1 / 25

Air Pollution– Inorganic Gaseous Pollutants

Air Pollution– Inorganic Gaseous Pollutants. Major inorganic gaseous pollutants. Carbon monoxide (CO) Sulfur dioxide (SO2) Nitrogen Oxide (NO, NO2) NOx=NO+NO2 Ozone (O3). HK 1-hour Air Quality Objectives for various air pollutants. a : 3-hr standard, b : annual arithmetic mean. O-O. O2.

nemo
Download Presentation

Air Pollution– Inorganic Gaseous Pollutants

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Air Pollution– Inorganic Gaseous Pollutants

  2. Major inorganic gaseous pollutants • Carbon monoxide (CO) • Sulfur dioxide (SO2) • Nitrogen Oxide (NO, NO2) NOx=NO+NO2 • Ozone (O3)

  3. HK 1-hour Air Quality Objectives for various air pollutants a: 3-hr standard, b: annual arithmetic mean

  4. O-O O2 Fe Fe Fe C-O CO Carbon monoxide: Health effect CO enters the blood stream and binds preferentially to hemoglobin, thereby replacing oxygen. 320 times stronger than hemoglobin-O2 binding

  5. Carbon monoxide: sources and sinks Such as automobiles • Sources • Incomplete combustion (internal engine) • Biomass burning • Methane oxidation • Oxidation of non-methane hydrocarbon • Decay of plant matter • Sink • Reaction with OH radical .OH + CO  CO2 + H. H. + O2 + M  HO2. + M • Removal by soil microorganism

  6. CO formation from methane oxidation

  7. CO emission sources in Hong Kong

  8. Carbon monoxide: Atmospheric chemistry CO + OH + O2 CO2 + HO2. HO2. + NO  NO2 + OH NO2 + hv  NO + O O + O2 + M  O3 + M Net: CO + 2 O2 + hv  CO2 + O3 The net reaction can be viewed as a catalytic oxidation of CO to CO2. Net formation of O3 occurs.

  9. Carbon monoxide: control strategies on the automobile source • Employ a leaner air/fuel mixture (higher air/fuel ratio) • Employ catalytic exhaust reactors • Excess air is pumped into the exhaust pipe. • Air-exhaust mixture pass through a catalytic converter to oxidize CO to CO2. • Addition of oxygenates to gasoline • Examples of oxygenates: methanol, ethanol, MTBE

  10. Sulfur dioxide: Health effect • Produce irritation and increasing resistance in the respiratory tract. • Mucus secretion • In sensitive individuals, the lung function changes may be accompanied by perceptible symptoms such as wheezing, shortness of breath, and coughing. • may also lead to increased mortality, especially if elevated levels of suspended particles are also present.

  11. Sulfur dioxide: Sources and sinks Sources • Combustion of S-containing fuel in electric power plants, vehicles. • S (organic S + FeS2 pyrite) + O2 --> SO2 • Oxidation of H2S: 2H2S + 3 O2 --> 2 SO2 + 2 H2O • H2S is produced as an end product of the anaerobic decomposition of S-containing compounds by micro organisms. • Oxidation of DMS Sink • Converted into sulphuric acid in either gas or liquid phase

  12. SO2 emission sources in Hong Kong

  13. Formation of sulfuric acid and sulfate from SO2 • In gas-phase SO2 + .OH + M  HOSO2. + M HOSO2. + O2  HO2. + SO3 SO3 + H2O + M  H2SO4 + M • In aqueous phase, dissolved SO2 is oxidized to sulfate by • O3 (dominant pathway when pH>5) • H2O2 (dominant pathway when pH<5) • organic peroxides • O2 catalyzed by iron and manganese • Sulfate formation: 2 NH3 + H2SO4  (NH4)2SO4

  14. Sulfur dioxide: Control strategies • Removal of S before DURING burning. Fludized bed combustion: Coal is burned with limestone (CaCO3) (finely pulverized) or dolomite (Ca-Mg carbonate) or both. CaCO3 --> CaO + CO2, CaO + SO2 --> CaSO3. CaSO3 is removed from the stack by an electrostatic precipitator. • removal of S from smokestacks before entering the atmosphere. Flue-gas desulfurization: SO2 is washed from the chimney (flue) gases by absorption in an alkaline solution.

  15. Sulfur dioxide: Control strategies (Continued) 3. Dilution Installation of tall stacks reduces SO2 levels in the immediate neighborhood by dispersing them more widely

  16. Nitrogen oxides: Health Effects NO • Cellular inflammation at very high concentrations. • May be incorporated into hemoglobin in the blood to interfere with the transport of oxygen around the body. NO2 • irritate the lungs • lower resistance to respiratory infection such as influenza.

  17. Nitrogen oxides: Sources and sinks Sources • Fuel combustion in power plants and automobiles. N2 + O2 --> NO 2 NO + O2 --> 2 NO2 • Natural sources: electrical storms; bacterial decomposition of nitrogen-containing organic matter

  18. NOx emission sources in Hong Kong

  19. Nitrogen oxides: Atmospheric chemistry Interconversion of NO and NO2 NO2 + hv  NO + O (1) O + O2 + M  O3 + M (2) NO + O3 NO2 + O2 (3) No net O3 formation NO2 + hv  NO + O (1) O + O2 + M  O3 + M (2) HO2. + NO NO2 + OH (4) RO2. + NO  NO2 + RO. (5) O3 is formed

  20. Nitrogen oxides: Atmospheric chemistry Formation of nitric acid Gas-phase reaction NO2 + OH  HNO3daytime (dominate pathway) Heterogeneous reaction NO2 + O3  NO3 + O2 NO3 + NO2 Û N2O5 N2O5 + H2O (aq) 2 HNO3 (aq) Minor pathway Only operative during nighttime

  21. Nitrogen oxides: Atmospheric chemistry Formation of nitrate HNO3 + NH3  NH4NO3 HNO3 + NaCl(s)  NaNO3 + HCl

  22. Nitrogen oxides: Control strategies 1. Lower the combustion temperature of the furnace in electric power plants 2. Install catalytic converters: catalytic converters in automobiles can remove 76%of NOx from tailpipes.

  23. Two-stage combustion to reduce both NOx and VOCs • First stage: combustion condition—rich in fuel • Second stage: combustion condition—rich in air

  24. Three-way catalytic converter for automobile exhaust (Remove CO, NO and HC) HC + H2O = H2 + CO 2NO + 2H2 = N2 + 2 H2O 2CO + O2 = 2CO2 HC + 2O2 = CO2 + 2H2O Catalyst: Rhodium Catalyst: Rhodium Catalyst: Platium/palladium

  25. NOx control in power plants • Ammonium reduction of NO • 4NH3 + 6NO = 5 N2 + 6 H2O • Urea reduction of NO • 2CO(NH2)2 + 6NO = 5 N2 + 2 CO2 + 4 H2O

More Related