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== Environmental effects and toxicity == | == Environmental effects and toxicity == | ||
Under construction! | |||
===Lead=== | ===Lead=== | ||
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|Consumer electronics make up 40 % of the lead in <nowiki>[US]</nowiki> landfills.<ref> Widmer, R. et al., 2005 “Global perspectives on e-waste,” Environmental Impact Assessment Review, ‘’’2005’’’, (25). </ref> | |||
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In electronic waste, lead occurs mainly in two forms; in {{WP|CRT}} monitors and in lead solder. CRT monitors produce x-rays, as the result of accelerated electrons interacting with the glass of the display. Therefore, the glass of the display and the internal shielding is leaded. About 24% of the glass is lead oxide<ref>Nnorom, I. et al., 2007, “Overview of electronic waste (e-waste) management practices and legislations, and their poor applications in the developing countries,” Resources Conservation & Recycling, ‘’’2008’’’, (52), p. 4. </ref>. | In electronic waste, lead occurs mainly in two forms; in {{WP|CRT}} monitors and in lead solder. CRT monitors produce x-rays, as the result of accelerated electrons interacting with the glass of the display. Therefore, the glass of the display and the internal shielding is leaded. About 24% of the glass is lead oxide<ref>Nnorom, I. et al., 2007, “Overview of electronic waste (e-waste) management practices and legislations, and their poor applications in the developing countries,” Resources Conservation & Recycling, ‘’’2008’’’, (52), p. 4. </ref>. | ||
===Other heavy metals=== | ===Other heavy metals=== | ||
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|About 70 % of the heavy metals (mercury and cadmium) in US landfills come from electronic waste.<ref> Widmer, R. et al., 2005 “Global perspectives on e-waste,” Environmental Impact Assessment Review, ‘’’2005’’’, (25). </ref> | |||
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Certain metals are directly dangerous to humans, while others impact us in other ways. | Certain metals are directly dangerous to humans, while others impact us in other ways. | ||
Revision as of 00:54, 19 November 2008
Electronic waste, otherwise known as e-waste or WEEE (waste electrical and electronic equipment) is a term that encompasses all waste with electronic components. This definition can be refined as to include household appliances, computers and computer peripherals, monitors, TVs, audio and video equipment, telephony equipment, lighting, and battery operated toys.
Problem
Electronic waste is especially concerning for three reasons.
- It contains a number of toxic chemicals and heavy metals.
- The amount of electronic waste being produced around the world is rapidly accelerating. In the W, during the period of 2000-2020, the amount of electronic waste produced is projected to increase at 5% per year at best and 10% per year at worst[1]. In the U.S.A., between 1998 and 2007, the rate of electronic waste production growth was approximately 8% per year[2].
- A large portion of this waste is not disposed of properly. For example, the United States Environmental Protection Agency found that 82% of the TVs, cell phones and computer products disposed of in 2007 were landfilled[3].
Summed up in one sentence, electronic waste is a growing source of hazardous waste that that has not been addressed in many[4] W countries.
Definition
Every country that has legislation concerning electronic waste has their own definition, but European Directive 2002/96/EC[5] sums it up nicely.
- Large household appliances (eg. ovens and refrigerators)
- Small household appliances (eg. blenders)
- IT and telecommunications equipment (eg. computers)
- Consumer equipment (eg. digital audio players and TVs)
- Lighting equipment (eg. light bulbs and fixtures)
- Electrical and electronic tools (with the exception of large-scale stationary industrial tools)
- Toys, leisure and sports equipment
- Medical devices (with the exception of all implanted and infected products)
- Monitoring and control instruments
- Automatic dispensers (eg. vending machines)
The above categories include most items that include electronics, with the exception of biohazardous, military, and very large waste.
Components
Electronic waste contains a number of hazardous materials, that will leach out or be released if disposed of improperly. Below is a list of constituent parts of electronic waste.
Large quantities
- Plastics, in casings, fans and electrical insulation
- Epoxy resin hardened fiberglass, in printed circuit boards
- Lead is present in numerous types of items, especially in solder and CRT monitors
- Zinc, used to inhibit corrosion and in batteries
- Tin, present in solder
- Copper, in wiring and printed circuit boards
- Aluminum, in hard drives, heat sinks, and casings
- Steel, in cases and for structural reinforcement
Small quantities
- Cadmium, in batteries and pigments[6]
- Beryllium, half of the world’s yearly production is used in computer and communication equipment[7]
- Mercury, in batteries and fluorescent lightbulbs
- Thallium, used in optics[8] and in photoresistors[9]
- Antimony, in lead-free solder, as a flame retardant[10], and in batteries[11]
- Nickel, used in magnets, as an alloying metal in steel, and in batteries
- Chromium, as an alloying metal in steel, in the production of pigments and magnetic tape
- Additives such as W, W
- Carbon and ceramics, in resistors
- Precious metals, such as silver, gold and palladium in extremely low concentrations [12].
Among the substances, content varies wildly by electronic waste type. An account of this was written by Morf, L. et al.[13].
Production
The electronics industry is an industry where technological improvements are being made rapidly, leading to the obsolescence of certain products very quickly. As an example, the lifespan of the average desktop computer in the USA is 2 years[14].
Table 1: average electronic waste produced per person, by country
| Country | Production in kg/year | Sources |
|---|---|---|
| Canada | 5.515 | 2005[3][4] |
| United States | 4.479 | 2005[5][6] |
| United Kingdom | 17.384 [15] | 2008[7][8] |
Environmental effects and toxicity
Under construction!
Lead
| Consumer electronics make up 40 % of the lead in [US] landfills.[16] |
In electronic waste, lead occurs mainly in two forms; in W monitors and in lead solder. CRT monitors produce x-rays, as the result of accelerated electrons interacting with the glass of the display. Therefore, the glass of the display and the internal shielding is leaded. About 24% of the glass is lead oxide[17].
Other heavy metals
| About 70 % of the heavy metals (mercury and cadmium) in US landfills come from electronic waste.[18] |
Certain metals are directly dangerous to humans, while others impact us in other ways.
The metal thallium is highly toxic[19]
Other metals require special circumstances for them to be harmful, such as Metals such as copper and tin are only toxic in certain forms.
Brominated flame retardants
Brominated flame retardants such as W, W and W are present in many plastics [20].
Plastic additives
Other toxins
Bioaccumulating toxins such as W, W, W, and W are present in small quantities [21]. W is a process in which an organism accumulates an unwanted substance in its body faster than it can be expelled. This process works in concert with W
Recycling electronic waste
Main article: Metal reclamation and recycling of electronic waste
Electronic waste recycling is a complex task, especially when the safe disposal of numerous hazardous materials is required.
Legislation and practices
Main article: Electronic waste legislation and practices
Electronic waste legislation and practices vary by country, but there are a number of international initiatives, such as the 1989 Basel Conventions and the European Union’s Reduction of Hazardous Substances Directive.
The role you play
As an individual, you have a considerable ability to influence the electronics industry and how the electronic waste you produce is handled and disposed of.
Reduce
The ideal way to reduce the impact that electronic waste has on humanity, and the environment that sustains it, is by reducing our consumption of electronic devices. The electronics industry is a source of constant innovations and very short timespans between generations of technology. This creates a climate that encourages upgrading equipment before its useful lifespan is spent. Before purchasing electronics, as a gift or for yourself, consider what you will use it for and how long it is expected that it will be used for. Do the benefits outweigh the cost of the item and the impact it will eventually have?
Reuse
As explained above, many electronic products are unwanted and disposed of even while they still function. If you no longer want an electronic item, consider selling or donating it to someone who would. Online services such as Freecycle [9] and Craigslist [10] can help you find people would like these items.
Recycle
If the electronics you no longer want have no value to anyone else, make sure that you take it to a local electronics recycler.
References
- ↑ Hilty, L. et Al., 2004, “The future impact ICT on environmental sustainability. Refinement and quantification,” Institute for Prospective Technological Studies, Fourth Interim Report; 2004.
- ↑ http://www.epa.gov/epawaste/conserve/materials/ecycling/manage.htm Accessed Nov. 11, 2008.
- ↑ http://www.epa.gov/epawaste/conserve/materials/ecycling/manage.htm Accessed Nov. 11, 2008.
- ↑ See Electronic waste legislations and practices.
- ↑ http://eur-lex.europa.eu/LexUriServ/LexUriServ.do?uri=CELEX:32002L0096:EN:HTML Accessed November 15, 2008.
- ↑ http://minerals.usgs.gov/minerals/pubs/commodity/cadmium/cadmimcs06.pdf Accessed November 15, 2008
- ↑ http://minerals.usgs.gov/minerals/pubs/commodity/beryllium/mcs-2008-beryl.pdf Accessed November 15, 2008
- ↑ http://minerals.usgs.gov/minerals/pubs/commodity/thallium/mcs-2008-thall.pdf Accessed November 15, 2008
- ↑ http://www.speclab.com/elements/thallium.htm Accessed November 11, 2008.
- ↑ http://www.e1.greatlakes.com/fr/products/jsp/antimony_fr_prod.jsp Accessed November 15, 2008
- ↑ http://minerals.usgs.gov/minerals/pubs/commodity/antimony/mcs-2008-antim.pdf Accessed November 15, 2008
- ↑ Cui, J., Zhang, L., 2008, "Metallurgical recovery of metals from electronic waste: A review," Journal of Hazardous Materials, 158.
- ↑ Morf, L. et al., 2006, “Metals, non-metals and PCB in electrical and electronic waste – Actual levels in Switzerland,” Waste Management, ‘’’2007’’’, (27).
- ↑ Kang, H. et Al., 2004, "Electronic waste recycling: A review of U.S. infrastructure and technology options," Resources, Conservation and Recycling, 2005, (45), p.4 .
- ↑ Note: this number is very high compared to other countries. Other sources quote similar[1], or considerably higher [2] production.
- ↑ Widmer, R. et al., 2005 “Global perspectives on e-waste,” Environmental Impact Assessment Review, ‘’’2005’’’, (25).
- ↑ Nnorom, I. et al., 2007, “Overview of electronic waste (e-waste) management practices and legislations, and their poor applications in the developing countries,” Resources Conservation & Recycling, ‘’’2008’’’, (52), p. 4.
- ↑ Widmer, R. et al., 2005 “Global perspectives on e-waste,” Environmental Impact Assessment Review, ‘’’2005’’’, (25).
- ↑ http://msds.chem.ox.ac.uk/TH/thallium.html Accessed November 7, 2008
- ↑ Choi, K.-I. et al., 2008, "Leaching of brominated flame retardants from TV housing plastics...," Chemosphere (2008).
- ↑ Liu, H. et al., 2007, "E-waste recycling induced polybrominated diphenyl ethers, polychlorinated biphenyls, polychlorinated dibenzo-p-dioxins and dibenzo-furans pollution in the ambient environment," Elsevier, sciencedirect.com