Environmental Biotechnology

1. Environmental Biotechnology TarhubAsghar AmraMasooma RaanaKhokhar Vishal Sharoon

2. MICROBIAL DESULPHURIZATION OF COAL PRESENTED BY: TARHUB ASGHAR 13-10205 BIOL 473

3. Introduction • Along with many contents coal contains high amount of sulphur content. • Sulphur dioxide emits when coal burnt causing air pollution. • For the removal of this pollutant we can used many method through which we can remove sulphur dioxide. • One possible method is flue gas desulphurization.

4. Flue gas desulphurization • It is a set of technologies used to remove sulfur dioxide (SO2) from exhaust flue gases of fossil-fuel power plants, and from the emissions of other sulfur oxide emitting processes. • Installation of this equipment in developing countries is often expensive. • So that is why low cost technologies are used to removed SO2.

5. Microbial desulphurization • During coal combustion heat is released to produce steam in boilers. • After combustion process sulphur in the form of pyrite FeS2 is transformed into gas phase. • Bioleaching support a use of bacteria for the removal of pyritic sulphur from coal. • Acidithiobacilliusferrooxidians and sulfolobusacidocaldarius were well known to be effective and removing pyritic sulphur from coal.

6. Biological Cleaning • Bioleaching – Two different mechanisms for biologically catalyzed oxidation of pyrite (sulfur combined with iron) • Direct • Indirect

7. Direct Bioleaching • Requires direct contact between the bacterium and the pyrite. • Generally not favored as with some coals the microorganisms are too large to fit inside the coal pores. • Reaction: 2 FeS2 + 7 O2 + 2 H2O → 2 FeSO4 + 2 H2SO4

8. Indirect Bioleaching • The indirect method is more prominent due to the limiting size of the coal pores compared to the size of the microorganism. • Reactions FeS2+ 14 Fe3+ + 8 H2O → 15 Fe2+ + 16 H+ + 2 SO4 2 Fe2+ + 2 H+ + O2 → 2 Fe3+ + H2O

10. microbial desulfurization process(microbial floatation separation method) • Recent years have seen increased burning of pulverized coal and the development of a liquid fuel called CWD, which combines coal with water. For this reason, much attention is being focused on microbial desulfurization processes. • "floatation separation method" is a process in which the ash is removed from coal.

11. Process • A suspension made with pulverized coal mixed with water is put into a separation tank. From the bottom of the tank, air bubbles are blown in, to which the particles of coal adhere and float. • The particles of ash are hydrophilic, so do not adhere to the air bubbles and sink of their own dead weight. • pyrite particles have the same surface properties as coal and would float along with the coal, not allowing any separation to take place.

12. Process • Iron bacteria added to the suspension selectively adheres to the pyrite particles, making them become hydrophilic. The pyrite particles then sink, enabling desulfurization while floatation separation is taking place.

13. Biomining Presented by: Amra M Qadir Roll number: 13-10034

14. Biomining: • The use of micro-organisms to facilitate the extraction of metals from sulphide or iron-containing ores . • The metal solublization process is due to a combination of : • Chemistry • Microbiology

15. Bioleaching: • Metals is exctracted into the water this process is known as bio-leaching. • Bio-oxidation : it is used in gold recovery where the metal remains in the mineral . • Metals for which this techniue is employed includes: copper , nickle, cobbalt, zinc and uranium. • For recovery of gold and silver , the activity of leaching bacteria is applied only to remove interfering metal sulfides from ores.

16. Common microganisms: • Thiobacillus. • Leptospirillum. • These are mesophill, acidophile and chemoithoautotrophes. They obtain energy from oxidation of either ferrous ion to ferric or reduction of sulphur compounds to sulphuric acid.

17. Mechanism: • Microorganism enhance metal sulfides oxidation and leaching kinetics is still controversial. • One school of thought. • Other school of thought. • Recent research has demonstrated that glycocalyx in AcidithiobacillusFerrooxidans and Leptospirillumferrooxidans consists of a weak exopolysaccharides layer to form a bridge between the bacterium and the crystal surface. It creates a microenvironment where most of the bioleaching processes takes place.

18. The most efficient leaching reaction takes place within the exoploysaccharide layer that surrounds the microbial cells. • Bioleaching process take place in three phase systems: • Aqueous phase. • Solid phase. • Gaseous phase.

19. Types of biomining: • Irrigation type( CU): • Crushed ore is stacked in columns, dumps or heaps. • Leaching solution percolate through the ore. • Irrigation may also be conducted in-situ. • Minimizes expense of operation. • Maximizes quantity of material that can be processed.

20. Stirred tank reactor: • Continuously operated, highly aerated. • Process is highly controlled. • Maximizes the decomposition rate. • To perform bioleaching process the adequate suspension aeration and mixing is necessary. • Selection of a suitable reactor for a biomining process and design should be based in the physical , chemical and biological characteristics of the system.

21. Bioleaching and biooxidation are best performed in a continuos mode of operation in which volumetric productivity is high and reactor volumes can be kept low. • In biomining the mineral species involved are usually recalcitrant to microbial action.and affinity is quite low. • It improves the yield and efficiency of bioleahing processes.

22. Heap and dump leaching: • Best known operation is Kennecott mine in Bingham canyon, Utah. • Numerous dumps having upto billion tones low grade ore. • Run of mine ore is pilled upto 350m. • Irrigated with a iron and sulphate rich waste water stream( raffinate). • Raffinate is devoid of CU. • Microorganisms solubilize sulfide into sulfate. • Copper sulfate rich is removed from the bottom, the CU removed then the CU free liquid recycled to dump. • Takes years to recover metal from an ore.

23. Advantages: • Simple equipment. • Low investment and operation costs. • Acceptable yields for the treatment of lower grade ores.

24. Disadvantages: • Plied material is very heterogenous. • No close process control can be exerted. • Rates of oxygen and carbon dioxide transfer can be obtained are low.

25. Gold: • AU is finely divided in pyrite ores. These recalcitrant ores in which Au can’t be readily solublized by cyanidation and which normally require roasting at 700F in oxygen. • The ore is first concentrated then microbially treat to decompose the arsenopyrite which makes the AU more accessible to cyanidation. This is called as biooxidation because the Au is not solubilized by micro-organisms.

26. Biox Process: • Ground gold containing concentrate is fed with phosphate, ammonium and water into a series of continuous reactors. • Solid content in vessel is 10-18%. • Residence time in reaction is 3 days. • Process operate at about 40c and PH is 1.5

27. Advantages of bio-oxidation Au: • Portion of the ore needs to be decomposed to allow high Au recovery. • Capital costs are 50% for roasting/ pressure oxidation. • Waste disposal is easy ( PH increased to 5 with lime causes to precipitate

28. Disadvantages: • Maximum solid concentration is about 20% solids. • A higher concentration of solids damages fermenters for a given oxygen transfer rate and damages microorganisms by shear forces. This maximum limits bio-oxidation to high value minerals.

29. Gold Bio-oxidation: • It is extracted from ores using cyanide. • First stirred tank bileach plant was commissioned in 1986 to pretreat a sulfidic gold concentrate to enhance gold recovery. • Recalcitrant ores are those in which gold is encased in a matrix of pyrite.

30. Advantages of biomining: • Rich surface ores are naturally exhausted, and lower grade ores must be used. • It can be carried out n in situ. That is, recovery can be conducted without bringing vast quantities of ore and waste rock to the surface. • Conventional mining processes ( roasting, smelting) consume large quantities of energy,whereasbiomining consumes minimal energy.

31. Conventional mining produces acidic dump water and air pollution as enviromental problem. It tends to generate limited hazardous wastes.

32. BIOINSECTICIDESRaana KhokharVishal Sharoon

33. Insect Killers Insect pests • Threat to agriculture system • Animal & human diseases • Chemical control • Annual cost $350 million

34. Conventional Chemical Pesticides can be problematic? • Lack of specificity • Persistence in the environment • Accumulation to damaging levels in high animals (birds)

35. Alternative? Microbial pathogens • Bacteria • Fungi • Protozoa • Virus

36. Why use Microbial Pathogens? • Specific • Cheap to produce • Narrow activity spectrum • No residue problems • 0% resistance But, • Not cultured at a large scale

37. Successful Bioinsecticide genus Bacillus • Spore forming • Gram positive • Rod-shaped soil bacterium

38. Bacteria-effectiveness • produce Protein Endotoxins during Sporulation • not contact poison but, • Ingestion single Bacillus species/subspecies may attack entire order or a single species

39. Production Fermentation process Product: Bacillus thuringiensis(δ-endotoxin) • 30° C • pH 7.2-7.6 • 25-30 hours • Media: starch, corn-steep liqour, casein, and yeast extract • 3000 tones per year

40. δ -endotoxin Insecticidal Crystal Proteins • Produced alongside spores • 30% of cell mass • Genes encoding ICPs are on Plasmids • Variations in amino acid residues causes dramatic effect in the activity

41. Septicemia-Blood Poisoning

42. δ-endotoxin In human & animal guts, • ICPs denature due to low pH • Hydrolyzed by proteases

43. Eco-Friendly B. thuringiensisendotoxins breakdown to non-toxics due to UV light

44. BIOINSECTICIDESFORMULATIONSVishal Sharoon13-10284

45. Formulations prepared from B. thuringiensis: • That kill caterpillars • B. thuringiensis var. kurstaki • Best known & most widely used • Controls leaf- feeding caterpillars

46. 2. That kills mosquitoes: • B. thuringiensis var. israelensis • Do not kill larval stages of higher flies • Control vectors of malaria & river blindness

47. 3. That kills beetles: • B. thuringiensis var. san Diego & B. thuringiensis var. enebrionis • Controls beetles of Coleoptera

48. Genetically engineered B. thuringiensis • Attack target insects • Possess multiple ICP genes • Controls development of insect resistance

49. ICPproduction in plants • By incorporating into another bacteria • Pseudomonas fluorescens • By inserting genes directly into crop plants

50. Other bioinsecticides • prepared from Bacillus papillae • Provides long lasting control • Not cultivated in artificial media • Mode of action is different