1. Solid Waste Disposal & the 3R’s

2. Big Ideas
Problem: We live in a single use, throw-away society that encourages the consumption
There is no “away”
Trash often does not stay put
Trash represents waste:
wasted resources, wasted energy, wasted land, wasted hours, wasted productivity
The best solution is prevention:
Preventing pollution is much safer & cheaper than trying to clean it up

3. Focus should be: Source Reduction
Source reduction (waste prevention) means consuming and throwing away less
You can:
Purchase durable, long-lasting goods
Seek products and packaging that are as free of toxins as possible
Avoid single use items
Saves resources
Saves money
Reduces pollution

4. Throw-a-way society
Only Humans produce waste other organisms can’t use
Until a society becomes relatively wealthy
Very little waste
1900’s most material reused/recycled
junk/scrap dealers
After WWII
Cultural/Social changes
Disposable products became the norm
Planned Obsolescence
Products designed to be replaced
Increases consumption & waste

5. Material Flow
Human Economy:
Mostly linear
Nature:
Closed loop

6. Solid waste: any unwanted or discarded material we produce that is not a liquid or gas.
Municipal solid waste (MSW): produced directly from homes & cities. (Mostly paper)
Industrial solid waste: produced indirectly by industries that supply people with goods and services.
Manufacturing
Agriculture
Mining/Drilling/Raw material extraction
Hazardous (toxic) waste: threatens human health or the environment because it is toxic, chemically active, corrosive or flammable. 2%
98%
50%
15%
35%
focus on MSW, even though majority is industrial

7. Municipal Solid Waste (MSW)
Waste collected by municipalities from
households,
small businesses,
institutions such as
schools,
prisons,
municipal buildings
hospitals.

8. US leads the world in trash production
The US has 4.5% of world’s population, but produces 1/3 of the world’s trash.
4.5 pounds per person
2 times as much as other industrialized nations
5 – 10 times as much as developing countries
Two reasons to be concerned
¾ represents unnecessary waste of earth’s finite resources
In producing the products we use and discard, we are creating huge amounts of
Air pollution
Water pollution
Land degradation
Solid and hazardous waste

9. Wasting Resources What we throw away in our high waste economy
Enough aluminum to rebuild country’s commercial airline fleet every 3 months
Discarded carpet each year would cover Delaware
27 million tons of edible food each year
Enough paper to build a wall 11 feet high across the entire country every year
Americans spend more money on trash bags than 90 other countries spend on everything they buy.

10. What Makes Up The Solid Waste Stream?
Biggest single category:
Paper
MSW
31% - paper
33%- organic materials (yard waste, food scraps, wood)
12%- plastic
18%- durable goods (appliances, tires)
80% – 90% could be recycle, or composted

11. What Makes Up The Solid Waste Stream?
Another way to look at MSW:
By Source
Biggest source: Containers & packaging

12. Reduce, Reuse, Recycle
Reduce- waste minimization or prevention – Source reduction
Reuse- reusing something like a disposable cup more than once
Recycle- materials are collected and converted into raw materials and then used to produce new objects

13. Landfills Where does MSW go? What we actually do
What we should be doing
What we actually do
(Landfills)

15. Dump versus a Landfill
Dump – an open site where waste was dumped in a pile.
Problems: attract pests of all kinds, create hazardous leachate, noxious smells
Dumps are illegal in the US
Landfill – an engineered system designed to dispose of waste in manner that protects public health and natural resources
Require extensive engineering systems to protect groundwater, prevent pest infestations and contain dust, odor and blowing trash.

16. Constructing a Landfill
Basics:
Build Landfill: Dig big hole, line it, install leachate collection system
Add trash (daily load is called a cell), cover each day with layers of dirt and clay to minimize smell and rodents
Close Landfill: Install methane collection system, cap the landfill, install storm water runoff system and groundwater monitoring system
Designate for other uses: Park, nature reserve, golf course.
No buildings: ground is unstable and methane can build up in structures

17. Sanitary Landfill: Compacted solid waste Topsoil Sand Clay Garbage
Synthetic liner
Subsoil
When landfill is full,
layers of soil and clay
seal in trash
Methane storage
and compressor
building
Electricity
generator
Leachate
treatment system
Methane gas
recovery
Pipe collect explosive
methane gas used as fuel
to generate electricity
Compacted
solid waste
storage tanks
monitoring
well
Groundwater
Leachate pipes
Leachate pumped up
to storage tanks for
safe disposal
Clay and plastic lining
to prevent leaks; pipes
collect leachate from
bottom of landfill

19. Federal Landfill Standards set by RCRA
Location restrictions
Away from faults, wetlands, flood plains, or other restricted areas.
Composite liners requirements
Geomembrane (plastic) liner over 2 feet of compacted clay soil lining the bottom and sides
Leachate collection systems
On top of the liner (usually with sand for drainage) and removes leachate from the landfill for treatment and disposal.
Operating practices
Compacting and covering waste frequently with several inches of soil (daily cover)
Benefits: reduce odor, control litter, insects, and rodents and protect public health.
Closure and post-closure care
Include covering landfills and providing long-term care and monitoring of closed landfills.
Methane collection & monitoring
Groundwater monitoring
Requires testing groundwater to determine whether leachate has escaped from the landfill.

20. Sanitary Landfill

21. Problems With Landfills
Most MSW is buried in landfills that eventually are expected to leak toxic liquids into the soil and underlying aquifers
Siting issues (“Not In My Backyard!”)
Leachate contamination
adjacent waterways & aquifers
human toxicity
Methane gas release  greenhouse gas
– From anaerobic decomposition of organic matter
Benefit: collect methane and use it for energy
Incomplete decomposition of waste

22. Methane Collection System
Collects valuable methane that results from anaerobic decomposition inside the landfill
Safety feature and energy source!
Methane = Natural gas
Can be a form of Waste to Energy

23. Choosing a Location (“Siting”) a Landfill
Controversial
Political
Soils with clay
Away from water sources
Above the water table
On the outskirts of populous centers
How far away: balance between transportation costs and proximity causing nuisance and eyesore
NIMBY resistance
Environmental justice

24. Benefits of Landfills Can accept large amounts of trash
Most convenient method of disposal
Regulated to make safer
Even though most expected to eventually leak
Accepts most MSW
Including paper, plastic, metal, organic material,etc
Exception: no hazardous waste
Including batteries, paints, solvents, pesticides, etc

26. Case Study: What Should We Do with Used Tires?
We face a dilemma in deciding what to so with hundreds of millions of discarded tires.

27. What Should We Do with Used Tires?
They can burn for years producing large amounts of toxic air pollutants... Very hard to put out

28. Tires
Are allowed in landfill if they are shredded otherwise they are recycled.

29. Incineration Where does MSW go? What we actually do
What we should be doing
What we actually do
(Landfills)

30. Incinerators Burning MSW can be used to generate electricity
Burn trash  create heat  boil water to make steam  steam turns a turbine  electricity!
Called Waste-to-energy
Incinerators must have:
Scrubbers
devices that use a liquid spray to neutralize acidic gases.
Removes SO2 , acidic gases and particulate matter
Filters or electrostatic precipitators
progressive series of filters remove tiny particles
Removes particulate matter

31. Incinerator Diagram:

32. Incinerators Volume of solid waste reduced by 90% after incineration
Produces heat that can make steam to generate electricity

33. Incineration Site selection often controversial Ash problems:
Smelly; ugly; truck traffic
(toxic) ash disposal
siting: NIMBY
Air pollution
Hg & Dioxins
Discourages recycling
Expensive to build
Ash problems:
fly ash (PM)
bottom ash
Can be toxic

35. Reuse/recycle Where does MSW go? What we actually do
What we should be doing
What we actually do
(Landfills)

36. Solving the MSW Problem
The only TRUE solution to our MSW problem is the 3 R’s (in order of preference):
Reduce
Reuse
Recycle

37. (1) Reduce Source reduction – MOST EFFECTIVE!!!
Design & manufacture products in ways that decrease the volume of solid waste created
Redesign packaging
Companies moving to Zero-Waste Manufacturing
Subaru
Reuses materials, reclaims solvents & paints, recycle materials, remaining 1% is burned for energy
Technological development can constantly decrease the size and weight of a product
Reduce consumption

38. (2) Reuse
Extends resource supplies and requires less energy than mining raw materials & manufacturing
Increases residence time before disposal
Examples
Refillable beverage containers
Reusable grocery bags
Many cities have banned plastic bags
Dallas stores must charge 5¢ per bag
Repair
Repurpose: newspaper for animal bedding
Ebay, flea markets, garage sales
Borrow books from library

39. (2) Reuse Developing Countries Developed Countries
Reusing can be hazardous for poor who scavenge in open dumps.
They can be exposed to toxins or infectious diseases.
Developed Countries
Reusing products is an important way to reduce resource use, waste, and pollution

40. (3) Recycling
Conservation of resources by converting material into new product.

41. Recycling is increasing in US
Other Developed Countries:

42. 2 Categories Closed-loop Becomes the same item Needs no/few new inputs
old carpet → new carpet
Open-loop
Becomes a different item
Needs additional inputs
plastic bottle → fleece jacket

43. (3) Recycle Recycle these: Every ton of recycled paper saves:
Glass bottles, newspapers, steel cans, plastic bottles, cardboard, office paper
Every ton of recycled paper saves:
17 trees
7000 gallons of water
4100 kwatt-hrs of energy
3 cubic yards of landfill space

44. (3) Recycle Recycling Paper Recycling Glass US recycles 50%
Denmark recycles 97%
Recycling Glass
US recycles 25%
Costs less than new glass
Can be used to make glassphalt

45. (3) Recycle 50% of aluminum recycled in US World avg = 70%
Recycled aluminum uses 90% fewer resources

46. Plastic Recycling
Recycling some plastics is chemically and economically difficult to recycle. Plastics are often recycled into other forms of plastic and those plastics are often not recyclable.
Many plastics are hard to isolate from other wastes.
Recovering individual plastic resins does not yield much material.
The cost of virgin plastic resins is lower than recycled resins due to low subsidized fossil fuel costs.
There are new technologies that are making plastics biodegradable
Plastics must be sorted according to their resin identification code which indicates the type of material they were made from.
Polyethylene terephalate, High density polyethlene, Polyvinyl chloride, Low density polyethylene, Polypropylene, Polystyrene, Other polycarbonates
Soft drink bottles
Shampoo and fast food service items
Yogurt containers, straws, and bottle caps
Other various plastics
Milk bottles and butter tubs
Grocery & bread bags
Styrofoam

47. Characteristics of Recyclable Materials
*Easily isolated from other waste
*Available in large quantities
*Valuable – there is a market

48. Benefits of Recycling Reduces global warming Reduces acid deposition
Reduces urban
air pollution
Make fuel
supplies
last longer
Reduces
Saves
energy
energy demand
water pollution
Recycling
Reduces solid
waste disposal
mineral
demand
Protects
species
habitat
destruction

49. Two Ways to Recycle
(MRF) Materials Recovery Facilities – Single Stream
Machines and workers separate trash at a facility
Pros: can increase the amount of recycled materials, provides high paying jobs
Cons: expensive to build and operate, can produce air pollution, only economically feasible when scrap prices are high
Concerns: removes responsibility and awareness from the consumer
Source separation
Consumers separate their trash into different bins
Pros: cheaper, can be less energy intensive, lower start-up costs
Cons: not everyone does it, relies on consumers
Concern: May waste resources if it requires two separate trucks to visit each house, better to have single truck with dual collection capabilities

50. Recycling – trying to achieve Zero-Waste
San Francisco – goal to minimize the amount of waste that ends up in a landfill
IBM & Recology on video library page

51. Nike: Reuse-A-Sneaker
Poor unsafe working conditions
Inadequate wages
Toxic solvents, adhesives, and rubber manufacturing
VOC’s
Imposed a Cradle to Grave Analysis
“Nike Considered”: likert scale of sustainability at each step in the process
Friendlier adhesives/rubber
Organic Exchange Cotton
Reuse-A-Shoe
Nike Grind – to make playground & other athletic surfaces

52. Why is recycling not the whole answer to our waste problem

54. Composting – Recycling Nutrients
Composting is the controlled decomposition of organic matter, such as food and yard wastes, into humus, a soil-like material

56. Composting: Recycling Nutrients
Organic Matter:
Food scraps
Yard waste
Agricultural manure
Sewage Sludge
Can also include
Wood
Paper (usually better to recycle, unless soiled)

57. Composting - Pros Reduces volume in landfills
Organic matter in landfills decompose anaerobically → produce methane
Produces humus
Fertilizer
Enhances soil texture
Retains moisture
Anyone can do it
Large or small scale
Can be sold or distributed to community

58. Composting - Cons Takes time and space Can be inconvenient
Need to monitor
C:N ratio 30:1 for best microbial action
Add moisture
Aerate/Agitate to add O2
If not properly maintained
Can smell bad
Attract flies, rats, etc

59. City Compost Pile: Large scale Composting

60. Hazardous Materials & Integrated Waste Management

61. The two largest classes of hazardous wastes are
Hazardous waste: is any discarded solid or liquid material that is toxic, ignitable, corrosive, or reactive enough to explode or release toxic fumes.
The two largest classes of hazardous wastes are
toxic heavy metals (lead, mercury, arsenic, cadmium, chromium).
synthetic organic compounds or Persistent Organic Pollutants (POP) (e.g. pesticides, PCBs, dioxins, DDT)

62. Hazardous Waste in the Environment
Hazardous Wastes in the environment are harmful when absorbed in high concentrations.
Heavy metals
POPs
Can easily leach into groundwater.
Chemicals and toxins can be released at safe levels but may react or combine with other chemicals, from synergism, to create dangerous mixtures.
They can be taken up by organisms via food or water or simply absorbed from the surroundings.
Will bioaccumulate and biomagnify in the food chain
Are Persistent
Stay in environment a long time
Spraying apples with insecticide, Japan

63. Hazardous Waste & Health
Heavy metals - Neurotoxins
Damage Brain & nerve function
Metal retardation
Hyperactivity, Shortened attention span, Behavior disorder
Kidney & Skeleton damage
Death
POP –
Disrupt systems
Endocrine
Gender benders
Thyroid disorders
Reproductive
Birth defects
Reduced fertility
Immune
Cancer

64. Hazardous Waste Harmful to humans/ecosystems
The majority is byproduct of industrial processes – 36 million ton/year
Households generate 1.5 million ton/year
Only 5% recycled
Expensive & difficult to treat & dispose of
No truly good way of disposal - 2 options:
1) source reduction: don’t create it in the 1st place
2) Use a less toxic alternative

65. Hazardous Waste Sources
Cleaning machinery
Manufacturing processes
Mining and drilling
Agriculture
Dry cleaners
Auto service stations
Households: over cleaners, batteries
Fuels, solvents, lubricants, pesticides

66. What Harmful Chemicals Are in Your Home?
Cleaning
Gardening
• Disinfectants
• Pesticides
• Drain, toilet, and
window cleaners
• Weed killers
• Ant and rodent killers
• Spot removers
• Septic tank cleaners
• Flea powders
Paint
• Latex and oil-based paints
• Paint thinners, solvents,
and strippers
Automotive
• Stains, varnishes,
and lacquers
Figure 22.15
Science: harmful chemicals found in many U.S. homes. The U.S. Congress has exempted disposal of these materials from government regulation. QUESTION: Which of these chemicals are in your home?
• Gasoline
• Wood preservatives
• Used motor oil
• Antifreeze
• Artist paints and inks
• Battery acid
General
• Solvents
• Dry-cell batteries
(mercury and cadmium)
• Brake and
transmission fluid
• Glues and cements
• Rust inhibitor and
rust remover
Fig , p. 534

67. Household Hazardous Waste
Common household items such as
paints, cleaners, oils, batteries and pesticides
Look for Labels
danger, warning, caution, toxic, corrosive, flammable or poison
Disposal
Deliver to your local HHW collection facility for proper disposal
Better: Share these materials with neighbors to reduce waste

68. Hazardous Waste Regulations (US)
Two major federal laws regulate the management and disposal of hazardous waste in the U.S.:
RCRA - Resource Conservation and Recovery Act
Tracks waste progress
Cradle-to-the-grave system to keep track of waste.
CERCLA - Comprehensive Environmental Response, Compensation, and Liability Act
Commonly known as Superfund program.
Clean up abandoned waste sites

69. Resource Conservation and Recovery Act (RCRA)
Regulates hazardous waste from “cradle to grave”
EPA regulates the generation, transportation, treatment, storage, and disposal of hazardous waste
Regulates disposal of solid waste in landfills – sets standards
Regulates handling of household hazardous waste
Regulates storage of materials in underground storage tanks (i.e. gas tanks)
Works to minimize the generation of hazardous waste

70. Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA) (Superfund Act)
Clean up abandoned hazardous waste sites.
Most severe sites on NPL – National Priorities List
NJ has 9,000 contaminated sites, but only 114 have final NPL status
Cleanup is very expensive, so who pays?
If a responsible party is located and financially able, they are required to pay for the cleanup.
If no party can be found, the government pays to clean up the site
Superfund was funded by a tax on oil and chemical companies until 1995, now it is funded by the general tax fund
Passed in 1980 In response to the Love Canal incident

71. Superfund Sites 2014 – 1,332 sites NJ – 114 CA – 97 PA – 95 NY – 85
TX – 50
Superfund Sites

72. Love Canal, NY - There Is No “Away”
Between , Hooker Chemical sealed multiple chemical wastes into steel drums and dumped them into an old canal excavation (Love Canal).
In 1953, the canal was filled and sold to Niagara Falls school board
In 1957, Hooker Chemical warned the school not to disturb the site because of the toxic waste.
In 1959 an elementary school, playing fields and homes were built disrupting the clay cap covering the wastes.
In 1976, residents complained of chemical smells and chemical burns from the site, increased rates of illness, birth defects

73. Love Canal
President Jimmy Carter declared Love Canal a federal disaster area.
The area was abandoned in 1980
In 1983, Love Canal became the 1st superfund site
Took 20 years & 400 million to clean up
It still is a controversy as to how much the chemicals at Love Canal injured or caused disease to the residents.
difficult to link long-term health effects

74. How many other Love Canals are there around the world
Chemical time bombs
Leaking chemical storage tanks and drums
Pesticides dumps
Piles of mining wastes

75. Brownfield
Abandoned industrial and commercial sites contaminated with hazardous wastes
Less contaminated than superfund sites
Factories, junkyards, older landfills, gas stations
Problems
Lots of sites: 450,000 in US
No uniform Federal Standards
Clean up is managed by city/state gov
Varies widely by region
No legal liability enforcement
Can’t compel polluter to clean up
Success
Can revitalize/rehabilitate for public good
Parks, athletic fields, nature preserves, etc

76. Brownfields Pros to remediation: Cons:
Can be done as part of urban redevelopment projects
Allows urban areas to return to profitable uses: parks, athletic field, preserves
Remove threat from hazardous wastes for both human and nature
Cons:
Expensive
Older sites may be difficult to clean to new standards.
Have to dispose of contaminated material
Have to disturb soil and habitat
Could contaminate another area

77. HAZARDOUS WASTES Management of the Waste we are Producing
(1) source reduction
(2) conversion to less hazardous materials
(3) long-term storage

78. Disposal of Hazardous Waste
Best - reduce
Stop production of products that contain hazardous wastes
find substitutes / alternative substances
Recycle and/or reuse
Better - mitigate
Convert into less hazardous substances by incineration, biological treatment or thermal treatment
Worst - store
Haz. Waste landfill, surface impoundments, underground injection wells,

79. Conversion to Less Hazardous Substances
Physical Methods: using charcoal or resins to separate out harmful chemicals.
Chemical Methods: using chemical reactions that can convert hazardous chemicals to less harmful or harmless chemicals, usually by incineration.
Biological Methods:
Bioremediation: bacteria or enzymes help destroy toxic and hazardous waste or convert them to more benign substances.
Phytoremediation: involves using natural or genetically engineered plants to absorb, filter and remove contaminants from polluted soil and water.
Mycoremediation : fungi mycelium absorbs contaminants from soil

80. DEALING WITH HAZARDOUS WASTE
We can produce less hazardous waste and recycle, reuse, detoxify, burn, and bury what we continue to produce.

81. Biological: Detoxifying Wastes
-Bioremediation
Uses organisms to break down wastes
Bacteria & microbes
-Phytoremediation uses plants to remove wastes from soil
-Mycoremediation uses fungi mycelium
Very good at absorbing heavy metal

82. Radioactive contaminants Inorganic metal contaminants
Organic contaminants
Poplar tree
Brake fern
Sunflower
Willow tree
Indian mustard
Landfill
Polluted
groundwater in
Oil
spill
AD: Easy to establish, inexpensive, little air pollution and low energy use
DIS: Slow, only effective where plant roots can reach, and some plants can become toxic
Polluted
leachate
Decontaminated
water out
Soil
Soil
Groundwater
Groundwater
Rhizofiltration
Roots of plants such as
sunflowers with dangling
roots on ponds or in green-
houses can absorb pollutants
such as radioactive strontium -90 and cesium-137 and various organic chemicals.
Phytodegradation
Plants such as poplars
can absorb toxic organic
chemicals and break them down into less harmful compounds which they store or
release slowly into the air.
Phytoextraction
Roots of plants such as Indian
mustard and brake ferns can
absorb toxic metals such as
lead, arsenic, and others and
store them in their leaves.
Plants can then be recycled
or harvested and incinerated.
Phytostabilization
Plants such as willow trees and poplars can absorb chemicals and keep them from reaching groundwater or nearby surface water.

83. Can reduce material dumped into landfills
Trade-Offs
Phytoremediation
Advantages
Disadvantages
Easy to establish
Slow (can
take several
growing
seasons)
Inexpensive
Effective only
at depth plant
roots can
reach
Can reduce material dumped into landfills
Some toxic organic chemicals may evaporate from plant leaves
Figure 22.18
Trade-offs: advantages and disadvantages of using phytoremediation to remove or detoxify hazardous waste. QUESTION: Which single advantage and which single disadvantage do you think are the most important?
Produces little air pollution compared to incineration
Some plants
can become
toxic to
animals
Low energy use
Fig , p. 538

84. Conversion to Less Hazardous Substances
Incineration: heating many types of hazardous waste to high temperatures – up to 2000 °C – in an incinerator can break them down and convert them to less harmful or harmless chemicals.
Plasma Torch: passing electrical current through gas to generate an electric arc and very high temperatures can create plasma.
The plasma process can be carried out in a torch which can decompose liquid or solid hazardous organic material.

85. Mobile. Easy to move to different sites
Trade-Offs
Plasma Arc
Advantages
Disadvantages
Small
High cost
Produces CO2 and CO
Mobile. Easy to move to different sites
Can release particulates and chlorine gas
Figure 22.19
Trade-offs: advantages and disadvantages of using a plasma arc torch to detoxify hazardous wastes. QUESTION: Which single advantage and which single disadvantage do you think are the most important?
Can vaporize and release toxic metals and radioactive elements
Produces no
toxic ash
Fig , p. 538

86. Long-Term Storage: Hazardous Waste
Hazardous waste can be disposed of on or underneath the earth’s surface, but without proper design and care this can pollute the air and water.
Deep-well disposal: liquid hazardous wastes are pumped under pressure into dry porous rock far beneath aquifers.
Surface impoundments: excavated depressions such as ponds, pits, or lagoons into which liners are placed and liquid hazardous wastes are stored.

87. Deep Underground Wells
Trade-Offs
Deep Underground Wells
Advantages
Disadvantages
Safe method if
sites are chosen
carefully
Leaks or spills at
surface
Leaks from
corrosion of well
casing
Wastes can be
retrieved if
problems
develop
Existing fractures
or earthquakes
can allow wastes
to escape into
groundwater
Figure 22.20
Trade-offs: advantages and disadvantages of injecting liquid hazardous wastes into deep underground wells. QUESTION: Which single advantage and which single disadvantage do you think are the most important?
Easy to do
Encourages
waste production
Low cost
Fig , p. 539

88. Low construction costs
Trade-Offs
Surface Impoundments
Advantages
Disadvantages
Groundwater
contamination
from leaking liners
(or no lining)
Low construction costs
Low operating costs
Air pollution from
volatile organic
compounds
Can be built quickly
Overflow from
flooding
Figure 22.21
Trade-offs: advantages and disadvantages of storing liquid hazardous wastes in surface impoundments. QUESTION: Which single advantage and which single disadvantage do you think are the most important?
Wastes can be retrieved if necessary
Disruption and
leakage from
earthquakes
Can store wastes indefinitely with secure double liners
Promotes waste
production
Fig , p. 539

89. Long-Term Storage of Hazardous Waste
Long-Term Retrievable Storage: Some highly toxic materials cannot be detoxified or destroyed. Metal drums are used to stored them in areas that can be inspected and retrieved.
Secure Landfills: Sometimes hazardous waste are put into drums and buried in carefully designed and monitored sites.

90. Secure Hazardous Waste Landfill
In the U.S. there are only 21 commercial hazardous waste landfills.

91. Above Ground Hazardous Waste Disposal
transporter
Hazardous waste
Support
column
Inspector
Elevator shaft
Fig , p. 540

92. International Waste Management =Toxic colonialism
Developed countries sometimes send their waste to developing countries
Less expensive than following laws within the country
Controversial aspect of waste management
Environmental Justice issue

93. Integrated Waste Management Life Cycle Analysis

94. Life-Cycle Analysis (Cradle to Grave)
Important tool to make good decisions
Maps the materials/energy/pollution used and released throughout the lifetime of the product
Mining raw material
Manufacturing
Shipping
Use
Disposal
Impacts quantified
Environmental
Economic
Social
Limitations
A lot must be estimated

95. Integrated Waste Management
Holistic approach (“from all angles”)
W. McDonough’s book Cradle to Cradle
New approach to manufacturing
Develop products for disassembly
Recycled easily: with little material put in waste stream
Ex: Volkswagen
Cars designed to be easily taken apart for repair/recycling
Ex: carpeting

96. Integrated Waste Management
A method that seeks to develop as many options as possible, to reduce environmental harm and cost.
Reduction, recycling, composting, landfills, and incineration are some ways IWM is utilized.
Move from linear to circular material flow

97. Optimized Management of MSW Waste Stream:

98. Integrated Waste Management Goal to reduce waste

99. E-Waste is Particularly Problematic!

101. E-waste
Electronic waste including televisions, cell phones, computers, DVD players and other electronic devices
Hazardous waste!
Contains POPS: PVCs (polyvinylchloride), PBBs (polybrominated flame retardants),
Heavy metals: lead, mercury, cadmium, chromium, etc
If disposed in landfill, these hazardous chemicals are released in air, water and soil
E-waste must be collected so the hazardous materials can be removed and recycled: US recycles 20% Switzerland recycles 80%
US produces half world’s e-waste

102. How to dispose of E-Waste
What we are currently doing:
The Electronic Waste Recycling Act mandates and funds a program to ensure the collection and proper disposal of e- waste
Most of the US’s e-waste is shipped to developing countries (China, India, Pakistan) to be recycled.
Less than 20% of e-waste is actually collected for recycling
What we SHOULD be doing:
Manufacture products that do not contain toxic materials
Design products that have interchangeable parts so that broken parts can be repaired and then re-used ( )
Require companies to take back products at the end of the life cycle so that the company has to consider how manage the waste in their design process.
Charge consumers a recycling fee when they purchase the product and require the trade-in of the old product when a new one is purchased

103. Achieving a Low-Waste Society
In the U.S., citizens have kept large numbers of incinerators, landfills, and hazardous waste treatment plants from being built in their local areas. (NIMBY)
Environmental justice means that everyone is entitled to protection from environmental hazards without discrimination.
NIABY – Not In Anyone’s Backyard
NOPE – Not On Planet Earth

104. Global Outlook: International Action to Reduce Hazardous Waste
An international treaty, The Stockholm Convention 2001, calls for phasing out the use of harmful persistent organic pollutants (POPs), the dirty dozen.
POPs are insoluble in water and soluble in fat.
Nearly every person on earth has detectable levels of POPs in their blood.
The U.S has not ratified this treaty.
Dirty dozen: DDT, dioxin, PCB’s (polychlorinated biphenyls), HCB (hexachlorobenzene)

105. Solutions: mimic nature
Consume less
Redesign manufacturing processes and products to:
use less material and energy
create less pollution and waste
Develop products that are easy to repair, reuse, recycle, or compost “cradle to cradle”
Eliminate or reduce packaging material
Charge fee-per-bag for trash collection, but free recycle collection
Establish cradle to grave responsibility laws

106. Making the Transition to a Low-Waste Society: A New Vision
Everything is connected.
There is no “away” for the wastes we produce.
Dilution is not always the solution to pollution.
The best and cheapest way to deal with wastes are reduction and pollution prevention.