expected to enhance the availability and affordability of these devices, thereby improving healthcare outcomes.

Key Concerns and Challenges Ahead of the Medical Device Industry in India

• Regulatory Challenges: The industry has long called for streamlined and clear regulations. The National Medical Devices Policy, 2023, aims to address these issues by creating a more coherent policy framework.
  • However, the implementation and adaptation to these new regulations can be complex and time-consuming for manufacturers.
• Infrastructure and Technology: The lack of advanced infrastructure and technology for high-end medical equipment remains a significant hurdle.
  • While the government has approved the establishment of medical device parks to reduce manufacturing costs and optimise resources, the industry still faces challenges in accessing cutting-edge technology and infrastructure.
• Skilled Workforce: The medical device sector requires a highly skilled workforce, but there is a notable gap in the availability of trained professionals.
• Market Dynamics: India’s medical device market is heavily dependent on imports, with a significant portion of high-end devices being sourced from countries like the U.S., China, and Germany.
  • It not only affects the trade balance but also makes the industry vulnerable to global supply chain disruptions.
• Research and Development (R&D): Investment in R&D is crucial for innovation and competitiveness. However, the Indian medical device industry has historically underinvested in R&D.

Need For Strengthening the Medical Device Industry in India

• Manufacturing Enhancement: The scheme focuses on the production of key components and accessories essential for medical devices.
  • It includes support for setting up new manufacturing units and upgrading existing ones to meet global standards.
• Skill Development: Recognising the need for a skilled workforce, the scheme includes provisions for training and development programs.
  • These aim to equip individuals with the necessary skills to operate advanced medical device manufacturing technologies.
• Support for Clinical Studies: To ensure the safety and efficacy of medical devices, the scheme provides support for clinical trials and studies.
  • It aims to help in the development of innovative and reliable medical devices.
• Infrastructure Development: The scheme promotes the establishment of common infrastructure facilities such as testing centres, research and development hubs, and logistics centres.
  • These facilities are intended to support the entire medical device manufacturing ecosystem.
• Industry Promotion: Various promotional activities are planned under the scheme to boost the visibility and competitiveness of Indian medical devices in the global market.
  • It includes participation in international trade fairs, exhibitions, and other industry events.

Financial Outlay of The Scheme

• The scheme has a total outlay of ₹500 crores under Sub-schemes like Common Facilities for Medical Devices Clusters; Marginal Investment Scheme for Reducing Import Dependence; Capacity Building and Skill Development for Medical Devices; Medical Device Clinical Studies Support Scheme; and Medical Device Promotion Scheme.
• This significant investment underscores the government’s commitment to making India a global hub for medical device manufacturing.

Key Features of the Scheme

• Self-Reliance: The scheme is a significant step towards making India self-reliant in the medical device sector, reducing dependency on imports1.
• Economic Growth: By boosting domestic manufacturing, the scheme aims to contribute to the overall economic growth and create job opportunities.
• Innovation and Quality: Emphasis on innovation and maintaining high-quality standards to compete globally.

Impact of the Scheme and Future Prospects

• It is expected to not only strengthen the domestic manufacturing capabilities but also reduce dependency on imports, thereby making India self-reliant in the medical device sector.
• The scheme is poised to create numerous job opportunities, foster innovation, and ensure the availability of high-quality medical devices at affordable prices. 
• As the demand for medical devices continues to rise, this initiative will play a crucial role in meeting both domestic and international needs.

Conclusion

• The Scheme for Strengthening the Medical Device Industry is a strategic initiative to enhance the domestic manufacturing capabilities, promote innovation, and ensure the availability of high-quality medical devices.
• This scheme not only aims to make India self-reliant but also positions it as a global leader in the medical device sector.

Bibek Debroy Committee on Railways

Syllabus: GS3/ Infrastructure

In News

• The Bibek Debroy Committee 2015 report aimed to make Indian Railways economically viable and competitive, with a focus on decentralization, safety, and modernization, however, reforms are yet to be implemented completely.  

Key Recommendations and Their Implementation

• Liberalisation of Indian Railways: Introduce private players to enhance competition and improve services.
  • Implementation: Partially implemented. Some PPP projects have been initiated, but full-scale liberalization is yet to be undertaken.
• Empowering Railway Officials: Grant more autonomy to GMs and DRMs for decision-making.
  • Implementation: Implemented. GMs and DRMs have been empowered to take independent decisions, leading to faster decision-making and improved efficiency.
• Overhaul of Accounting System: Implement accrual accounting to improve financial transparency and accountability.
  • Implementation: Implemented. The Indian Railways has adopted accrual accounting.
• Establishment of Rail Development Authority (RDA): Create an independent regulator to oversee railway operations and promote competition.
  • Implementation: Implemented. The RDA has been established to provide expert advice on pricing, non-fare revenue, and competition.
• Focus on Safety: Create a dedicated fund for safety-related investments.
  • Implementation: Implemented. The Rashtriya Rail Sanraksha Kosh (RRSK) was established for safety upgrades with a ₹1 lakh crore fund.

Role of Technology in Modernising Fisheries Sector

Syllabus: GS 3/Economy 

In Context

• A workshop on drone technology in fisheries was held at ICAR-CMFRI, Kochi.

About Fisheries and Aquaculture sector 

• They are a key source of food, nutrition, employment, income, and foreign exchange.
• Fish, rich in protein and omega-3 fatty acids, helps combat hunger and malnutrition.
• India’s Position in Fisheries: 2nd largest fish-producing nation, with ~8% of global production.
  • Top aquaculture producer, 3rd largest in capture fisheries, and a leading shrimp exporter.
• Record Fish Production: Fish production grew from 7.52 lakh tonnes in 1950-51 to 175.45 lakh tonnes in 2022-23.
  • Inland fisheries and aquaculture production doubled since 2013-14, reaching 131.33 lakh tonnes in 2022-23.
• Doubling of Exports:Seafood exports increased from Rs 30,213 crore (2013-14) to Rs 60,523.89 crore (2023-24), with the USA as the largest market.
  • The sector contributes 1.069% to National GVA and 6.86% to Agriculture GVA, with steady growth from 2014-15 to 2021-22.
• Government Efforts: The Government of India has invested Rs 38,572 crore over the last decade to drive the Blue Revolution, transforming the fisheries sector.
  • Pradhan Mantri Matsya Sampada Yojana (PMMSY): PMMSY focuses on sustainable, inclusive growth in fisheries and aquaculture.
  • Other initiatives include modern aquaculture practices, satellite monitoring, and the exploration of drone technology for various applications.

Technology in Fisheries

• Efficient application of technology is essential for both fish production and utilization, covering fishing craft, gear, preservation, processing, and distribution.
  • Digital technologies like ICT, IoT, AI, machine learning, blockchain, and Cloud-edge computing can support the expansion and sustainability of the aquaculture and fisheries sectors.
• Drone Technology in Fisheries: Drones are used for water sampling, disease detection, feed management, aquaculture farm management, and fish marketing.
  • Underwater drones help monitor fish behavior and detect distress.

Importance 

• Increased Productivity: Technology enables fishermen to catch more fish with fewer resources and time.
• Enhanced Safety: Real-time updates on weather and sea conditions reduce risks for fishermen.
• Reduced Waste: Better storage and transportation reduce post-harvest losses, ensuring that more of the catch reaches consumers.
• Sustainability: Monitoring tools can help prevent overfishing and encourage responsible practices.
• Economic Upliftment: Improved efficiency and access to market data help fishermen earn better incomes.

Issues and Concerns 

• Slow development: Technological advancements in fishing and processing have been slow in India, relying largely on inshore, small-scale fishing methods
• High Initial Cost: Many fishermen cannot afford the latest technologies, leading to inequalities within the sector.
• Training and Adaptation: Many fishers need training to use new technologies effectively, which may be challenging for older generations or those with limited literacy.
• Environmental Concerns: Certain technologies, if misused, can contribute to overfishing and disrupt marine ecosystems.
• Dependency on Technology: Over-reliance on technological tools can make fishers vulnerable if the technology fails or requires maintenance.

Conclusion and Way Forward 

• Technology has great potential to revolutionize India’s fisheries sector, making it more productive, sustainable, and resilient.
•  However, the adoption of technology must be balanced with considerations of cost, environmental impact, and training to ensure long-term benefits for the sector and its stakeholders.

World’s First CO₂ to Methanol Plant 

Syllabus: GS3/ Environment

In News

• At its Vindhyachal plant, NTPC achieved the first-ever synthesis of CO₂ (captured from flue gas) and hydrogen (from a PEM electrolyzer) into methanol. This pioneering carbon management technology aims to advance sustainable fuel production.

About CO₂-to-methanol conversion

• Carbon Dioxide Capture: CO2 is captured from industrial sources like power plants or directly from the atmosphere.
• Hydrogen Production: Renewable energy sources, such as solar or wind power, are used to produce hydrogen through electrolysis of water.
• Methanol Synthesis: The captured CO2 is combined with hydrogen in the presence of a catalyst to produce methanol. This process typically occurs at high pressure and temperature.

Benefits of CO2-to-Methanol Conversion

• Carbon Capture and Utilization (CCU): It provides a way to utilize CO2, reducing its impact on the atmosphere.
• Renewable Fuel Source: Methanol can be used as a fuel for transportation, power generation, or as a feedstock for chemicals.
• Energy Storage: Methanol can be stored and transported more easily than hydrogen, making it a potential energy storage solution and supporting a transition to hydrogen-based energy systems.
• Versatile Feedstock: Methanol is widely used in producing chemicals, solvents, and plastics, supporting diverse industrial applications.

What is Methanol?

• Brief: Methanol, also known as methyl alcohol or wood alcohol, is the simplest alcohol. It’s a clear, colorless, and flammable liquid with a distinctive odor.
• Key Properties: Colorless, Miscibility (mixes completely with water), Toxic if ingested, Flammability. 

Discovery of X-rays

Syllabus: GS 3/Science and Technology 

In News 

• 129 years ago on 8 November, X-rays were discovered. 

Discovery of X-rays

• Wilhelm Conrad Röntgen discovered X-rays in 1895, noticing that they could produce images of bones by passing through flesh and other soft tissues.
  • Named “X-rays” to denote their unknown nature.
  • Immediate public interest and intense research began in early 1896.
• Properties of X-rays: X-rays have much higher energy and much shorter wavelengths than ultraviolet light, ranging from 0.03 to 3 nanometers, about the size of an atom.
  • Scientists usually refer to X-rays by their energy levels rather than wavelengths.
  • High temperatures (millions of degrees Celsius) emit X-rays, as seen in objects like pulsars, supernova remnants, and black hole accretion disks.
• Further Scientific Discoveries: J.J. Thomson discovered X-rays ionized gases, leading to the discovery of electrons in 1897.
  • H. Becquerel’s research led to the discovery of radioactivity in March 1896.

Applications

• Medical Applications: Physicians started using X-rays in January 1896 to examine bones and organs.
  •  X-rays create images by shooting rays through the body, where bones absorb more rays and cast shadows on X-ray film, making the bones visible.
• X-rays in Astronomy: The Sun’s corona, which is hotter than its surface, emits mostly X-rays.
  • Satellites like Japan’s Hinode collect X-ray data from the Sun to study its corona.
  • X-ray telescopes in space (due to Earth’s atmosphere blocking X-rays) use grazing incidence mirrors to focus high-energy X-rays onto detectors.
  • X-ray data from space telescopes provide information about the temperature, composition, and density of celestial objects.
• X-rays in Planetary Exploration: NASA’s Mars rover, Spirit, used X-rays to detect zinc and nickel in Martian rocks using the Alpha Proton X-Ray Spectrometer (APXS).
• X-rays in Earth’s Aurora: Solar storms send energetic particles to Earth, creating geomagnetic storms that result in auroras and X-ray emissions.
  • These X-rays from auroras are absorbed by Earth’s atmosphere, making them harmless to people on the ground.

Rainforests into Rubber Plantations Alters Soil’s Properties

Syllabus: GS3/ Environment

Context

• A study found that deforestation and conversion of erstwhile rainforests into rubber plantations is detrimental to the soil health.

Cultivation of Natural Rubber

• Natural rubber is derived from the latex of Hevea brasiliensis, a tree native to the Amazon Basin. 
• Rubber cultivation has proliferated in Southeast Asia and other tropical regions due to high global demand. 

Impact of rubber plantations

• Increased DOC Production: Studies indicate that rubber plantations produce higher levels of dissolved organic carbon (DOC) across seasons, surpassing natural rainforest levels.
  • DOC is a key component in the carbon cycle, influencing carbon transformation and migration. However, excessive DOC leaching can be problematic.
• Altered Carbon-Nitrogen ratio: Rubber plantations display a higher DOC to dissolved nitrogen ratio, disrupting the balance needed for optimal soil health.
  • This imbalance affects microbial activity, leading to limited utilization of DOC and greater leaching.
• Nutrient Demands: Rubber trees have high nutrient requirements, depleting soil fertility over time. 
• Soil Organic Matter (OM) Changes: These changes alter the physicochemical and biochemical properties of the soil, particularly the topsoil, which is vital for sustaining diverse ecosystems.

Solutions

• Optimizing Plant Density: Maintaining an optimal number of rubber trees per unit area helps balance nutrient uptake and reduces the stress on soil properties.
• Legume Intercropping: Integrating legume crops in rubber plantations can improve soil nitrogen levels, enhancing microbial activity and nutrient cycling. 
• Sustainable Land Management: Employing soil conservation techniques such as mulching, cover cropping, and reduced tillage can protect soil structure and organic matter content.

Conclusion

• Ensuring soil health in rubber plantation areas is critical not only for long-term agricultural productivity but also for broader environmental conservation. 
• The findings stress the need for integrated land management strategies to harmonize economic interests with ecological integrity.

Geographical Conditions for Rubber production – Climate: Hot and humid conditions with temperatures between 25-35°C. – Rainfall: Annual precipitation between 1,800-2,500 mm. – Soil Type: Deep, well-drained loamy or lateritic soils with good water-holding capacity. – Altitude: Generally grown up to 300 meters above sea level. Rubber Production in India – Kerala: The leading state in rubber production, contributing over 70% of India’s total output. – Other states are Tamil Nadu, Karnataka, Tripura, and Assam.