Why this chapter matters for UPSC: This chapter is the gateway to India's mining and minerals policy. Every question about steel (SAIL, Tata Steel, India's 2nd-largest producer status), aluminium (Niyamgiri Hills controversy, NALCO, tribal rights under PESA and FRA), copper (Khetri mines, HCL), and the emerging critical minerals agenda (lithium, REEs for EVs and clean energy) traces directly to the metallurgical chemistry here. The reactivity series explains why some metals must be extracted by electrolysis (aluminium — energy-intensive), why gold is found natively, and why corrosion is selective.

PART 1 — Quick Reference Tables

Metals vs Non-metals: Key Property Comparison

PropertyMetalsNon-metals
Physical state (at room temp)Mostly solids (exception: Hg is liquid)Solids, liquids (Br), or gases
LustreShiny metallic lustreDull (exception: iodine has slight lustre)
HardnessGenerally hard (exception: Na, K are soft — cut with knife)Generally brittle (exception: diamond is hardest natural substance)
MalleabilityMalleable (beaten into sheets) — gold is most malleableBrittle; break or crumble when hammered
DuctilityDuctile (drawn into wires) — silver is most ductileNot ductile
ConductivityGood conductors of heat and electricity — silver is best; copper most usedPoor conductors (exception: graphite conducts electricity)
Melting/Boiling pointsGenerally high (exception: Ga melts at 29.7°C; Hg liquid at RT)Generally low (exception: carbon/diamond — ~3550°C)
DensityGenerally highGenerally low
SonoritySonorous — rings when struck (bells = bell metal Cu+Sn)Not sonorous

Reactivity Series (Electrochemical Series)

GroupMetals (Most → Least Reactive)Key BehaviourExtraction Method
Very highK, Na, Ca, MgReact violently with cold water; can't exist free in natureElectrolysis (very energy-intensive)
HighAlReacts with steam; self-passivating (Al₂O₃ layer)Electrolysis of molten Al₂O₃ (Hall-Héroult process)
ModerateZn, Fe, Ni, Sn, PbReact with dilute acids; iron reacts slowly with steamCarbon/CO reduction (blast furnace)
Below HCu, HgDon't react with dilute acids; can be displaced by Hâ‚‚Reduction (mild heating of ore); displacement
LeastAg, Au, PtFound as native metals; extremely stableSimple physical separation; panning for gold

India's Key Metal Ores, Locations, and Companies

MetalMain OreKey Indian LocationsPublic Sector CompanyPrivate Sector
IronHaematite (Fe₂O₃), MagnetiteJharkhand, Odisha, Chhattisgarh, GoaSAIL, RINL (Vizag)Tata Steel, JSW Steel, Essar
AluminiumBauxite (Al₂O₃·nH₂O)Odisha (largest), Jharkhand, Gujarat, MaharashtraNALCO, BALCO (now Vedanta)Hindalco (Aditya Birla)
CopperChalcopyrite (CuFeSâ‚‚)Rajasthan (Khetri), Jharkhand (Singhbhum), MPHindustan Copper Ltd (HCL)
ZincSphalerite (ZnS)Rajasthan (Zawar, Rampura-Agucha — world's 2nd largest zinc mine)HZL (Hindustan Zinc Ltd, now Vedanta)Vedanta
GoldNative gold; gold-bearing quartzKarnataka (Kolar Gold Fields — depleted; Hutti mines active)Hutti Gold Mines Ltd
Rare EarthsMonazite (beach/river sands)Kerala, Tamil Nadu, Odisha coastsIndian Rare Earths Ltd (IREL)

PART 2 — Detailed Notes

1. Properties of Metals

Physical properties: Metals are generally solids at room temperature — the notable exception being mercury (Hg), which is liquid. Gallium (Ga) melts at just 29.7°C (it literally melts on your palm). All other metals are solid.

Gold is the most malleable metal — a single gram of gold can be beaten into a sheet of approximately 1 square metre (used in gold leaf art, gilding, and gold leaf in Ayurvedic formulations). Silver is the most ductile metal — 1 gram can be drawn into 2 km of wire.

Conductivity: Silver is the best conductor of both heat and electricity, but copper is used most widely in electrical wiring because silver is too expensive. Aluminium is used in high-tension power transmission lines (lighter than copper despite slightly lower conductivity — a critical engineering trade-off).

Chemical properties: Metals form basic oxides (e.g., CuO, Fe₂O₃) and react with acids to produce hydrogen gas (except Cu, Hg, Ag, Au, Pt which are below hydrogen in the reactivity series). The more reactive the metal, the more vigorously it reacts with air, water, and acids.

Key Term

Amphoteric metals: Aluminium and zinc react with both acids and strong bases — they are amphoteric. This means Al dissolves in dilute HCl (acid) AND in NaOH solution (base), producing hydrogen in both cases. This property is important in chemical analysis and in the aluminium recycling process.

2. Non-metals

Non-metals occupy the upper-right of the periodic table (with the exception of hydrogen). Most are gases at room temperature (Oâ‚‚, Nâ‚‚, Clâ‚‚, Fâ‚‚, noble gases). The non-metallic solid forms of carbon — diamond and graphite — have dramatically contrasting properties:

  • Diamond: Covalent network solid, each carbon bonded to 4 others — hardest natural substance (10 on Mohs scale), electrical insulator, used in cutting tools, drill bits, abrasives
  • Graphite: Layered structure, each carbon bonded to 3 others in flat sheets — slippery (layers slide), good electrical conductor (delocalised Ï€ electrons), used in pencil "leads," electrodes, and high-temperature lubricants

Phosphorus exists in multiple allotropic forms: white phosphorus (highly reactive, toxic, spontaneously inflammable in air — used in chemical weapons, prohibited under CWC) and red phosphorus (stable, used in match boxes — the striking surface).

Sulphur occurs naturally near volcanic vents and in crude oil/natural gas (as Hâ‚‚S). The Claus process converts Hâ‚‚S from petroleum refining into elemental sulphur, which is then used to make Hâ‚‚SOâ‚„.

3. Occurrence and Extraction of Metals

Terminology:

  • Mineral: Any naturally occurring substance in the earth's crust (may or may not contain a useful metal)
  • Ore: A mineral from which a metal can be profitably extracted; ores are minerals, not all minerals are ores
  • Gangue: Impurities mixed with the ore; must be removed during extraction

Extraction flow:

  1. Concentration/Enrichment — Remove gangue from ore: froth flotation (sulphide ores; gangue wets with water, ore floats with oil froth), gravity separation (denser ore sinks; e.g., tin ore), magnetic separation (magnetite Fe₃Oâ‚„ separated from non-magnetic gangue)

  2. Conversion to oxide — Roasting (heat sulphide ore in air → metal oxide: 2ZnS + 3Oâ‚‚ → 2ZnO + 2SOâ‚‚); Calcination (heat carbonate ore: ZnCO₃ → ZnO + COâ‚‚)

  3. Reduction to metal — Method depends on position in reactivity series:

    • Moderate/low reactivity: carbon/CO reduction in blast furnace (Feâ‚‚O₃ + 3CO → 2Fe + 3COâ‚‚)
    • High reactivity (Al, Mg, Na, K): electrolytic reduction of molten oxide/chloride

  4. Refining — Electrolytic refining gives highest purity metal (99.9%+ copper): crude copper (impure) is anode; pure copper sheet is cathode; CuSOâ‚„ solution is electrolyte — copper dissolves from anode and deposits on cathode; impurities (silver, gold, platinum) sink as "anode mud" and are separately recovered

UPSC Connect

UPSC GS3 — Niyamgiri Hills and Aluminium Extraction: The Niyamgiri Hills in Odisha contain one of India's largest bauxite deposits (~73 MT), overlying a sacred hill of the Kondh tribal community who call it "Niyam Raja" (their god). Vedanta Resources sought to mine it for its aluminium refinery at Lanjigarh. The Supreme Court in 2013 (Orissa Mining Corporation vs MoEF) directed gram sabhas of the affected villages to decide — in a landmark exercise of democratic consent, all 12 gram sabhas rejected the mining. This case established the importance of Free, Prior, and Informed Consent (FPIC) of tribal communities under FRA 2006 and PESA 1996 for mining on forest/tribal land.

3a. [Additional] Thermite Reaction — Reactivity Series in Action

Thermite reaction: Fe₂O₃ + 2Al → Al₂O₃ + 2Fe + enormous heat (~3,000°C)

Aluminium (higher in reactivity series) displaces iron from iron oxide. Reaction is so exothermic it produces molten iron — which is the point.

Key Term

[Additional] Thermit Welding of Railway Tracks (Indian Railways):

The molten iron produced in the thermite reaction is used to fuse two rail ends together — joining rails into Continuous Welded Track (CWR / Long Welded Rail — LWR). The process:

  1. Rail ends are cleaned and aligned; a mould packed around the joint
  2. Thermite mixture (Al powder + Fe₂O₃ in ratio ~1:3 by weight) ignited
  3. Reaction produces ~3,000°C — molten iron flows into the mould gap
  4. On cooling, rail ends are fused into a single continuous piece

Why this matters for UPSC GS3 (Infrastructure):

  • CWR eliminates the clickety-clack joints — reduces track maintenance, allows higher train speeds, and improves ride quality
  • Indian Railways has extensively adopted CWR — now covers a large proportion of the network
  • Railway Board uses the SKV (short preheat) thermit welding technique — faster than conventional thermit welding
  • This is the most direct real-world application of the reactivity series — more reactive Al reduces less reactive Fe from its oxide, releasing the energy difference as heat

3b. [Additional] Hall-Heroult Process — Why Aluminium is Called "Solidified Electricity"

Hall-Heroult process: Aluminium cannot be extracted by carbon reduction (Al is more reactive than carbon in the reactivity series — C cannot reduce Al₂O₃ at practical temperatures). Electrolysis of molten aluminium oxide (Al₂O₃ dissolved in molten cryolite, Na₃AlF₆) is the only viable route.

Key Term

[Additional] Energy cost of aluminium production:

The Hall-Heroult process is extraordinarily energy-intensive:

  • 13,000–17,000 kWh of electricity per tonne of aluminium produced (world average ~15,370 kWh/tonne; more efficient modern cells ~13,000 kWh/tonne)
  • The electrolytic cells run 24 hours a day, continuously — shutting down is impractical (molten bath solidifies; restart takes weeks and damages the cells)
  • At India's electricity cost (~₹6–8/kWh industrial), electricity alone costs ₹80,000–1,20,000 per tonne of aluminium
  • This is why aluminium is called "solidified electricity" or "electricity in metallic form"

UPSC GS3 implications:

  • Aluminium smelters (NALCO at Angul, Odisha; Vedanta/Balco at Korba, Chhattisgarh; Hindalco at Hirakud, Odisha) are located near captive power plants or cheap power sources
  • NALCO's Angul smelter has its own 1,200 MW captive thermal power plant — electricity cost determines competitiveness
  • As India transitions to renewable energy, aluminium smelters are a critical industrial load — cheap renewable power (solar, hydro) could make Indian aluminium greener and more competitive
  • The energy intensity of aluminium also makes recycling economically compelling: recycling aluminium uses only ~5% of the energy of primary production (from ore)

3c. [Additional] Green Steel — EAF vs BOF and India's Decarbonisation Challenge

Steel is India's largest industrial CO₂ emitter. The chemistry of iron extraction (carbon reduction in blast furnace) is inherently carbon-emitting:

Basic Oxygen Furnace (BOF/BF-BOF) route (conventional):

  • Pig iron from blast furnace (using coking coal as both fuel and reducing agent) → refined in basic oxygen furnace
  • CO₂ emissions: >2 tonnes CO₂ per tonne of steel (typically 2.1–2.5 t CO₂/t steel)
  • India's steel sector: ~75–80% BF-BOF route (SAIL, Tata Steel's primary route)

Electric Arc Furnace (EAF) route (greener):

  • Scrap steel (or Direct Reduced Iron/DRI — sponge iron) melted using electric arc
  • CO₂ emissions: up to 75% lower than BOF if powered by clean electricity (~0.5–0.7 t CO₂/t steel with grid electricity; near-zero with 100% renewable electricity)
  • India's EAF share: ~28% of total steel production — but mostly uses coal-based DRI (sponge iron) as feedstock (not scrap), which limits the CO₂ benefit (DRI from natural gas or green hydrogen would be far cleaner)
UPSC Connect

[Additional] India's Green Steel Challenge (GS3 — Industry, Environment):

India is the world's 2nd largest steel producer (144.3 MT crude steel in FY2023-24; ~152 MT projected FY2024-25; PIB/Ministry of Steel). The steel sector contributes ~8–9% of India's total CO₂ emissions. Key policy dimensions:

  • Green Hydrogen for DRI: Green H₂ (electrolysis using renewable energy) can replace coking coal in DRI production — "green DRI" + EAF = near-zero-emission steel. SAIL and Tata Steel have announced pilot projects. H₂ DRI steel could cost ~$150–200/tonne more than conventional steel currently.
  • Green Steel Taxonomy (December 2024): India released the world's first Taxonomy of Green Steel (Ministry of Steel, December 12, 2024). Green steel = CO₂ intensity below 2.2 t CO₂e per tonne of finished steel. Star rating: 3-star (<2.2 t), 4-star (<2.0 t), 5-star (<1.6 t). Takes effect FY2026-27. Enables green procurement (railways, construction). India is the first country to release such a taxonomy.
  • Green Steel Mission: Ministry of Steel preparing a Green Steel Mission with estimated cost of ₹15,000 crore to help industry reduce carbon emissions toward net zero.
  • National Steel Policy 2017 target: 300 MT capacity by 2030. Updated discussions include emissions reduction pathways.
  • PAT Scheme (Perform Achieve Trade): Steel plants are under BEE's PAT cycle — mandatory energy efficiency improvement targets with tradeable energy savings certificates (ESCerts).
  • Challenge: India lacks large scrap reserves (country is young; steel infrastructure not yet end-of-life) — EAF route will depend on DRI until scrap availability improves in 2030s–2040s.

4. Alloys

Alloys are homogeneous mixtures of metals (or metals with non-metals) designed to improve properties. Pure metals are often too soft, too reactive, or too low-melting for engineering applications.

AlloyCompositionKey PropertiesApplications
Stainless steelFe + 10–18% Cr + 8% NiCorrosion-resistant; hard; non-magnetic variantsCutlery, surgical instruments, food industry, architecture
BrassCu + 20–45% ZnMore malleable than Cu; corrosion-resistantMusical instruments, fittings, coins (old 5-paisa)
BronzeCu + 10% Sn (+ sometimes Al, Mn)Harder than Cu; resists saltwater corrosionBells (bell metal), statues, coins, bearings
DuraluminAl + 4% Cu + Mg + MnStrong, light (density ~2.8 g/cm³), corrosion-resistantAircraft bodies, spacecraft, military vehicles
SolderPb (37%) + Sn (63%) — traditionalLow melting point; bonds metalsTraditional electronics soldering (being replaced by Pb-free solder: Sn-Ag-Cu)
AmalgamHg + Ag/Sn/Cu/ZnSoft when mixed, hardens in minutesDental fillings (being phased out due to Hg toxicity; Minamata Convention)
UPSC Connect

UPSC GS3 — Critical Minerals and Clean Energy Transition: The shift to clean energy (EVs, wind turbines, solar panels) has created a new category of strategic resources: critical minerals. Unlike iron or copper, many of these are rare, geographically concentrated, and lack developed supply chains.

India's Critical Mineral Mission (2023) identified 30 critical minerals: lithium, cobalt, nickel, graphite, REEs, titanium, tungsten, vanadium, and others. Key concerns:

  • China's dominance: China controls ~60% of global REE production and ~85% of processing. China's 2023 export controls on gallium and germanium (semiconductor materials) demonstrated the geopolitical risk.
  • India's discoveries: A geological survey in 2023 identified lithium deposits in Reasi district, Jammu and Kashmir (~5.9 million tonnes — one of the world's largest deposits; confirmation and commercial viability studies ongoing). Lithium is critical for EV batteries (lithium-ion).
  • Khanij Bidesh India Ltd (KABIL): A joint venture of NALCO, HCL, and MECL to acquire critical mineral assets overseas (Australia, Argentina, Chile — the "Lithium Triangle" for Li, cobalt in DRC, REEs).
  • Deep sea mining: India has a pioneering deep sea programme. The Samudrayaan mission (launched 2023, 6,000 m depth in the Central Indian Ocean) explores polymetallic nodules (containing Mn, Fe, Ni, Co, Cu) and seafloor massive sulphides (containing Cu, Zn, Pb). India has exploration rights to a 75,000 sq km site in the Central Indian Ocean (ISBA allotment). Deep sea mining raises serious environmental concerns — disturbance of benthic ecosystems, sediment plumes, carbon release from deep-sea sediments.

5. Metal Recycling and E-waste

Urban mining — recovering metals from electronic waste — is increasingly important as primary ore grades decline. E-waste contains gold, silver, palladium, copper, and REEs at concentrations many times higher than primary ores. India is the world's 3rd largest e-waste generator (~3.2 million tonnes/year). The E-Waste Management Rules 2022 (revised from 2016) impose Extended Producer Responsibility (EPR) on manufacturers — they must take back and recycle their products at end-of-life. Formalising the informal e-waste recycling sector (which employs ~500,000 workers, mostly in unsafe conditions) is a key challenge.

[Additional] 3a. India's Rare Earth Elements — Reserves, IREL's Gap, and the REPM Scheme

The chapter lists IREL (Indian Rare Earths Ltd) in the metals table and mentions REEs in the critical minerals section. What is missing is the complete picture: India has the world's 3rd largest REE reserves yet produces less than 1% of global REE output — and the processing bottleneck is almost entirely in China's hands. India's 2025 cabinet-approved REPM scheme is the most significant policy response.

Key Term

Monazite — India's REE feedstock mineral: Monazite is a phosphate mineral containing rare earth elements (primarily cerium, lanthanum, neodymium, praseodymium) along with thorium (a mildly radioactive element). Because of its thorium content, monazite is classified as a "prescribed substance" under the Atomic Energy Act 1962 — only Government of India's IREL (Indian Rare Earths Ltd), a DAE PSU, is permitted to mine and process it.

Where India's monazite occurs: Coastal beach placer deposits (heavy mineral sands) in Odisha (Chatrapur — IREL's OSCOM), Kerala (Chavara), Tamil Nadu (Manavalakurichi), and Andhra Pradesh. Additional hard-rock REE deposits in Rajasthan and Gujarat carbonatites.

India's total REE resources (AMD/DAE, confirmed by Lok Sabha parliamentary reply 2025):

  • Coastal monazite (8 states): 7.23 million tonnes REO (Rare Earth Oxide)
  • Hard-rock deposits: 1.29 million tonnes REO
  • Total: 8.52 million tonnes REO — approximately 3% of world's REO resources (USGS 2026)

The REE separation challenge — why it is so difficult: The 17 rare earth elements (lanthanides) are chemically near-identical — same valence (+3), nearly the same atomic radii, nearly the same solubility behaviour. Separating them requires dozens to hundreds of solvent extraction stages using precisely tuned organic solvents. Each stage also generates radioactive waste streams from associated thorium. For heavy REEs (dysprosium, terbium — critical for high-temperature permanent magnets), separation is even more complex.

China's processing dominance (IEA, 2024):

StageChina's global share
REE mining~60–70%
Separation/refining~91%
Magnet manufacturing~93%
Heavy REE (Dy, Tb) processing~99%
UPSC Connect

[Additional] India's REE Strategy — IREL Gap and REPM Scheme — GS3 (Critical Minerals / Industry):

India's actual REE position:

  • REE production (2024): ~2,900 tonnes REO — 7th globally (USGS MCS 2025)
  • China produces ~270,000 tonnes REO — 93× more than India
  • India mines some REE from monazite at IREL's OSCOM (Odisha) and Chavara (Kerala) but produces only mixed rare earth chloride (lower-value light REEs — cerium, lanthanum) — NOT the high-value separated individual oxides/metals of neodymium, dysprosium, terbium needed for permanent magnets
  • India's permanent magnet imports from China: 84.8–90.4% by quantity, 59.6–81.3% by value (2022-23 to 2024-25) — near-total import dependency for EV motors, wind turbines, industrial motors

Cabinet-approved REPM Scheme (November 26, 2025):

  • Full name: "Scheme to Promote Manufacturing of Sintered Rare Earth Permanent Magnets"
  • Outlay: ₹7,280 crore (₹6,450 crore sales-linked incentive + ₹750 crore capital subsidy)
  • Target capacity: 6,000 MTPA of fully integrated REPM manufacturing
  • Value chain covered: Rare earth oxides → metals → alloys → finished sintered permanent magnets
  • Duration: 7 years (2-year gestation + 5-year incentive disbursement); up to 5 selected entities
  • This is India's first systematic attempt to build an indigenous REE-to-magnet supply chain

Complementary policy framework:

  • National Critical Minerals Mission (approved January 2025): ₹34,300 crore for upstream exploration and mining
  • Dedicated Rare Earth Corridors (Union Budget 2026-27): In Odisha, Kerala, Andhra Pradesh, and Tamil Nadu — for mining, processing, R&D, and manufacturing clusters

UPSC synthesis: India's REE paradox — 3rd largest reserves, 7th largest producer, near-zero processing capacity — is the textbook example of the resource curse's inverse: resources without value chain. The REPM scheme (Nov 2025, ₹7,280 cr) and National Critical Minerals Mission (Jan 2025, ₹34,300 cr) are direct responses. Key exam angles: (i) monazite chemistry (REE + thorium → DAE jurisdiction); (ii) China's 91% processing dominance → export controls risk (China banned REE exports to Japan in 2010; imposed controls in 2023); (iii) connection to EVs/wind turbines (neodymium-iron-boron magnets are in every EV motor and wind turbine generator); (iv) Quad/I2U2 critical minerals cooperation.

[Additional] 3b. Phosphorus — India's Hidden Food Security Vulnerability

The chapter covers phosphorus as a non-metal and mentions phosphate fertilisers (DAP, SSP) in the industrial chemistry table. What is missing is the strategic dimension: phosphate rock is the raw material for phosphorus fertilisers — and India imports ~90% of it, from countries concentrated around Morocco's OCP Group, which controls ~70% of global reserves. This is food security's most overlooked chokepoint.

Key Term

Phosphorus in the food chain — why it is irreplaceable: Phosphorus (P) is a non-metal essential for all life — it forms the backbone of DNA (phosphate-sugar backbone), ATP (energy currency of cells), and plant cell membranes. In agriculture, phosphorus is irreplaceable for:

  • Root development and early plant growth
  • Flowering, fruiting, and seed formation
  • Efficient nitrogen fixation by legume root nodules

Unlike nitrogen (which can be fixed from atmospheric N₂ via the Haber process), phosphorus must come from phosphate rock — there is no atmospheric reservoir or synthetic substitute. Phosphate dispersed into waterways is lost from the agricultural system permanently.

From rock to fertiliser: Phosphate rock (Ca₃(PO₄)₂ — calcium phosphate) → treated with H₂SO₄ → DAP (diammonium phosphate: (NH₄)₂HPO₄) or SSP (single superphosphate: Ca(H₂PO₄)₂ + CaSO₄).

Peak phosphorus: The USGS estimates global economically extractable phosphate rock reserves at ~72 billion tonnes (2023). At current consumption rates (~220 million tonnes/year), this gives a theoretical depletion horizon of ~300 years — but quality and accessibility of remaining reserves are declining, pushing costs upward.

UPSC Connect

[Additional] India's Phosphate Import Dependency — GS3 (Agriculture / Food Security / Critical Minerals):

India's domestic situation:

  • Total rock phosphate resources (National Mineral Inventory): 312.67 million tonnes — but most are low-grade (below 28% P₂O₅, the industry minimum for DAP production)
  • Only commercial mine: Jhamarkotra, Udaipur district, Rajasthan — India's largest and most viable phosphate mine
  • Import dependency: ~90% (PIB, Department of Fertilizers) — India is the world's largest importer of DAP (diammonium phosphate)
  • DAP imports (FY 2024-25): 49.72 lakh metric tonnes — mostly from Oman (39.5%), Qatar (14.7%), UAE (10.7%), Saudi Arabia (8%)
  • Rock phosphate + phosphoric acid: Imported primarily from Morocco, Jordan, Togo, Tunisia, Senegal

Morocco's OCP Group — the dominant supplier:

MetricData
Morocco's global phosphate reserves~70% of world's known reserves (50 billion MT)
OCP's global export market share~31%
OCP's share in India's rock phosphate imports~22%
OCP's share in India's phosphoric acid imports~50%
India's share of OCP's total revenue (H1 2025)19% — structural interdependence

India's supply security strategy:

  • Equity stakes: IFFCO holds ~19% stake (jointly with GoI) in Industries Chimiques du Sénégal (ICS) (660,000 TPA plant); Coromandel International raised stake in BMCC (Senegal) to 53.8% in September 2024
  • Long-term supply agreements (July 2025): India signed 5-year offtake agreements with Saudi Arabia for 3.1 million TPA of phosphates (IPL, Kribhco, Coromandel signatories); renewed 5-year agreement with Morocco's OCP
  • Domestic exploration: GoI targeting exploitation of 30 lakh MT of phosphorite in Rajasthan, MP, UP, and AP
  • NBS scheme: Nutrient Based Subsidy insulates DAP farm-gate price from global volatility; in 2024-25, special one-time subsidy of ₹3,500/tonne on DAP added on top of NBS

Why this is strategically critical: Unlike oil (which can be replaced by renewables), or gas (which can be replaced by hydrogen), phosphorus has no substitute in food production. The geographic concentration of reserves (Morocco ~70%) creates a single-country supply risk comparable to Saudi Arabia for oil. Any disruption to Moroccan phosphate exports (political instability, price manipulation, export controls) would immediately impact India's fertiliser supply and, within 1-2 crop seasons, food production.

UPSC synthesis: Phosphate is the least-discussed but most irreplaceable of India's critical input dependencies. Connect it to: (i) food security (4 pillars — availability/stability columns); (ii) fertiliser subsidy (₹1.8+ lakh crore annually — phosphate import cost is embedded); (iii) India's Morocco relationship (a bilateral not driven by tourism or IT but by phosphate); (iv) green agriculture transition (reducing synthetic phosphate through precision farming, recycling phosphorus from wastewater).

[Additional] 3a. India's Rare Earth Elements Value Chain — IREL, Monazite, and the Separation Bottleneck

The chapter lists IREL in the ore table and mentions REEs in critical minerals. What is missing is the fundamental supply chain problem: India has the world's 3rd largest REE resources but produces only ~1% of global output — because mining is easy; separation is the bottleneck, and China controls 91% of global REE processing.

Key Term

What are Rare Earth Elements (REEs) and why are they hard to separate?

REEs = the 17 lanthanide elements (La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu) + Sc + Y. They always occur together in the same mineral -- never separately. Separating them from each other is the core challenge:

  • All lanthanides are chemically near-identical -- same +3 valence, nearly identical atomic radii, nearly identical behaviour in acid solutions
  • Separation requires dozens to hundreds of solvent-extraction stages -- each stage achieves only marginal separation
  • Each stage produces acidic, radioactive waste (from thorium/uranium impurities in monazite)
  • Heavy REEs (dysprosium, terbium -- essential for high-temperature permanent magnets used in EV motors and wind turbines) are especially difficult to separate; China holds ~99% of heavy REE processing capacity

China built this separation expertise over 40 years -- India has the ore but not the separation infrastructure.

Where REEs come from in India -- Monazite: Monazite is a phosphate mineral rich in REEs and thorium (mildly radioactive). Because of its thorium content, it is a "prescribed substance" under the Atomic Energy Act 1962 -- only IREL (a DAE PSU) can mine and process it.

Coastal placer deposits: Odisha (Chatrapur -- IREL OSCOM), Kerala (Chavara), Tamil Nadu (Manavalakurichi), Andhra Pradesh, Maharashtra.

UPSC Connect

[Additional] India's REE Strategy -- GS3 (Critical Minerals / Science and Technology):

India's REE reserves (AMD/DAE -- PIB confirmed):

CategoryREO (Rare Earth Oxide) Quantity
Coastal monazite (8 states)7.23 million tonnes REO
Hard-rock deposits (Rajasthan, Gujarat)1.29 million tonnes REO
Total~8.52 million tonnes REO

India holds ~3% of world REO resources (USGS MCS 2026). China: ~52%; Namibia: ~22%; USA: ~15%.

The production gap:

  • India REE mine output (2024): ~2,900 tonnes REO -- 7th globally
  • China output: ~270,000 tonnes REO -- ~70% of world total
  • India output = ~1% of China's, despite having ~6% of China's reserves
  • IREL produces mixed rare earth chloride (lower-value, undifferentiated) -- it does NOT produce high-purity separated individual REE oxides/metals at scale

China's processing dominance (IEA, 2024):

StageChina's global share
Mining~60-70%
Separation/refining~91%
Permanent magnet manufacturing~93%
Heavy REE (Dy, Tb) processing~99%

China's 2023 export controls on gallium and germanium demonstrated that processing dominance = geopolitical leverage. REE export controls followed in 2025.

India's policy response:

  • REPM Scheme (Cabinet approval November 26, 2025): "Scheme to Promote Manufacturing of Sintered Rare Earth Permanent Magnets" -- outlay Rs 7,280 crore (Rs 6,450 crore sales-linked + Rs 750 crore capital subsidy); target 6,000 MTPA integrated REPM manufacturing; 7-year duration; up to 5 beneficiaries; covers full value chain (REE oxides to metals to alloys to finished sintered magnets)
  • National Critical Minerals Mission (January 2025): Rs 34,300 crore outlay for exploration and mining
  • Dedicated Rare Earth Corridors (Budget 2026-27): In Odisha, Kerala, Andhra Pradesh, Tamil Nadu -- for mining, processing, R&D, and manufacturing
  • Import dependency: India's permanent magnet imports from China were 84.8-90.4% by quantity (2022-25) -- the REPM scheme directly targets this

UPSC synthesis: REE connects this chapter's metal properties (malleability, ductility, conductivity -- REEs enhance all three in alloys and magnets) to GS3 strategic minerals, China's supply chain dominance, and Aatmanirbhar Bharat in clean energy manufacturing. The AMD/IREL/REPM scheme chain is a direct Mains answer for critical minerals and India's EV/wind turbine ambitions.

[Additional] 3b. Phosphorus -- India's Hidden Food Security Vulnerability

The chapter covers non-metals and lists phosphoric acid (H3PO4) with fertiliser applications. What is missing is the strategic reality: India imports ~90% of its phosphate rock -- there is no substitute for phosphorus in food production, and Morocco holds 70% of the world's known reserves.

Key Term

Why phosphorus is uniquely critical among non-metals:

Most industrial chemicals can be synthesised or substituted. Phosphorus cannot:

  • Phosphorus is essential for ATP (energy molecule), DNA, RNA, and cell membranes in all life
  • Plants cannot grow without phosphate -- no amount of nitrogen or potassium substitutes
  • Unlike carbon (captured from atmosphere) or nitrogen (fixed from air via Haber process), phosphorus has no atmospheric reservoir -- it can only come from rock phosphate mining
  • Once dispersed into waterways or soil sediment, phosphorus is effectively lost from the agricultural system

"Peak Phosphorus": Global phosphate rock reserves ~72 billion tonnes economically extractable (USGS 2023). At 2022 extraction rates, ~300 years remain -- but ore quality declines as higher-grade deposits are exhausted. Unlike oil, no energy alternative replaces phosphorus in food production.

India's domestic phosphate: Total resources ~312.67 million tonnes (National Mineral Inventory) -- but most are low-grade (P2O5 content below the 28-32% industrial threshold for DAP). The only commercially viable deposit: Jhamarkotra mines, Udaipur, Rajasthan (Aravalli range).

UPSC Connect

[Additional] India's Phosphate Import Dependency -- GS3 (Agriculture / Food Security / Strategic Resources):

Scale of dependency (PIB-confirmed, Department of Fertilizers):

  • India is ~90% dependent on imports for rock phosphate
  • India is the world's largest DAP importer -- FY2024-25 DAP imports: 49.72 lakh MT
  • Only ~40% of India's DAP requirement is met domestically; ~60%+ requires imported raw materials

FY2024-25 DAP import sources:

SourceShare
Oman~39.5%
Qatar~14.7%
UAE~10.7%
Saudi Arabia~8.0%

Rock phosphate: Morocco, Jordan, Togo, Mauritania Phosphoric acid: Morocco (~50%), Tunisia, Senegal

Morocco's OCP Group -- the structural dependency:

  • Morocco holds ~70% of the world's known phosphate reserves (~50 billion tonnes; Middle East Monitor, July 2024)
  • OCP products cover ~90% of India's domestic DAP consumption through supply chains
  • India accounts for 19% of OCP's total revenue (H1 2025) -- interdependence runs both ways

India's supply security measures:

  • Coromandel International: Raised stake in BMCC (Senegal rock phosphate miner) to 53.8% (September 2024)
  • IFFCO: 19% stake (jointly with GoI) in Industries Chimiques du Senegal (ICS), 660,000 TPA
  • July 2025: IPL, Kribhco, and Coromandel signed 5-year offtake with Saudi Arabia for 3.1 million TPA of phosphates; also signed 5-year agreement with Morocco's OCP
  • Nutrient Based Subsidy (NBS) scheme: Insulates domestic DAP price from global phosphate volatility; special one-time subsidy of Rs 3,500/tonne on DAP in 2024-25

The 2021-22 price shock lesson: When global phosphate prices tripled (Chinese export restrictions + supply disruptions), India's fertiliser subsidy bill surged by Rs 1.5 lakh crore -- demonstrating direct fiscal and food security risk. India accelerated LTAs with Morocco, Jordan, and Gulf producers as a direct response.

UPSC synthesis: Phosphorus connects non-metal chemistry (this chapter) to food security (SDG 2 Zero Hunger), GS3 agriculture policy (DAP subsidy, NBS scheme), strategic resources (import vulnerability, Morocco monopoly), and diplomacy (IFFCO overseas equity stakes, India-Morocco MoUs). The "~90% import dependency + no substitute" makes phosphate India's most strategic non-metallic mineral -- more concentrated than oil, because renewable energy can replace fossil fuels but nothing replaces phosphorus in food.

Exam Strategy

Prelims traps:

  • Mercury is the only metal that is liquid at room temperature. Gallium melts at ~30°C (near room temperature) but is usually counted as a solid metal at standard room temperature (25°C).
  • Graphite is a non-metal that conducts electricity — a common exception question. It conducts because of delocalised electrons in the graphene layers.
  • Aluminium forms a protective oxide layer (Alâ‚‚O₃) that prevents further corrosion — this is why aluminium household items don't "rust" visibly despite being reactive.
  • Copper is below hydrogen in the reactivity series — it does NOT react with dilute Hâ‚‚SOâ‚„ or HCl. It reacts with hot concentrated Hâ‚‚SOâ‚„ and HNO₃.
  • In electrolytic refining, the impure metal is the anode (dissolves) and pure metal is the cathode (deposits) — frequently asked question.
  • The anode mud in copper refining contains silver, gold, and platinum — this is how those precious metals are recovered as by-products.

Mains frameworks:

  • Critical minerals → clean energy transition → China's supply chain dominance → India's Critical Mineral Mission → KABIL → strategic partnerships (Quad, I2U2)
  • Niyamgiri → FRA 2006 → gram sabha consent → FPIC → tribal rights vs development → SC jurisprudence
  • Deep sea mining → Samudrayaan → polymetallic nodules → ISA regulations → environmental concerns → blue economy

Practice Questions

Prelims:

  1. With reference to the "Critical Mineral Mission" of India, which of the following minerals is/are included?
    (a) Lithium and Cobalt only
    (b) Rare Earth Elements only
    (c) Lithium, Cobalt and Nickel only
    (d) Lithium, Cobalt, Nickel, Rare Earth Elements, and other strategic minerals

  2. The process of electrolytic refining is used to obtain very pure metals. In this process, the impure metal forms the:
    (a) Anode
    (b) Cathode
    (c) Electrolyte
    (d) Both anode and cathode alternately

Mains:

  1. What are critical minerals? Discuss the importance of critical minerals for India's energy transition and the steps taken to secure their supply. (CSE Mains 2023, GS Paper 3, 15 marks)

  2. Discuss the significance of deep-sea mining for India's mineral security. What are the environmental concerns and how is India approaching this frontier? (CSE Mains 2022, GS Paper 3, 10 marks)