You're offline — cached pages and worlds still work
Drishti Innovations logo
Drishti Innovations

Strategies for Control of Environmental Pollution

Environmental Chemistry: Strategies for Control of Environmental Pollution

What You'll Learn

  • The 12 principles of Green Chemistry (Anastas-Warner) and how to apply atom economy
  • Green chemistry examples: H₂O₂ bleaching and liquid CO₂ dry cleaning
  • How catalytic converters work (Pt/Pd/Rh) to control vehicle emissions
  • Electrostatic precipitator operation for removing SPM from stack gases
  • Primary, secondary, and tertiary sewage treatment processes
  • Bioremediation using microorganisms to clean polluted sites

Level 1 — Core Concepts

Green Chemistry — Principles

Green Chemistry (also called sustainable chemistry) designs chemical processes that reduce or eliminate the use and generation of hazardous substances.

Developed by Paul Anastas and John Warner (1998) — 12 principles:

#PrincipleKey Idea
1Waste PreventionBetter to prevent waste than treat it
2Atom EconomyMaximise incorporation of starting materials into final product
3Less Hazardous SynthesisUse/generate substances with little or no human/environmental toxicity
4Designing Safer ChemicalsDesign drugs/products with desired function, minimal toxicity
5Safer Solvents and AuxiliariesAvoid auxiliary substances (solvents, separation agents) where possible
6Design for Energy EfficiencyRun reactions at room temperature/pressure where possible
7Renewable FeedstocksUse agricultural or biological raw materials rather than fossil fuels
8Reduce DerivativesAvoid unnecessary derivatisation (protecting groups) → extra steps = more waste
9CatalysisUse catalysts (selective) in preference to stoichiometric reagents
10Design for DegradationProducts should break down into innocuous materials after use
11Real-time Pollution MonitoringDevelop methods to monitor and prevent hazardous substance formation
12Inherently Safer ChemistryChoose processes with minimal accident potential

Atom Economy:

Atom Economy (%) = (Molecular mass of desired product / Total molecular mass of all products) × 100
  • Addition reactions: AE = 100% (no by-products)
  • Substitution reactions: AE < 100% (leaving group is waste)
  • Rearrangement reactions: AE = 100%
  • Elimination reactions: AE < 100%

Example: Hydrogenation of ethylene:

CH₂=CH₂ + H₂ → CH₃CH₃
MM of desired product (ethane) = 30
Total MM of products = 30
Atom Economy = (30/30) × 100 = 100%

Green Chemistry in Practice

H₂O₂ as Bleaching Agent (replacing Cl₂)

Old process — Cl₂ bleaching:

Cl₂ + H₂O → HCl + HOCl
HOCl → bleaching action
By-products: organochlorine compounds (AOX) → persistent, toxic, carcinogenic

Green alternative — H₂O₂ bleaching:

H₂O₂ → [O] + H₂O    (under mild conditions)
[O] → bleaching action
By-product: H₂O (harmless)

Advantages:

  • No toxic by-products
  • Atom economy = higher
  • Biodegradable
  • Used in paper pulp bleaching and textile industries

Liquid CO₂ as Dry Cleaning Solvent (replacing PERC)

Old process — Perchloroethylene (PERC, tetrachloroethylene, CCl₂=CCl₂):

  • Effective degreaser/solvent
  • Problem: carcinogenic, ozone-depleting, persistent groundwater contaminant

Green alternative — Liquid CO₂:

  • CO₂ at ~60 bar, 31°C → supercritical CO₂ → excellent solvent
  • After cleaning, pressure released → CO₂ gas escapes (recyclable), clothes are dry
  • No toxic residue, no solvent waste
  • Atom economy concern not applicable here (solvent, not reagent) — advantage is non-toxic, recyclable solvent

Catalytic Converters

Fitted in vehicle exhaust system to convert toxic emissions into harmless gases before release.

Catalyst: Platinum (Pt), Palladium (Pd), and Rhodium (Rh) on honeycomb alumina support

Three reactions:

Reaction 1: CO oxidation
2CO + O₂ → 2CO₂          (catalysed by Pt/Pd)

Reaction 2: Hydrocarbon combustion  
CₓHᵧ + O₂ → CO₂ + H₂O   (catalysed by Pt/Pd)

Reaction 3: NOₓ reduction
2NO → N₂ + O₂  }         (catalysed by Rh)
2NO₂ → N₂ + 2O₂}

Overall: CO, unburned hydrocarbons, NOₓ → CO₂, H₂O, N₂

Design features:

  • Honeycomb structure → maximises catalyst surface area
  • Three-way catalyst (TWC) → handles all three reaction types simultaneously
  • Requires lead-free petrol (Pb poisons/deactivates the catalyst — "catalytic converter poisoning")

Electrostatic Precipitator (ESP)

Removes suspended particulate matter (SPM, dust, fly ash) from industrial stack gases.

Working principle:

  1. Stack gas passes between two electrodes (collecting plates + discharge wires)
  2. High voltage (~50,000 V) applied → corona discharge → ionises gas molecules → produces ions
  3. Ions attach to dust/SPM particles → particles become charged
  4. Charged particles migrate to oppositely charged collecting plate
  5. Particles accumulate on plates → periodic rapping dislodges them → collected in hoppers

Efficiency: >99% removal of particulates
Used in: thermal power plants, cement kilns, smelters, paper mills

Does NOT remove gaseous pollutants (SO₂, NOₓ, CO) — only solid/liquid particles.


Sewage Treatment

Municipal wastewater (sewage) treatment occurs in three stages.

Primary Treatment (Physical)

  • Screening: coarse bar screens remove large solids (rags, plastic)
  • Grit chamber: settling removes sand, gravel
  • Primary sedimentation: 1–2 hour settling → removes ~50% suspended solids, ~30% BOD
  • Output: primary sludge (settled solids) + primary effluent

Secondary Treatment (Biological)

  • Aerobic treatment: effluent aerated → bacteria consume dissolved organic matter → BOD reduced by ~90%
    • Methods: trickling filters (bacteria on gravel), activated sludge process (aerated tanks), rotating biological contactors
  • Anaerobic treatment: primary sludge digested in anaerobic digesters → produces biogas (CH₄ + CO₂) — energy recovery
  • Secondary effluent has BOD < 30 ppm (from ~200 ppm raw sewage)

Tertiary Treatment (Chemical/Physical)

For removal of residual pollutants before discharge into sensitive water bodies:

  • Reverse osmosis (RO): removes dissolved salts, heavy metals, residual BOD
  • Chemical precipitation: add alum [Al₂(SO₄)₃] or lime [Ca(OH)₂] → flocculate phosphates, turbidity
  • Activated carbon adsorption: removes trace organics, colour, odour
  • Chlorination/UV: disinfection to kill pathogens
  • Produces: near-drinking quality water (used for industrial cooling, irrigation, or groundwater recharge)
Sewage Treatment Efficiency Summary:
Raw sewage: BOD ~ 200 ppm
After primary: BOD ~ 130 ppm (35% reduction)
After secondary: BOD < 30 ppm (>85% reduction)
After tertiary: BOD < 5 ppm (>97% reduction)

Bioremediation

Use of living organisms (mainly microorganisms) to break down or neutralise pollutants in a contaminated environment.

OrganismPollutant DegradedExample
Pseudomonas putidaPetroleum hydrocarbons, toluene, naphthaleneOil spill cleanup
Dehalococcoides spp.Chlorinated solvents (PCE, TCE)Contaminated groundwater
Geobacter spp.Heavy metals (Cr⁶⁺ → Cr³⁺), uraniumIndustrial site cleanup
Phytoremediation (sunflower, Indian mustard)Heavy metals (Pb, As, Cd)Uptake metals into plant biomass

Pseudomonas and oil spills:

  • Pseudomonas putida was the first patented genetically engineered organism (Ananda Chakraborty, 1980)
  • Capable of degrading multiple hydrocarbon fractions in crude oil
  • Converts hydrocarbons → CO₂ + H₂O (complete mineralisation)

In situ bioremediation: treating contaminated soil/groundwater without excavation
Ex situ bioremediation: excavating contaminated material and treating in bioreactors


Level 2 — JEE Depth

Atom Economy — Calculation Practice

Reaction A (substitution): CH₄ + Cl₂ → CH₃Cl + HCl

Desired product = CH₃Cl (MM = 50.5)
All products = CH₃Cl + HCl (50.5 + 36.5 = 87)
Atom Economy = 50.5/87 × 100 = 58%
HCl is "waste" in terms of atom economy

Reaction B (addition): CH₂=CH₂ + H₂ → CH₃CH₃

Atom Economy = 30/30 × 100 = 100%
All atoms from reactants appear in desired product

Addition reactions always have 100% AE — one of the reasons catalytic hydrogenation is preferred in green chemistry.

Catalytic Converter — Why Rh for NOₓ?

Rh is specifically chosen for NOₓ reduction because:

  • Rh adsorbs NO strongly on its surface
  • Adsorbed NO dissociates: 2NO(ads) → N₂ + O₂ (surface reaction)
  • N₂ is released (harmless); O₂ used by Pt/Pd for CO oxidation
  • Pt/Pd are more effective oxidation catalysts; Rh is more effective for reduction

Reverse Osmosis — Osmotic Pressure

π = MRT (van't Hoff equation for dilute solutions)

For seawater (0.6 M NaCl): π ≈ 27 atm
RO requires applied pressure > π (typically 55–80 atm for seawater desalination)
Freshwater forced through semipermeable membrane; dissolved salts rejected

Biogas Composition and Anaerobic Digestion

Primary sludge (cellulose, proteins, fats) → anaerobic bacteria (acetogenic + methanogenic) → biogas

Step 1 (hydrolysis + acidogenesis):
C₆H₁₂O₆ → 2CH₃CH₂OH + 2CO₂  (acetogens)

Step 2 (methanogenesis):
CH₃COO⁻ + H₂O → CH₄ + HCO₃⁻  (methanogens, e.g., Methanosaeta)
4H₂ + CO₂ → CH₄ + 2H₂O

Biogas composition: ~65% CH₄, ~35% CO₂ (trace H₂S)
Calorific value: ~22 MJ/m³

Worked Examples

Example 1: Atom Economy calculation

Problem: Calculate the atom economy for the manufacture of ethanol from
ethylene by (a) direct hydration and (b) indirect hydration via ethyl sulphate.

Case (a): Direct hydration
  CH₂=CH₂ + H₂O → CH₃CH₂OH
  
  MM desired product (ethanol) = 46
  Total MM of products = 46 (only ethanol)
  Atom Economy = 46/46 × 100 = 100%
  
  This is an ADDITION reaction → 100% atom economy

Case (b): Indirect hydration via sulphuric acid
  Step 1: CH₂=CH₂ + H₂SO₄ → CH₃CH₂OSO₃H  (ethyl sulphate)
  Step 2: CH₃CH₂OSO₃H + H₂O → CH₃CH₂OH + H₂SO₄
  Net:    CH₂=CH₂ + H₂O → CH₃CH₂OH
  
  Same net reaction, but H₂SO₄ is used and regenerated → not a by-product
  For the OVERALL net equation, AE is still 100%.
  
  However, the indirect route has additional considerations:
  - Uses corrosive H₂SO₄ (Principle 3: less hazardous synthesis violated)
  - Higher energy requirement (Principle 6 violated)
  - Requires additional processing steps
  → Direct hydration (catalytic, steam process) is the GREEN choice

Answer: Both routes: AE = 100% for net equation.
Direct hydration preferred on green chemistry principles 3, 5, 6.

Example 2: Catalytic converter reactions

Problem: A catalytic converter processes exhaust gas containing CO (500 ppm),
NO (300 ppm), and C₈H₁₈ (50 ppm). Write the balanced reactions for each
pollutant and identify which metal catalyst is needed.

Pollutant 1: CO → CO₂
  2CO + O₂ → 2CO₂
  Catalyst: Platinum (Pt) or Palladium (Pd) — oxidation catalyst
  
  Result: CO (toxic, binds Hb) → CO₂ (harmless greenhouse gas)

Pollutant 2: NO → N₂
  2NO → N₂ + O₂
  Catalyst: Rhodium (Rh) — reduction catalyst (Rh most effective for N–O bond breaking)
  
  Result: NO (toxic, irritant, acid rain precursor) → N₂ (harmless)

Pollutant 3: Octane (C₈H₁₈) → CO₂ + H₂O
  2C₈H₁₈ + 25O₂ → 16CO₂ + 18H₂O
  Catalyst: Pt/Pd — oxidation catalyst
  
  Result: Unburned hydrocarbon (smog precursor) → CO₂ + H₂O

Overall converter function:
  Input:  CO, NOₓ, unburned HC  (toxic)
  Output: CO₂, N₂, H₂O         (harmless or greatly reduced harm)
  
Important notes:
  - Must use unleaded petrol (Pb deactivates Pt/Pd/Rh)
  - Operating temperature: 400–800°C (converter heats up during driving)
  - Cold-start problem: first 1–2 minutes, converter not yet hot → significant raw emissions

Common Mistakes

MistakeWhy It's WrongCorrect Approach
Calculating atom economy using only the desired product's molar massAE compares mass of desired product to TOTAL mass of ALL products (all atoms in reaction)AE = (MM of desired product / sum of MM of ALL products) × 100
Saying catalytic converters remove SO₂Catalytic converters are designed for CO, NOₓ, and unburned HCs; not SO₂SO₂ requires flue-gas desulphurisation (scrubbing with lime slurry) — separate process
Confusing primary, secondary, tertiary sewage treatmentPrimary = physical settling; secondary = biological/microbial; tertiary = chemical/RODo not call biological treatment "primary" — primary treatment has NO biology
Thinking electrostatic precipitators remove gaseous pollutantsESPs work by charging particulate matter; gaseous molecules are too small and not capturedESPs remove SPM (fly ash, dust); gaseous SO₂, CO, NOₓ require scrubbers or catalytic treatment

Quick Check

Q1. Atom economy for the reaction: CH₂=CH₂ + HBr → CH₃CH₂Br is:

A) 50%
B) 75%
C) 100%
D) 25%

Q2. In a three-way catalytic converter, which metal primarily catalyses the reduction of NOₓ to N₂?

A) Platinum
B) Palladium
C) Rhodium
D) Gold

Q3. The BOD of raw municipal sewage before treatment is approximately:

A) 3–5 ppm
B) 10–20 ppm
C) 50–100 ppm
D) 150–250 ppm

Q4. H₂O₂ is preferred over Cl₂ for bleaching in green chemistry because:

A) H₂O₂ is a stronger bleaching agent than Cl₂
B) H₂O₂ produces water as the only by-product, not toxic organochlorines
C) H₂O₂ is less expensive than Cl₂ at industrial scale
D) H₂O₂ has a higher atom economy than Cl₂ in all contexts

Q5. Pseudomonas bacteria are used in bioremediation of:

A) Heavy metal contamination (Hg, Pb)
B) Radioactive waste
C) Petroleum hydrocarbon oil spills
D) Excess nitrates in agricultural runoff

Answer Key: 1-C | 2-C | 3-D | 4-B | 5-C


NCERT Links

  • NCERT Class 12 Chemistry — Chapter 14: Environmental Chemistry
  • Pages 424–432 (strategies for pollution control)
  • Key sections: 14.5 Strategies to control environmental pollution
  • Green Chemistry section (14.5.1): Anastas-Warner principles, examples
  • Cross-reference: NCERT Class 12 Chemistry Chapter 5 (Surface Chemistry) for catalyst mechanism
  • Also see NCERT Exemplar, Chapter 14 for assertion-reason questions on sewage treatment

Drishti

🎯 Exam Tips

  • Atom Economy = 100% for addition reactions ALWAYS — this is a guaranteed point if you remember it
  • Three-way catalytic converter metals: Pt + Pd (oxidation of CO, HC) and Rh (reduction of NOₓ) — Rh is the unique one
  • Sewage treatment order: Primary (physical) → Secondary (biological, 90% BOD removal) → Tertiary (chemical/RO) — don't mix the order
  • Green chemistry H₂O₂ vs Cl₂ bleaching and liquid CO₂ vs PERC dry cleaning are classic examples frequently asked

📊 Weightage

  • Strategies for pollution control: 0–1 question per JEE Main paper
  • Green Chemistry increasingly featured in recent papers (2022–2026 trend)
  • Atom economy calculation is a high-confidence point scorer

🔗 Related Topics

  • Surface Chemistry (catalyst mechanism — adsorption on Pt/Pd/Rh surface)
  • Electrochemistry (electrostatic precipitator — high-voltage corona discharge)
  • Biomolecules (microbial digestion in secondary sewage treatment)
  • Chemical Kinetics (catalytic reaction rates in converter)

📝 Revision Checklist

  • State the atom economy formula and calculate for addition vs substitution reactions
  • Name 3 Anastas-Warner principles with examples
  • Explain H₂O₂ bleaching advantage over Cl₂ with chemical equations
  • Write all 3 catalytic converter reactions with correct metal catalyst
  • Describe ESP working principle in 4 steps
  • Distinguish primary, secondary, and tertiary sewage treatment with BOD reduction
  • Name Pseudomonas sp. as bioremediation organism for oil spills
  • Define bioremediation and give one in situ and one ex situ example

Key Takeaways (TL;DR)

  • What You'll Learn
  • Level 1 — Core Concepts
  • Level 2 — JEE Depth
  • Worked Examples

Master this topic with Drishti OS

Get unlimited mock tests, AI-powered mentorship, and complete video courses when you join.

Start Free Practice