π Glacier Loss Warning: Only 24% May Survive at 2.7Β°C Warming
β Key Findings:
β’ At 2.7Β°C rise, only 24% of glaciers may remain globally
β’ Limiting to 1.5Β°C (Paris target) could save up to 54% glacier mass
β’ Indian glaciers & Hindu Kush: only 25% ice remains at 2Β°C
β’ Glacier retreat is faster in South Asia, steepest in Indian sub-regions
β Why it Matters:
β’ Major rivers (Ganga, Indus, Brahmaputra) are glacier-fed
β’ Melting raises sea levels, threatens millions of lives
β Study Used:
β’ 21 scientists, 8 models, 200,000+ glaciers simulated
β Key Findings:
β’ At 2.7Β°C rise, only 24% of glaciers may remain globally
β’ Limiting to 1.5Β°C (Paris target) could save up to 54% glacier mass
β’ Indian glaciers & Hindu Kush: only 25% ice remains at 2Β°C
β’ Glacier retreat is faster in South Asia, steepest in Indian sub-regions
β Why it Matters:
β’ Major rivers (Ganga, Indus, Brahmaputra) are glacier-fed
β’ Melting raises sea levels, threatens millions of lives
β Study Used:
β’ 21 scientists, 8 models, 200,000+ glaciers simulated
Mount Etna : world heritage site since 2013
π Key Takeaways: Mount Etnaβs Massive Eruption
β Eruption Details:
β’ Mount Etna, the largest volcano in Europe, erupted explosively on June 1, sending ash and smoke several kilometers into the sky.
β’ Experts suggest the eruption was triggered by increasing pressure inside the volcano, leading to the collapse of the southeast crater.
β’ This was categorized as a Strombolian eruption, characterized by bursts of lava, rock, and ash.
β Location & Importance:
β’ Mount Etna, an active volcano on the east coast of Sicily, is Europeβs largest active volcano and a UNESCO World Heritage site.
β’ The volcano has been active for over 2,700 years and is known for its frequent eruptions.
#MountEtna #Volcano #Eruption #Strombolian #Italy
π Key Takeaways: Mount Etnaβs Massive Eruption
β Eruption Details:
β’ Mount Etna, the largest volcano in Europe, erupted explosively on June 1, sending ash and smoke several kilometers into the sky.
β’ Experts suggest the eruption was triggered by increasing pressure inside the volcano, leading to the collapse of the southeast crater.
β’ This was categorized as a Strombolian eruption, characterized by bursts of lava, rock, and ash.
β Location & Importance:
β’ Mount Etna, an active volcano on the east coast of Sicily, is Europeβs largest active volcano and a UNESCO World Heritage site.
β’ The volcano has been active for over 2,700 years and is known for its frequent eruptions.
#MountEtna #Volcano #Eruption #Strombolian #Italy
π Important Deserts
π Subtropical Hot Deserts
π Great Victoria Desert
β Largest Australian Desert
β Contains many sand dunes and salt lakes
π Great Sandy Desert
β Passes through the Pilbara region
β An ephemeral river, Rudall, flows through here
π Gibson Desert
π Simpson Desert
π Tanami Desert
π Subtropical Hot Deserts
π Great Victoria Desert
β Largest Australian Desert
β Contains many sand dunes and salt lakes
π Great Sandy Desert
β Passes through the Pilbara region
β An ephemeral river, Rudall, flows through here
π Gibson Desert
π Simpson Desert
π Tanami Desert
π Important Volcanoes
π Mount Yasur
β Location: Tanna Island, Vanuatu
β Details: One of the worldβs most accessible active volcanoes; continuous activity.
π Mount Ruapehu
β Location: North Island, New Zealand
β Details: Active stratovolcano; highest point in the North Island.
π Mount Tavurvur
β Location: East New Britain, Papua New Guinea
β Details: Active volcano; part of the Rabaul caldera.
π Mount Yasur
β Location: Tanna Island, Vanuatu
β Details: One of the worldβs most accessible active volcanoes; continuous activity.
π Mount Ruapehu
β Location: North Island, New Zealand
β Details: Active stratovolcano; highest point in the North Island.
π Mount Tavurvur
β Location: East New Britain, Papua New Guinea
β Details: Active volcano; part of the Rabaul caldera.
π Ellsworth Mountains in Antarctica
β Location:
β’ The Ellsworth Mountains are situated in West Antarctica.
β Key Feature:
β’ These mountains include Mount Vinson, the highest peak in Antarctica, standing at 4,892 meters.
#EllsworthMountains #MountVinson #Antarctica #Geography
β Location:
β’ The Ellsworth Mountains are situated in West Antarctica.
β Key Feature:
β’ These mountains include Mount Vinson, the highest peak in Antarctica, standing at 4,892 meters.
#EllsworthMountains #MountVinson #Antarctica #Geography
π Hydrology of the Brahmaputra: Key Insights
π Origin & Flow
The Brahmaputra originates as Yarlung Tsangpo in Tibet, enters India as Siang in Arunachal, and flows as Brahmaputra in Assam before becoming Jamuna in Bangladesh.
π Rainfall Dependency
Arunachal contributes 42.57% of Indiaβs Brahmaputra basin rainfall; Tibet contributes <20% of water yield in India.
π Chinese Projects
Chinaβs upstream dams, including the massive Medog dam and South-North Water Diversion Project, pose concerns but lie upstream of Arunachal, limiting major impact.
π Indian Strategy
India must prepare a long-term river strategy focusing on real-time data, resilience, and multilateral diplomacy to counter upstream threats.
π Origin & Flow
The Brahmaputra originates as Yarlung Tsangpo in Tibet, enters India as Siang in Arunachal, and flows as Brahmaputra in Assam before becoming Jamuna in Bangladesh.
π Rainfall Dependency
Arunachal contributes 42.57% of Indiaβs Brahmaputra basin rainfall; Tibet contributes <20% of water yield in India.
π Chinese Projects
Chinaβs upstream dams, including the massive Medog dam and South-North Water Diversion Project, pose concerns but lie upstream of Arunachal, limiting major impact.
π Indian Strategy
India must prepare a long-term river strategy focusing on real-time data, resilience, and multilateral diplomacy to counter upstream threats.
π Post: JammuβSrinagar Rail Link & Chenab Bridge Highlights
π Project Overview
β 272 km rail line from Udhampur to Baramulla
β Divided into 4 sections with 943 bridges and 36 tunnels
β Includes the Chenab Bridge & Anji Khad Bridge
π Chenab Bridge
β Tallest railway bridge in the world: 359m above riverbed
β Length: 1.315 km, Arch span: 467m, 17 spans
β Cost: βΉ1,486 crore, Steel used: 28,660 MT
β Built to withstand Zone V earthquakes & wind speeds up to 266 km/h
β Design life: 120 years
π Anji Khad Bridge
β Indiaβs first cable-stayed railway bridge
π Operations
β Vande Bharat Express to run 6 days/week
β Expected full DelhiβSrinagar service by Sept 2024
π Project Overview
β 272 km rail line from Udhampur to Baramulla
β Divided into 4 sections with 943 bridges and 36 tunnels
β Includes the Chenab Bridge & Anji Khad Bridge
π Chenab Bridge
β Tallest railway bridge in the world: 359m above riverbed
β Length: 1.315 km, Arch span: 467m, 17 spans
β Cost: βΉ1,486 crore, Steel used: 28,660 MT
β Built to withstand Zone V earthquakes & wind speeds up to 266 km/h
β Design life: 120 years
π Anji Khad Bridge
β Indiaβs first cable-stayed railway bridge
π Operations
β Vande Bharat Express to run 6 days/week
β Expected full DelhiβSrinagar service by Sept 2024
π Mineral Belts of India β Areas & Potentials
π The North Eastern Peninsular Belt
β Area/Region: Extends from the Aravalli range in Rajasthan in the west to the Chotanagpur Plateau in Jharkhand and Odisha in the east.
β Potentials: Rich deposits of coal, iron ore, copper, lead, and zinc.
π The South Western Belt
β Area/Region: Located in the states of Karnataka, Goa, and parts of Maharashtra.
β Potentials: Abundant reserves of iron ore, manganese, limestone, and bauxite.
π The North Western Belt
β Area/Region: Spread across Rajasthan and Gujarat.
β Potentials: Deposits of limestone, marble, gypsum, rock phosphate, lignite, and bentonite.
π The Central Belt
β Area/Region: Located in Chhattisgarh and Madhya Pradesh.
β Potentials:
β’ Coal: Substantial reserves, key for Indiaβs energy needs.
β’ Iron Ore: Supports the iron and steel industry.
β’ Bauxite, Limestone, and Dolomite: Crucial for aluminium production, cement manufacturing, and construction materials.
π The Southern Belt
β Area/Region: Located in Tamil Nadu, Andhra Pradesh, and Karnataka.
β Potentials: Rich deposits of iron ore, bauxite, and limestone.
π The Eastern Belt
β Area/Region: Extends through Odisha, West Bengal, and parts of Jharkhand.
β Potentials: Vast reserves of iron ore, coal, manganese, and chromite.
π The Western Belt
β Area/Region: Located in Maharashtra and Gujarat.
β Potentials: Deposits of manganese, bauxite, limestone, and gypsum.
π The North Eastern Peninsular Belt
β Area/Region: Extends from the Aravalli range in Rajasthan in the west to the Chotanagpur Plateau in Jharkhand and Odisha in the east.
β Potentials: Rich deposits of coal, iron ore, copper, lead, and zinc.
π The South Western Belt
β Area/Region: Located in the states of Karnataka, Goa, and parts of Maharashtra.
β Potentials: Abundant reserves of iron ore, manganese, limestone, and bauxite.
π The North Western Belt
β Area/Region: Spread across Rajasthan and Gujarat.
β Potentials: Deposits of limestone, marble, gypsum, rock phosphate, lignite, and bentonite.
π The Central Belt
β Area/Region: Located in Chhattisgarh and Madhya Pradesh.
β Potentials:
β’ Coal: Substantial reserves, key for Indiaβs energy needs.
β’ Iron Ore: Supports the iron and steel industry.
β’ Bauxite, Limestone, and Dolomite: Crucial for aluminium production, cement manufacturing, and construction materials.
π The Southern Belt
β Area/Region: Located in Tamil Nadu, Andhra Pradesh, and Karnataka.
β Potentials: Rich deposits of iron ore, bauxite, and limestone.
π The Eastern Belt
β Area/Region: Extends through Odisha, West Bengal, and parts of Jharkhand.
β Potentials: Vast reserves of iron ore, coal, manganese, and chromite.
π The Western Belt
β Area/Region: Located in Maharashtra and Gujarat.
β Potentials: Deposits of manganese, bauxite, limestone, and gypsum.
π Modern Methods of Water Management
β Rainwater Harvesting: Collecting rainwater is a very efficient way to replenish the groundwater table and save natural water.
β Pressure Reducing Valves: In a hydraulic system, a pressure-reducing valve essentially regulates the amount of pressure. These valves guarantee that the water level to be used is predetermined.
β Water metering: Installing water metres to track water usage in both residential and business buildings is another effective technique to reduce water waste. It can aid in leak detection.
β Greywater recycling: It is a technique for reusing used and wastewater from showers, washing machines, and kitchen sinks for things like flushing toilets and watering plants.
β Water-efficient Accessories: New developments are pushing the limits of water saving without compromising usage patterns, such as altered spray patterns in taps and showers and enhanced flush pressure in toilets.
β Fog Harvesting: Exploring fog harvesting technologies in hilly regions. Specialized mesh structures capture moisture droplets from fog, providing a valuable water source in areas with limited rainfall. That have been implemented in countries like Chile, Morocco, and Peru.
#gs1 #Geography #mains
Join @Mapping_prelims_mains
β Rainwater Harvesting: Collecting rainwater is a very efficient way to replenish the groundwater table and save natural water.
β Pressure Reducing Valves: In a hydraulic system, a pressure-reducing valve essentially regulates the amount of pressure. These valves guarantee that the water level to be used is predetermined.
β Water metering: Installing water metres to track water usage in both residential and business buildings is another effective technique to reduce water waste. It can aid in leak detection.
β Greywater recycling: It is a technique for reusing used and wastewater from showers, washing machines, and kitchen sinks for things like flushing toilets and watering plants.
β Water-efficient Accessories: New developments are pushing the limits of water saving without compromising usage patterns, such as altered spray patterns in taps and showers and enhanced flush pressure in toilets.
β Fog Harvesting: Exploring fog harvesting technologies in hilly regions. Specialized mesh structures capture moisture droplets from fog, providing a valuable water source in areas with limited rainfall. That have been implemented in countries like Chile, Morocco, and Peru.
#gs1 #Geography #mains
Join @Mapping_prelims_mains
π Indian Ocean Dipole (IOD) & Indian Monsoon π§οΈ
π What is IOD?
The Indian Ocean Dipole (IOD) is a climate phenomenon caused by temperature differences between the eastern (Bay of Bengal) and western (Arabian Sea) regions of the Indian Ocean. It greatly impacts the Indian monsoon and rainfall distribution.
πΉ Positive IOD:
β Warmer West, Cooler East - Warmer sea temperatures in the west and cooler in the east create favorable conditions for rainfall.
β Enhanced Monsoon - Strengthens monsoon circulation, increasing rainfall in central India.
β Increased Rainfall - Observed above-average rainfall in central India during positive IOD years.
π» Negative IOD:
β Cooler West, Warmer East - Temperature reversal leads to a weaker monsoon.
β Weaker Monsoon - Disrupts monsoon circulation, causing a delayed or weak monsoon.
β Drought Risk - Potential drought conditions, particularly in central and eastern India, with below-average rainfall.
#Geography
π What is IOD?
The Indian Ocean Dipole (IOD) is a climate phenomenon caused by temperature differences between the eastern (Bay of Bengal) and western (Arabian Sea) regions of the Indian Ocean. It greatly impacts the Indian monsoon and rainfall distribution.
πΉ Positive IOD:
β Warmer West, Cooler East - Warmer sea temperatures in the west and cooler in the east create favorable conditions for rainfall.
β Enhanced Monsoon - Strengthens monsoon circulation, increasing rainfall in central India.
β Increased Rainfall - Observed above-average rainfall in central India during positive IOD years.
π» Negative IOD:
β Cooler West, Warmer East - Temperature reversal leads to a weaker monsoon.
β Weaker Monsoon - Disrupts monsoon circulation, causing a delayed or weak monsoon.
β Drought Risk - Potential drought conditions, particularly in central and eastern India, with below-average rainfall.
#Geography
π Pollution Dome
π Definition
β Formed when unfavorable atmospheric conditions trap pollutants in urban areas, causing smog buildup.
π Contributing Factors
β Stagnant Air: Calm winds trap pollutants.
β Temperature Inversions: Warm air traps cooler air, preventing vertical dispersion.
β Geographic Bottlenecks: Mountains/valleys restrict air movement, trapping pollutants.
π Additional Factors
β Industrial Activity: Emissions from factories, power plants, and vehicles worsen pollution in stagnant air.
β Unfavorable Weather Patterns: Systems like anticyclones limit atmospheric mixing, trapping pollutants closer to the ground.
#Geography
#environment
π Definition
β Formed when unfavorable atmospheric conditions trap pollutants in urban areas, causing smog buildup.
π Contributing Factors
β Stagnant Air: Calm winds trap pollutants.
β Temperature Inversions: Warm air traps cooler air, preventing vertical dispersion.
β Geographic Bottlenecks: Mountains/valleys restrict air movement, trapping pollutants.
π Additional Factors
β Industrial Activity: Emissions from factories, power plants, and vehicles worsen pollution in stagnant air.
β Unfavorable Weather Patterns: Systems like anticyclones limit atmospheric mixing, trapping pollutants closer to the ground.
#Geography
#environment
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CSP-2025-WR-NameList-Engl-110625.pdf
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