1. Waste Management

2. What are Wastes? Waste (also known as rubbish, trash, refuse, garbage, junk, litter, and ort) is unwanted or useless materials. In biology, waste is any of the many unwanted substances or toxins that are expelled from living organisms, metabolic waste; such as urea and sweat. Basel Convention Definition of Wastes “substances or objects which are disposed of or are intended to be disposed of or are required to be disposed of by the provisions of the law” Disposal means “any operation which may lead to resource recovery, recycling, reclamation, direct re-use or alternative uses (Annex IVB of the Basel convention)”

3. Basel Convention The Basel Convention on the Control of Transboundary Movements of Hazardous Wastes and Their Disposal, usually known simply as Basel Convention, is an international treaty that was designed to reduce the movements of hazardous waste between nations, specially to prevent transfer of hazardous waste from developed to less developed countries (LDCs). It does not, however, address the movement of radioactive waste. The convention is also intended to minimize the amount and toxicity of wastes generated, to ensure their environmentally sound management as closely as possible to the source of generation, and to assist LDCs in environmentally sound management of the hazardous and other wastes they generate. The Convention was opened for signature on 22 nd March 1989, and entered into force on 5 May 1992.

4. The definition………… Produced by the United Nations Statistics Division (U.N.S.D.): "Wastes are materials that are not prime products (that is products produced for the market) for which the generator has no further use in terms of his/her own purposes of production, transformation or consumption, and of which he/she wants to dispose. Wastes may be generated during the extraction of raw materials, the processing of raw materials into intermediate and final products, the consumption of final products, and other human activities. Residuals recycled or reused at the place of generation are excluded."United Nations Statistics Division

5. Kinds of Wastes Solid wastes: wastes in solid forms, domestic, commercial and industrial wastes Examples: plastics, styrofoam containers, bottles, cans, papers, scrap iron, and other trash Liquid Wastes: wastes in liquid form Examples: domestic washings, chemicals, oils, waste water from ponds, manufacturing industries and other sources

6. According to EPA regulations, SOLID WASTE is Any garbage or refuse (Municipal Solid Waste) Sludge from a wastewater treatment plant, water supply treatment plant, or air pollution control facility Other discarded material Solid, liquid, semi-solid, or contained gaseous material from industrial, commercial, mining, and agricultural operations, and from community activities

7. Classification of Wastes according to their Properties Bio-degradable can be degraded (paper, wood, fruits and others) Non-biodegradable cannot be degraded (plastics, bottles, old machines,cans, styrofoam containers and others)

8. Classification of Wastes according to their Effects on Human Health and the Environment Hazardous wastes Substances unsafe to use commercially, industrially, agriculturally, or economically and have any of the following properties- ignitability, corrosivity, reactivity & toxicity. Non-hazardous Substances safe to use commercially, industrially, agriculturally, or economically and do not have any of those properties mentioned above. These substances usually create disposal problems.

9. Classification of wastes according to their origin and type Municipal Solid wastes: Solid wastes that include household garbage, rubbish, construction & demolition debris, sanitation residues, packaging materials, trade refuges etc. are managed by any municipality. Bio-medical wastes: Solid or liquid wastes including containers, intermediate or end products generated during diagnosis, treatment & research activities of medical sciences. Industrial wastes: Liquid and solid wastes that are generated by manufacturing & processing units of various industries like chemical, petroleum, coal, metal gas, sanitary & paper etc. Agricultural wastes: Wastes generated from farming activities. These substances are mostly biodegradable. Fishery wastes: Wastes generated due to fishery activities. These are extensively found in coastal & estuarine areas. Radioactive wastes: Waste containing radioactive materials. Usually these are byproducts of nuclear processes. Sometimes industries that are not directly involved in nuclear activities, may also produce some radioactive wastes, e.g. radio-isotopes, chemical sludge etc. E-wastes: Electronic wastes generated from any modern establishments. They may be described as discarded electrical or electronic devices. Some electronic scrap components, such as CRTs, may contain contaminants such as Pb, Cd, Be or brominated flame retardants.

10. Sources of Wastes Households Commerce and Industry

11. MAGNITUDE OF PROBLEM: in Urban Area (Dhaka) - Per capita waste generation increasing by 1.3% per annum -With urban population increasing between 3 – 3.5% per annum -Yearly increase in waste generation is around 5% annually - India produces more than 42.0 million tons of municipal solid waste annually. -Per capita generation of waste varies from 200 gm to 600 gm per capita / day. Average generation rate at 0.4 kg per capita per day in 0.1 million plus towns.

12. IMPACTS OF WASTE IF NOT MANAGED WISELY Affects our health Affects our socio-economic conditions Affects our coastal and marine environment Affects our climate GHGs are accumulating in Earth’s atmosphere as a result of human activities, causing global mean surface air temperature and subsurface ocean temperature to rise. Rising global temperatures are expected to raise sea levels and change precipitation and other local climate conditions. Changing regional climates could alter forests, crop yields, and water supplies. This could also affect human health, animals, and many types of ecosystems. Deserts might expand into existing rangelands, and features of some of our national parks might be permanently altered.

13. IMPACTS OF WASTE… - Some countries are expected to become warmer, although sulfates might limit warming in some areas. - Scientists are unable to determine which parts of those countries will become wetter or drier, but there is likely to be an overall trend toward increased precipitation and evaporation, more intense rainstorms, and drier soils. - Whether rainfall increases or decreases cannot be reliably projected for specific areas.

14. Impacts of waste…. Activities that have altered the chemical composition of the atmosphere: -Buildup of GHGs primarily carbon dioxide (CO 2 ) methane (CH 4 ), and nitrous oxide (N 2 0). -C0 2 is released to the atmosphere by the burning of fossil fuels, wood and wood products, and solid waste. -CH 4 is emitted from the decomposition of organic wastes in landfills, the raising of livestock, and the production and transport of coal, natural gas, and oil. -N0 2 is emitted during agricultural and industrial activities, as well as during combustion of solid waste and fossil fuels. In 1977, the US emitted about one-fifth of total global GHGs.

15. SOURCES OF HUMAN EXPOSURES Exposures occurs through Ingestion of contaminated water or food Contact with disease vectors Inhalation Dermal

16. Points of contact Soil adsorption, storage and biodegrading Plant uptake Ventilation Runoff Leaching Insects, birds, rats, flies and animals Direct dumping of untreated waste in seas, rivers and lakes results in the plants and animals that feed on it

17. Waste hierarchy Waste hierarchy refers to 3 Rs Reduce, Reuse, Recycle

19. Waste Minimizing solid waste  Minimizing packaging  Recycleable Paper, plastics, metals, glass, wood  Reusable ? Textiles, leather, rubber, metals, wood  Compostable Yard trimmings, food scraps (vegetable)

20. Dealing with Material Use and Wastes

22. CATEGORIES OF WASTE DISPOSAL 1.DILUTE AND DISPERSE (ATTENUATION) Throw it in the river / lake / sea Burn it Basically this involves spreading trash thinly over a large area to minimize its impact Works for sewage, some waste chemicals, when land-disposal is not available Plastic in Pacific

23. 2.CONCENTRATE AND CONTAIN (ISOLATION) Waste dumps, landfills Historically, that’s how most of the solid waste gets treated

24. Useful options Resource recovery Composting Vermicomposting Energy recovery Incineration Pyrolysis Gasification Bio-methanation or anaerobic digestion

25. Impacts of waste on health Chemical poisoning through chemical inhalation Uncollected waste can obstruct the storm water runoff resulting in flood Low birth weight Cancer Congenital malformations Neurological disease

26. Impacts of waste on health Nausea and vomiting Increase in hospitalization of diabetic residents living near hazard waste sites. Mercury toxicity from eating fish with high levels of mercury. Goorah, S., Esmyot, M., Boojhawon, R. (2009). The Health Impact of Nonhazardous Solid Waste Disposal in a Community: The case of the Mare Chicose Landfill in Mauritius. Journal of Environment Health, 72(1) 48- 54 Kouznetsova, M., Hauang, X., Ma, J., Lessner, L. & Carpenter, D. (2007). Increased Rate of Hospitalization for Diabetes and Residential Proximity of Hazardous waste Sites. Environmental Health Perspectives, 115(1)75-75 Barlaz, M., Kaplan, P., Ranjithan, S. & Rynk, R. (2003) Evaluating Environmental Impacts of solid Waste Management Alternatives. BioCycle, 52-56.

27. Effects of waste on animals and aquatics life Increase in mercury level in fish due to disposal of mercury in the rivers. Plastic found in oceans ingested by birds. Resulted in high algal population in rivers and sea. Degrades water and soil quality.

28. Impacts of waste on Environment Waste breaks down in landfills to form methane, a potent greenhouse gas Change in climate and destruction of ozone layer due to waste biodegradable Littering, due to waste pollutions, illegal dumping, Leaching: is a process by which solid waste enter soil and ground water and contaminating them. U.S. Environment Protection Agency (2009)

29. It is estimated that food wasted by the US and Europe could feed the world three times over. Food waste contributes to excess consumption of freshwater and fossil fuels which, along with methane and CO2 emissions from decomposing food, impacts global climate change. Every tonne of food waste prevented has the potential to save 4.2 tonnes of CO2 equivalent. If we all stop wasting food that could have been eaten, the CO2 impact would be the equivalent of taking one in four cars off the road.

30. Benefits of Recycling

31. What is a Hazardous Waste? Hazardous waste is a waste with properties that make it dangerous or potentially harmful to human health or the environment Hazardous waste Ignitability - Ignitable wastes create fires under certain conditions or are spontaneously combustible, or have a flash point less than 60 °C (140 °F). Corrosivity - Corrosive wastes are acids or bases (pH less than or equal to 2 or greater than or equal to 12.5) that are capable of corroding metal containers, such as storage tanks, drums, and barrels. Reactivity - Reactive wastes are unstable under "normal" conditions. They can cause explosions, toxic fumes, gases, or vapors when mixed with water. Toxicity - Toxic wastes are harmful or fatal when ingested or absorbed (e.g., containing mercury, lead, etc.). When toxic wastes are disposed of on land, contaminated liquid may drain (leach) from the waste and pollute ground water. Toxicity is defined through a laboratory procedure called the Toxicity Characteristic Leaching Procedure (TCLP). Major types: Organics and Heavy Metals, Radioactive wastes

32. Benefits of Recycling USA recycled 83 million tons of MSW. This provides an annual benefit of 182 million metric tons of carbon dioxide equivalent emissions reduced, comparable to removing the emissions from 33 million passenger cars. But the ultimate benefits from recycling are cleaner land, air, and water, overall better health, and a more sustainable economy.

33. Municipal Waste On-site (at home) Open Dump Sanitary Landfill Incineration Ocean dumping

34. Open Dump Unsanitary, draws pests and vermin, harmful runoff and leachates, toxic gases Still accounts for half of solid waste Several thousand open dumps in the USA

35. Sanitary Landfill – Layer of compacted trash covered with a layer of earth once a day and a thicker layer when the site is full – Require impermeable barriers to stop escape of leachates: can cause problem by overflow – Gases produced by decomposing garbage needs venting – 1 acre/10,000 people: acute space problem: wastes piling up over 150 million tons/year; – # of landfills down from 8000(1988) to 3091(1996) – NIMBY, NIMFYE, NIMEY, NOPE – NJ ships >5 million tons of waste every year

37. Sanitary Landfill Avoid: – Swampy area/ Flood plains /coastal areas – Fractures or porous rocks – High water table Prefer: – Clay layers – Heads of gullies

38. Monitoring of Sanitary Landfills Gases: Methane, Ammonia, Hydrogen sulphide Heavy Metals: Lead, Chromium in soil Soluble substances: chloride, nitrate, sulfate Surface Run-offs Vegetation: may pick up toxic substances Plant residue in soil Paper/plastics etc – blown by the wind

41. Incineration Solves space problem but: – produces toxic gases like Cl, HCl, HCN, SO 2 – High temp furnaces break down hazardous compounds but are expensive ($75 - $2K/ton) – Heat generated can be recovered: % of waste burnt Japan 67%, Switzerland 80%, USA 6% – North Little Rock, AK saving $50K in heating cost and reducing landfill requirement by 95% – How many MSW combustors exist in the United States? In 1996, 110 combustors with energy recovery existed with the capacity to burn up to 100,000 tons of MSW per day.

42. Burning Wastes Mass burn incineration Air pollution Waste to energy

44. Ocean Dumping Out of sight, free of emission control norms Contributes to ocean pollution Can wash back on beaches, and can cause death of marine mammals Preferred method: incineration in open sea Ocean Dumping Ban Act, 1988: bans dumping of sewage sludge and industrial waste Dredge spoils still dumped in oceans, can cause habitat destruction and export of fluvial pollutants

45. Reducing Waste Incineration, compacting Hog feed: requires heat treatment Composting: requires separation of organics from glass and metals Recycling and Reusing – Recycle of glass containers: 5 million tons – Plastic: marked by types for easy recycling – Converted into Fibers, trash bags, plastic lumber, fill for pillows, insulation etc – Junked cars: 150 – 200 kg of plastics: soon to be recycled

46. Recycling: facts and figures In 1999, recycling and composting activities prevented about 64 million tons of material from ending up in landfills and incinerators. Today, this country recycles 32 percent of its waste, a rate that has almost doubled during the past 15 years. 50 percent of all paper, 34 percent of all plastic soft drink bottles, 45 percent of all aluminum beer and soft drink cans, 63 percent of all steel packaging, and 67 percent of all major appliances are now recycled. Twenty years ago, only one curbside recycling program existed in the United States, which collected several materials at the curb. By 2005, almost 9,000 curbside programs had sprouted up across the nation. As of 2005, about 500 materials recovery facilities had been established to process the collected materials.

48. Waste Exchange One persons waste can be another persons raw material Fluorite from Al smelter in MD Isopropyl alcohol = cleaning solvent Nitric Acid from Electronic Industry = high grade fertilizer Spent acid of steel industry = control for H 2 S

49. Liquid Waste Sewage Highly toxic Industrial Waste & Used Oil – Dilute and Disperse – Concentrate and Contain – Secure Landfill Sealed drums to be put in impermeable holds with monitoring wells to check for leakage: does not work – Deep well Disposal Pumping in deep porous layer bounded by impermeable formations, well below water table $1 million to drill, $15-20/ton afterwards Restricted by geological considerations, can trigger earthquakes

52. Radioactive Waste Disposal Isotopes with short half-lives are gone quickly, those with long half-lives will decay too little Low level wastes: 90% of all radioactive wastes – 20 temporary and 6 commercial disposal sites – States to take care of their low level waste High level wastes e.g., spent nuclear fuel rods – Should be so disposed as to cause less than 1000 death in 10,000 years

53. High Level Waste Depository Rocketing to sun Under Antarctica Ice sheet Subduction Zone Sea bed disposal Bedrock caverns – Granites, basalt, tuff, shale, salt caverns – Salt: High melting point, impermeable in dry condition, self-sealing, cheap resource No permanent high level waste repository yet

54. Requirements for a radio-active waste disposal system Design and Fabricate a System that will – Last thousands of years longer than recorded human history – Be robust enough to isolate highly radioactive material so that it will not threaten human health and environment for more than ten thousand years.

56. WHAT SHOULD BE DONE Reduce Waste - Reduce office paper waste by implementing a formal policy to duplex all draft reports and by making training manuals and personnel information available electronically. - Improve product design to use less materials. - Redesign packaging to eliminate excess material while maintaining strength. - Work with customers to design and implement a packaging return program. - Switch to reusable transport containers. - Purchase products in bulk.

57. WHAT SHOULD BE DONE Reuse - Reuse corrugated moving boxes internally. - Reuse office furniture and supplies, such as interoffice envelopes, file folders, and paper. - Use durable towels, tablecloths, napkins, dishes, cups, and glasses. - Use incoming packaging materials for outgoing shipments. - Encourage employees to reuse office materials rather than purchase new ones.

58. WHAT SHOULD BE DONE Donate/Exchange - old books - old clothes - old computers - excess building materials - old equipment to local organizations

59. WHAT SHOULD BE DONE Employee Education - Develop an “office recycling procedures” packet. - Send out recycling reminders to all employees including environmental articles. - Train employees on recycling practices prior to implementing recycling programs. - Conduct an ongoing training process as new technologies are introduced and new employees join the institution.

60. WHAT SHOULD BE DONE Employee Education - education campaign on waste management that includes an extensive internal web site, quarterly newsletters, daily bulletins, promotional signs and helpful reference labels within the campus of an institution.

61. WHAT SHOULD BE DONE Conduct outreach program adopting an ecologically sound waste management system which includes: waste reduction segregation at source composting recycling and re-use more efficient collection more environmentally sound disposal