2. - 2.2 – ORGANIC MATTER

3. (Diederik Rousseau UNESCO-IHE Institute for Water Education Online Module Water Quality Assessment 2

4. Degradable organic matter is broken down by microbes, usually with the help of oxygen, although in the absence of oxygen also anaerobic reactions (fermentation and methanogenesis) are possible. Amount of organic waste load expressed as "Oxygen Demand": Theoretical oxygen demand, ThOD, from reaction with O 2, e.g. : C 2 H 5 OH + 3 O 2  2 CO 2 + 3 H 2 O (M.W. * of ethanol = 46)  ThOD of C 2 H 5 OH = = 2.08 mg O 2 /mg ethanol (M.W. = molecular weight; M.W. of C 2 H 5 OH = (2*12)+(5*1)+16 +1= 46) (Degradable) organic matter 3

5. Calculate that the theoretical oxygen demand of: glucose (C 6 H 12 O 6 ) = 1.07 g O 2 /g glucose ethanal (C 2 H 4 O) = 1.82 g O 2 /g ethanal Use the Periodic Table of Elements on the next slides to calculate the molecular weight of both compounds. The two tables can also be used later, for nutrients, heavy metals, etc. Question 4

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8. BOD 5 20 : Biochemical Oxygen Demand, by microbial decomposition in the lab, under standardised conditions: during 5 days at 20 º Celsius in the dark (to prevent algae growth and photosynthesis of O 2 ) Surface water and wastewater normally contain sufficient quantities of bacteria for the analysis. Biochemical Oxygen Demand (BOD) 7

9. Warning: other compounds (than organic matter) can also be converted by microbes while using oxygen. Most common one is NH 4 + : Theoretically:NH 4 + + 2 O 2  NO 3 - + 2H + + H 2 O Nitrogen Oxygen Demand (nBOD) = 4.57 g O 2 / g NH 4 -N ! When no measures are taken to prevent this, the analysis result is called TBOD (total BOD). When a so-called nitrification inhibitor is added (prevents conversion of NH 4 + ), then it is called CBOD (carbon-BOD). Biochemical Oxygen Demand (BOD) 8

10. 9 INTERMEZZO: NH 4 -N or NH 4 ? In water quality monitoring we can express concentration as: Based on the molecule, so mg NH 4 /L (M.W. = 14 + 4 =18) (rounded off) Based on the atom(s), so mg NH 4 -N/L (Atomic weight A.W. = 14) So a water quality of 1.0 mg NH 4 /L corresponds to 0.78 mg NH 4 - N/L. Similarly: the Worlds Health Organization, WHO, guideline for nitrate in drinking water = 50 mg NO 3 /L, equivalent to (14/62)*50 = 11.3 mg NO 3 -N/L. It is highly recommendable to use the “Atoms system” (e.g. to make mass balances) Be very aware, in water quality data interpretation as well as in your own data reporting, of the way the results are expressed ! It’s a big source of errors!

11. In practice, to avoid 5 days delay between sampling and obtaining result: COD: Chemical Oxygen Demand; oxidation by strong chemical oxidant, usually K 2 Cr 2 O 7 (potassium dichromate) in the presence of sulfuric acid at elevated temperatures (~ 150 ºC), during 2 hours The recovery of organic material is usually >95% (meaning that also most non-biodegradable substances are taken into account). For various types of (waste)waters, there is usually a more or less constant ratio between BOD and COD: domestic wastewater: BOD/COD = 0.65 surface water: BOD/COD = 0.40 Chemical Oxygen Demand (COD) 10

12. Mainly from domestic and industrial sources. Some examples are given below: Sources of BOD and COD BOD (mg/L)COD (mg/L) Medium-strength domestic wastewater Metcalf & Eddy (2003) 190430 Textile wastewater (Rwanda) Sekomo (2006) 1972497 Paper mill wastewater (Kenya) (Abira, 2008) 93 - 633571 – 3085 Landfill leachate Kjeldsen et al. (2002) 20 – 57,000140 – 152,000 11

13. BOD and COD in GEMS countries BOD and COD in a GEMS monitoring station, Indonesia BOD - COD 12

14. BOD – COD 13

15. Assignment Have a look at the BOD / COD data for your own country at: http://www.gemstat.org/ 14

16. TOC – Total Organic Carbon DOC – Dissolved Organic Carbon (see lecture notes) Micro-organic pollutants (see Unit 4) Other related parameters 15

17. Impact of BOD on dissolved oxygen in a river 16

18. See Unit 2.6. : Modelling, for the general formula of the oxygen sag curve, for the minimum DO (“depth of oxygen sag is roughly proportional to BOD load”), and for the distance to reach the minimum Impact of BOD on dissolved oxygen in a river 17

19. 18 Wastewater treatment for removing of (see next slide): Suspended solids in sewage (1) CBOD, NBOD by microbes, under strong aeration (2) Bacterial “sludge” (3) Extra: Pathogens (4), e.g. by U.V. radiation Also as extra (expensive!): nutrients (phosphate, nitrate, … see Course 2.3.) Cost recovery often: “the polluter pays” (households, factories, schools,...) The Netherlands: BOD reduction from 1970-2005: > 90% !

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