From Wikipedia, the free encyclopedia
(Redirected from E-waste)

Defective and obsolete electronic equipment

Electronic waste (or e-waste) describes discarded electrical or electronic devices. It is also commonly known as waste electrical and electronic equipment (WEEE) or end-of-life (EOL) electronics. [1] Used electronics which are destined for refurbishment, reuse, resale, salvage recycling through material recovery, or disposal are also considered e-waste. Informal processing of e-waste in developing countries can lead to adverse human health effects and environmental pollution. The growing consumption of electronic goods due to the Digital Revolution and innovations in science and technology, such as bitcoin, has led to a global e-waste problem and hazard. The rapid exponential increase of e-waste is due to frequent new model releases and unnecessary purchases of electrical and electronic equipment (EEE), short innovation cycles and low recycling rates, and a drop in the average life span of computers. [2]

Electronic scrap components, such as CPUs, contain potentially harmful materials such as lead, cadmium, beryllium, or brominated flame retardants. Recycling and disposal of e-waste may involve significant risk to the health of workers and their communities. [3]

Definition

Hoarding (first), disassembling (second) and collecting (third) electronic waste in Bengaluru, India

E-waste or electronic waste is created when an electronic product is discarded after the end of its useful life. The rapid expansion of technology and the consumption driven society results in the creation of a very large amount of e-waste.

In the US, the United States Environmental Protection Agency (EPA) classifies e-waste into ten categories:

  1. Large household appliances, including cooling and freezing appliances
  2. Small household appliances
  3. IT equipment, including monitors
  4. Consumer electronics, including televisions
  5. Lamps and luminaires
  6. Toys
  7. Tools
  8. Medical devices
  9. Monitoring and control instruments
  10. Automatic dispensers

These include used electronics which are destined for reuse, resale, salvage, recycling, or disposal as well as re-usables (working and repairable electronics) and secondary raw materials (copper, steel, plastic, or similar). The term "waste" is reserved for residue or material which is dumped by the buyer rather than recycled, including residue from reuse and recycling operations, because loads of surplus electronics are frequently commingled (good, recyclable, and non-recyclable). Several public policy advocates apply the term "e-waste" and "e-scrap" broadly to apply to all surplus electronics. Cathode ray tubes (CRTs) are considered one of the hardest types to recycle. [4] [5]

Using a different set of categories, the Partnership on Measuring ICT for Development defines e-waste in six categories:

  1. Temperature exchange equipment (such as air conditioners, freezers)
  2. Screens, monitors (TVs, laptops)
  3. Lamps (LED lamps, for example)
  4. Large equipment (washing machines, electric stoves)
  5. Small equipment (microwaves, electric shavers)
  6. Small IT and telecommunication equipment (such as mobile phones, printers)

Products in each category vary in longevity profile, impact, and collection methods, among other differences. [6] Around 70% of toxic waste in landfills is electronic waste. [7]

CRTs have a relatively high concentration of lead and phosphors (not to be confused with phosphorus), both of which are necessary for the display. The United States Environmental Protection Agency (EPA) includes discarded CRT monitors in its category of "hazardous household waste" [8] but considers CRTs that have been set aside for testing to be commodities if they are not discarded, speculatively accumulated, or left unprotected from weather and other damage. These CRT devices are often confused between the DLP Rear Projection TV, both of which have a different recycling process due to the materials of which they are composed.

The EU and its member states operate a system via the European Waste Catalogue (EWC) – a European Council Directive, which is interpreted into "member state law". In the UK, this is in the form of the List of Wastes Directive. However, the list (and EWC) gives a broad definition (EWC Code 16 02 13*) of what is hazardous electronic waste, requiring "waste operators" to employ the Hazardous Waste Regulations (Annex 1A, Annex 1B) for refined definition. Constituent materials in the waste also require assessment via the combination of Annex II and Annex III, again allowing operators to further determine whether waste is hazardous. [9]

Debate continues over the distinction between " commodity" and "waste" electronics definitions. Some exporters are accused of deliberately leaving difficult-to-recycle, obsolete, or non-repairable equipment mixed in loads of working equipment (though this may also come through ignorance, or to avoid more costly treatment processes). Protectionists may broaden the definition of "waste" electronics in order to protect domestic markets from working secondary equipment.

The high value of the computer recycling subset of electronic waste (working and reusable laptops, desktops, and components like RAM) can help pay the cost of transportation for a larger number of worthless pieces than what can be achieved with display devices, which have less (or negative) scrap value. A 2011 report, "Ghana E-waste Country Assessment", [10] found that of 215,000 tons of electronics imported to Ghana, 30% was brand new and 70% was used. Of the used product, the study concluded that 15% was not reused and was scrapped or discarded. This contrasts with published but uncredited claims that 80% of the imports into Ghana were being burned in primitive conditions.

Quantity

A fragment of a discarded circuit board from a television remote

E-waste is considered the "fastest-growing waste stream in the world" [11] with 44.7 million tonnes generated in 2016- equivalent to 4500 Eiffel towers. [6] In 2018, an estimated 50 million tonnes of e-waste was reported, thus the name 'tsunami of e-waste' given by the UN. [11] Its value is at least $62.5 billion annually. [11]

Rapid changes in technology, changes in media (tapes, software, MP3), falling prices, and planned obsolescence have resulted in a fast-growing surplus of electronic waste around the globe. Technical solutions are available, but in most cases, a legal framework, a collection, logistics, and other services need to be implemented before a technical solution can be applied.

Display units (CRT, LCD, LED monitors), processors (CPU, GPU, or APU chips), memory (DRAM or SRAM), and audio components have different useful lives. Processors are most frequently out-dated (by software no longer being optimized) and are more likely to become "e-waste" while display units are most often replaced while working without repair attempts, due to changes in wealthy nation appetites for new display technology. This problem could potentially be solved with modular smartphones (such as the Phonebloks concept). These types of phones are more durable and have the technology to change certain parts of the phone making them more environmentally friendly. Being able to simply replace the part of the phone that is broken will reduce e-waste. [12] An estimated 50 million tons of e-waste are produced each year. [13] The USA discards 30 million computers each year and 100 million phones are disposed of in Europe each year. The Environmental Protection Agency estimates that only 15–20% of e-waste is recycled, the rest of these electronics go directly into landfills and incinerators. [14] [15]

Electronic waste at Agbogbloshie, Ghana

In 2006, the United Nations estimated the amount of worldwide electronic waste discarded each year to be 50 million metric tons. [16] According to a report by UNEP titled, "Recycling – from e-waste to Resources," the amount of e-waste being produced – including mobile phones and computers – could rise by as much as 500 percent over the next decade in some countries, such as India. [17] The United States is the world leader in producing electronic waste, tossing away about 3 million tons each year. [18] China already produces about 10.1 million tons (2020 estimate) domestically, second only to the United States. And, despite having banned e-waste imports, China remains a major e-waste dumping ground for developed countries. [18]

An iPhone with a damaged screen

Society today revolves around technology and by the constant need for the newest and most high-tech products we are contributing to a mass amount of e-waste. [19] Since the invention of the iPhone, cell phones have become the top source of e-waste products .[ citation needed] Electrical waste contains hazardous but also valuable and scarce materials. Up to 60 elements can be found in complex electronics. [20] Concentration of metals within the electronic waste is generally higher than a typical ore, such as copper, aluminium, iron, gold, silver, and palladium. [21] As of 2013, Apple has sold over 796 million iDevices (iPod, iPhone, iPad). Cell phone companies make cell phones that are not made to last so that the consumer will purchase new phones. Companies give these products such short lifespans because they know that the consumer will want a new product and will buy it if they make it. [22][ better source needed] In the United States, an estimated 70% of heavy metals in landfills comes from discarded electronics. [23] [24]

While there is agreement that the number of discarded electronic devices is increasing, there is considerable disagreement about the relative risk (compared to automobile scrap, for example), and strong disagreement whether curtailing trade in used electronics will improve conditions, or make them worse. According to an article in Motherboard, attempts to restrict the trade have driven reputable companies out of the supply chain, with unintended consequences. [25]

E-waste data 2016

In 2016, Asia was the territory that had the most extensive volume of e-waste (18.2 Mt), accompanied by Europe (12.3 metric tons), America (11.3 metric tons), Africa (2.2 metric tons), and Oceania (0.7 metric tons). The smallest in terms of total e-waste made, Oceania was the largest generator of e-waste per capita (17.3 kg/inhabitant), with hardly 6% of e-waste cited to be gathered and recycled. Europe is the second broadest generator of e-waste per citizen, with an average of 16.6 kg/inhabitant; however, Europe bears the loftiest assemblage figure (35%). America generates 11.6 kg/inhabitant and solicits only 17% of the e-waste caused in the provinces, which is commensurate with the assortment count in Asia (15%). However, Asia generates fewer e-waste per citizen (4,2 kg/inhabitant). Africa generates only 1.9 kg/inhabitant, and limited information is available on its collection percentage. The record furnishes regional breakdowns for Africa, Americas, Asia, Europe, and Oceania. The phenomenon somewhat illustrates the modest number figure linked to the overall volume of e-waste made that 41 countries have administrator e-waste data. For 16 other countries, e-waste volumes were collected from exploration and evaluated. The outcome of a considerable bulk of the e-waste (34.1 Metric tons) is unidentified. In countries where there is no national E-waste constitution in the stand, e-waste is possible interpreted as an alternative or general waste. This is land-filled or recycled, along with alternative metal or plastic scraps. There is the colossal compromise that the toxins are not drawn want of accordingly, or they are chosen want of by an informal sector and converted without well safeguarding the laborers while venting the contaminations in e-waste. Although the e-waste claim is on the rise, a flourishing quantity of countries are embracing e-waste regulation. National e-waste governance orders enclose 66% of the world population, a rise from 44% that was reached in 2014 [26]

E-waste data 2019

In 2019, an enormous volume of e-waste (53.6 Mt, with a 7.3 kg per capita average) was generated globally. This is projected to increase to 74 Mt by 2030. Asia still remains the largest contributor of a significant volume of electronic waste at 24.9 Mt, followed by the Americas (13.1 Mt), Europe (12 Mt), and Africa and Oceania at 2.9 Mt and 0.7 Mt, respectively. In per capita generation, Europe came first with 16.2 kg, and Oceania was second largest generator at 16.1 kg, and followed by the Americas. Africa is the least generator of e-waste per capita at 2.5 kg. Regarding the collection and recycling of these waste, the continent of Europe ranked first (42.5%), and Asia came second (11.7%). The Americas and Oceania are next (9.4% and 8.8% respectively), and Africa trails behind at 0.9%. Out of the 53.6 Metric tons generated e-waste globally, the formally documented collection and recycling was 9.3%, and the fate of 44.3% remains uncertain, with its whereabouts and impact to the environment varying across different regions of the world. However, the number of countries with national e-waste legislation, regulation or policy, have increased since 2014, from 61 to 78. A great proportion of undocumented commercial and domestic waste get mixed with other streams of waste like plastic and metal waste, implying that fractions which are easily recyclable might be recycled, under conditions considered to be inferior without depollution and recovery of all materials considered valuable. [27]

E-waste data 2021

In 2021, an estimated of 57.4 Mt of e-waste was generated globally. According to estimates in Europe, where the problem is best studied, 11 of 72 electronic items in an average household are no longer in use or broken. Annually per citizen, another 4 to 5 kg of unused electrical and electronic products are hoarded in Europe prior to being discarded. [28] In 2021, less than 20 percent of the e-waste is collected and recycled. [29]

E-waste data 2022

In 2022, an increase of 3.4% was estimated of the generated e-waste globally, hitting 59.4Mt, which made the total unrecycled e-waste on earth to 2022 is over 347 Mt. [30] The transboundary flow of e-waste has gained attention from the public due to a number of worrisome headlines, but global study on the volumes and trading routes has not yet been conducted. According to the Transboundary E-waste Flows Monitor, 5.1 Mt (or slightly under 10% of the 53.6 Mt of global e-waste) crossed international boundaries in 2019. This study divides transboundary movement of e-waste into regulated and uncontrolled movements and takes into account both the receiving and sending regions in order to better comprehend the implications of such movement. Of the 5.1 Mt, 1.8 Mt of the transboundary movement is sent under regulated conditions, while 3.3 Mt of the transboundary movement is delivered under uncontrolled conditions because used EEE or e-waste may encourage unlawful movements and provide a risk to the proper management of e-waste. [31]

E-waste legislative frameworks

The European Union (EU) has addressed the issue of electronic Waste by introducing two pieces of legislation. The first, the Waste Electrical and Electronic Equipment Directive (WEEE Directive) came into force in 2003. [1] The main aim of this directive was to regulate and motivate electronic waste recycling and re-use in member states at that moment. It was revised in 2008, coming into force in 2014. [2] Furthermore, the EU has also implemented the Directive on the restriction of the use of certain hazardous substances in electrical and electronic equipment from 2003. [3] This documents was additionally revised in 2012. [4] When it comes to Western Balkan countries, North Macedonia has adopted a Law on Batteries and Accumulators in 2010, followed by the Law on Management of electrical and electronic equipment in 2012. Serbia has regulated management of special waste stream, including electronic waste, by National waste management strategy (2010–2019). [5] Montenegro has adopted Concessionary Act concerning electronic waste with ambition to collect 4 kg of this waste annually per person until 2020. [6] Albanian legal framework is based on the draft act on waste from electrical and electronic equipment from 2011 which focuses on the design of electrical and electronic equipment. Contrary to this, Bosnia and Herzegovina is still missing a law regulating electronic waste.

As of October 2019, 78 countries globally have established either a policy, legislation or specific regulation to govern e-waste. [32] However, there is no clear indication that countries are following the regulations. Regions such as Asia and Africa are having policies that are not legally binding and rather only programmatic ones. [33] Hence, this poses as a challenge that e-waste management policies are yet not fully developed by globally by countries.

Solving the e-waste Problem (StEP) initiative

Solving the E-waste Problem is a membership organization that is part of United Nations University and was created to develop solutions to address issues associated with electronic waste. Some of the most eminent players in the fields of Production, Reuse and Recycling of Electrical and Electronic Equipment (EEE), government agencies and NGOs as well as UN Organisations count themselves among its members. StEP encourages the collaboration of all stakeholders connected with e-waste, emphasizing a holistic, scientific yet applicable approach to the problem.: [34]

Waste electrical and electronic equipment

The European Commission (EC) of the EU has classified waste electrical and electronic equipment (WEEE) as the waste generated from electrical devices and household appliances like refrigerators, televisions, and mobile phones and other devices. In 2005 the EU reported total waste of 9 million tonnes and in 2020 estimates waste of 12 million tonnes. This electronic waste with hazardous materials if not managed properly, may end up badly affecting our environment and causing fatal health issues. Disposing of these materials requires a lot of manpower and properly managed facilities. Not only the disposal, manufacturing of these types of materials require huge facilities and natural resources (aluminum, gold, copper and silicon, etc.), ending up damaging our environment and pollution. Considering the impact of WEEE materials make on our environment, EU legislation has made two legislations: 1. WEEE Directive; 2. RoHS Directive: Directive on usage and restrictions of hazardous materials in producing these Electrical and Electronic Equipment.

WEEE Directive: This Directive was implemented in February 2003, focusing on recycling electronic waste. This Directive offered many electronic waste collection schemes free of charge to the consumers (Directive 2002/96/EC [7]). The EC revised this Directive in December 2008, since this has become the fastest growing waste stream. In August 2012, the WEEE Directive was rolled out to handle the situation of controlling electronic waste and this was implemented on 14 February 2014 (Directive 2012/19/EU [8]). On 18 April 2017, the EC adopted a common principle of carrying out research and implementing a new regulation to monitor the amount of WEEE. It requires each member state to monitor and report their national market data. - Annex III to the WEEE Directive (Directive 2012/19/EU): Re-examination of the timelines for waste collection and setting up individual targets (Report [9]).

WEEE Legislation: - On 4 July 2012, the EC passed legislation on WEEE (Directive 2012/19/EU [10]). To know more about the progress in adopting the Directive 2012/19/EU (Progress [11]). - On 15 February 2014, the EC revised the Directive. To know more about the old Directive 2002/96/EC, see (Report [12]).

RoHS Directive: In 2003, the EC not only implemented legislation on waste collection but also on the alternative use of hazardous materials (Cadmium, mercury, flammable materials, polybrominated biphenyls, lead and polybrominated diphenyl ethers) used in the production of electronic and electric equipment (RoHS Directive 2002/95/EC [13]). This Directive was again revised in December 2008 and later again in January 2013 (RoHS recast Directive 2011/65/EU [14]). In 2017, the EC has made adjustment to the existing Directive considering the impact assessment [15] and adopted to a new legislative proposal [16] (RoHS 2 scope review [17]). On 21 November 2017, the European Parliament and Council has published this legislation amending the RoHS 2 Directive in their official journal [18].

European Commission legislation on batteries and accumulators (Batteries Directive)

Each year, the EU reports nearly 800 000 tons of batteries from automotive industry, industrial batteries of around 190 000 tons and consumer batteries around 160 000 tons entering the Europe region. These batteries are one of the most commonly used products in household appliances and other battery powered products in our day-to-day life. The important issue to look into is how this battery waste is collected and recycled properly, which has the consequences of resulting in hazardous materials release into the environment and water resources. Generally, many parts of these batteries and accumulators / capacitors can be recycled without releasing these hazardous materials release into our environment and contaminating our natural resources. The EC has rolled out a new Directive to control the waste from the batteries and accumulators known as 'Batteries Directive' [19] aiming to improve the collecting and recycling process of the battery waste and control the impact of battery waste on our environment. This Directive also supervises and administers the internal market by implementing required measures. This Directive restricts the production and marketing of batteries and accumulators which contains hazardous materials and are harmful to the environment, difficult to collect and recycle them. Batteries Directive [20] targets on the collection, recycling and other recycling activities of batteries and accumulators, also approving labels to the batteries which are environment neutral. On 10 December 2020, The EC has proposed a new regulation (Batteries Regulation [21]) on the batteries waste which aims to make sure that batteries entering the European market are recyclable, sustainable and non-hazardous (Press release [22]).

Legislation: In 2006, the EC has adopted the Batteries Directive and revised it in 2013. - On 6 September 2006, the European Parliament and European Council have launched Directives in waste from Batteries and accumulators (Directive 2006/66/EC [23]). - Overview of Batteries and accumulators Legislation [24]

Evaluation of Directive 2006/66/EC (Batteries Directive): Revising Directives could be based on the Evaluation [25] process, considering the fact of the increase in the usage of batteries with an increase in the multiple communication technologies, household appliances and other small battery-powered products. The increase in the demand of renewable energies and recycling of the products has also led to an initiative 'European Batteries Alliance (EBA)' which aims to supervise the complete value chain of production of more improved batteries and accumulators within Europe under this new policy act. Though the adoption of the Evaluation [26] process has been broadly accepted, few concerns rose particularly managing and monitoring the use of hazardous materials in the production of batteries, collection of the battery waste, recycling of the battery waste within the Directives. The evaluation process has definitely gave good results in the areas like controlling the environmental damage, increasing the awareness of recycling, reusable batteries and also improving the efficiency of the internal markets.

However, there are few limitations in the implementations of the Batteries Directive in the process of collecting batteries waste and recovering the usable materials from them. The evaluation process throws some light on the gap in this process of implementation and collaborate technical aspects in the process and new ways to use makes it more difficult to implement and this Directive maintains the balance with technological advancements. The EC's regulations and guidelines has made the evaluation process more impactful in a positive way. The participation of number of stakeholders in the evaluation process who are invited and asked to provide their views and ideas to improve the process of evaluation and information gathering. On 14 March 2018, stakeholders and members of the association participated to provide information about their findings, support and increase the process of Evaluation Roadmap [27].

European Union directives on e-waste

The European Union (EU) has addressed the e-waste issue by adopting several directives. In 2011 an amendment was made to a 2003 Directive 2002/95/EC regarding restriction of the use of hazardous materials in the planning and manufacturing process in the EEE. In the 2011 Directive, 2011/65/EU it was stated as the motivation for more specific restriction on the usage of hazardous materials in the planning and manufacturing process of electronic and electrical devices as there was a disparity of the EU Member State laws and the need arose to set forth rules to protect human health and for the environmentally sound recovery and disposal of WEEE. (2011/65/EU, (2)) The Directive lists several substances subject to restriction. The Directive states restricted substances for maximum concentration values tolerated by weight in homogeneous materials are the following: lead (0.1%); mercury (0.1%), cadmium (0.1%), hexavalent chromium (0.1%), polybrominated biphenyls (PBB) (0.1%) and polybrominated diphenyl ethers (PBDE) (0.1 %). If technologically feasible and substitution is available, the usage of substitution is required.

There are, however, exemptions in the case in which substitution is not possible from the scientific and technical point of view. The allowance and duration of the substitutions should take into account the availability of the substitute and the socioeconomic impact of the substitute. (2011/65/EU, (18))

EU Directive 2012/19/EU regulates WEEE and lays down measures to safeguard the ecosystem and human health by inhibiting or shortening the impact of the generation and management of waste of WEEE. (2012/19/EU, (1)) The Directive takes a specific approach to the product design of EEE. It states in Article 4 that Member States are under the constraint to expedite the kind of model and manufacturing process as well as cooperation between producers and recyclers as to facilitate re-use, dismantling and recovery of WEEE, its components, and materials. (2012/19/EU, (4)) The Member States should create measures to make sure the producers of EEE use eco-design, meaning that the type of manufacturing process is used that would not restrict later re-use of WEEE. The Directive also gives Member States the obligation to ensure a separate collection and transportation of different WEEE. Article 8 lays out the requirements of the proper treatment of WEEE. The base minimum of proper treatment that is required for every WEEE is the removal of all liquids. The recovery targets set are seen in the following figures.

Under Annex I of Directive 2012/19/EU, the categories of EEE covered are as follows:

  1. Large household appliances
  2. Small household appliances
  3. IT and telecommunications equipment
  4. Consumer equipment and photovoltaic panels
  5. Lighting equipment
  6. Electrical and electronic tools (with the exception of large-scale stationary industrial tools)
  7. Toys, leisure and sports equipment
  8. Medical devices (with the exception of all implanted and infected products)
  9. Monitoring and control instruments
  10. Autonomic dispensers

Minimum recovery targets referred in Directive 2012/19/EU starting from 15 August 2018:

WEEE falling within category 1 or 10 of Annex I

- 85% shall be recovered, and 80% shall be prepared for re-use and recycled;

WEEE falling within category 3 or 4 of Annex I

- 80% shall be recovered, and 70% shall be prepared for re-use and recycled;

WEEE falling within category 2, 5, 6, 7, 8 or 9 of Annex I

-75% shall be recovered, and 55% shall be prepared for re-use and recycled;

For gas and discharged lamps, 80% shall be recycled.

In 2021, the European Commission proposed the implementation of a standardization – for iterations of USB-C – of phone charger products after commissioning two impact assessment studies and a technology analysis study. Regulations like this may reduce electronic waste by small but significant amounts as well as, in this case, increase device- interoperability, convergence and convenience for consumers while decreasing resource-needs and redundancy. [35] [36] [37][ additional citation(s) needed] The regulations were passed in June 2022, mandating that all phones sold in the EU to have USB-C charging ports by late 2024. [38]

International agreements

A report by the United Nations Environment Management Group [39] lists key processes and agreements made by various organizations globally in an effort to manage and control e-waste. Details about the policies could be retrieved in the links below.

Global trade issues

Electronic waste is often exported to developing countries.
4.5-volt, D, C, AA, AAA, AAAA, A23, 9-volt, CR2032, and LR44 cells are all recyclable in most countries.
The E-waste centre of Agbogbloshie, Ghana, where electronic waste is burnt and disassembled with no safety or environmental considerations

One theory is that increased regulation of electronic wastes and concern over the environmental harm in nature economies creates an economic disincentive to remove residues prior to export. Critics of trade in used electronics maintain that it is still too easy for brokers calling themselves recyclers to export unscreened electronic waste to developing countries, such as China, [47] India and parts of Africa, thus avoiding the expense of removing items like bad cathode ray tubes (the processing of which is expensive and difficult). The developing countries have become toxic dump yards of e-waste. Developing countries receiving foreign e-waste often go further to repair and recycle forsaken equipment. [48] Yet still 90% of e-waste ended up in landfills in developing countries in 2003. [48] Proponents of international trade point to the success of fair trade programs in other industries, where cooperation has led to creation of sustainable jobs and can bring affordable technology in countries where repair and reuse rates are higher.

Defenders of the trade[ who?] in used electronics say that extraction of metals from virgin mining has been shifted to developing countries. Recycling of copper, silver, gold, and other materials from discarded electronic devices is considered better for the environment than mining. They also state that repair and reuse of computers and televisions has become a "lost art" in wealthier nations and that refurbishing has traditionally been a path to development.

South Korea, Taiwan, and southern China all excelled in finding "retained value" in used goods, and in some cases have set up billion-dollar industries in refurbishing used ink cartridges, single-use cameras, and working CRTs. Refurbishing has traditionally been a threat to established manufacturing, and simple protectionism explains some criticism of the trade. Works like " The Waste Makers" by Vance Packard explain some of the criticism of exports of working product, for example, the ban on import of tested working Pentium 4 laptops to China, or the bans on export of used surplus working electronics by Japan.

Opponents of surplus electronics exports argue that lower environmental and labor standards, cheap labor, and the relatively high value of recovered raw materials lead to a transfer of pollution-generating activities, such as smelting of copper wire. Electronic waste is often sent to various African and Asian countries such as China, Malaysia, India, and Kenya for processing, sometimes illegally. Many surplus laptops are routed to developing nations as "dumping grounds for e-waste". [49]

Because the United States has not ratified the Basel Convention or its Ban Amendment, and has few domestic federal laws forbidding the export of toxic waste, the Basel Action Network estimates that about 80% of the electronic waste directed to recycling in the U.S. does not get recycled there at all, but is put on container ships and sent to countries such as China. [50] [51] [52] [53] This figure is disputed as an exaggeration by the EPA, the Institute of Scrap Recycling Industries, and the World Reuse, Repair and Recycling Association.

Independent research by Arizona State University showed that 87–88% of imported used computers were priced above the constituent materials they contained, and that "the official trade in end-of-life computers is thus driven by reuse as opposed to recycling". [54]

Trade

Sacks of mobile phones in Agbogbloshie, Ghana

Proponents of the trade say growth of internet access is a stronger correlation to trade than poverty. Haiti is poor and closer to the port of New York than southeast Asia, but far more electronic waste is exported from New York to Asia than to Haiti. Thousands of men, women, and children are employed in reuse, refurbishing, repair, and re-manufacturing, unsustainable industries in decline in developed countries. Denying developing nations access to used electronics may deny them sustainable employment, affordable products, and internet access, or force them to deal with even less scrupulous suppliers. In a series of seven articles for The Atlantic, Shanghai-based reporter Adam Minter describes many of these computer repair and scrap separation activities as objectively sustainable. [55]

Opponents of the trade argue that developing countries utilize methods that are more harmful and more wasteful. An expedient and prevalent method is simply to toss equipment onto an open fire, in order to melt plastics and to burn away non-valuable metals. This releases carcinogens and neurotoxins into the air, contributing to an acrid, lingering smog. These noxious fumes include dioxins and furans. Bonfire refuse can be disposed of quickly into drainage ditches or waterways feeding the ocean or local water supplies. [53]

In June 2008, a container of electronic waste, destined from the Port of Oakland in the U.S. to Sanshui District in mainland China, was intercepted in Hong Kong by Greenpeace. [56] Concern over exports of electronic waste were raised in press reports in India, [57] [58] Ghana, [59] [60] [61] Côte d'Ivoire, [62] and Nigeria. [63]

The research that was undertaken by the Countering WEEE Illegal Trade (CWIT) project, funded by the European Commission, found that in Europe only 35% (3.3 million tons) of all the e-waste discarded in 2012 ended up in the officially reported amounts of collection and recycling systems. The other 65% (6.15 million tons) was either:

  • Exported (1.5 million tons),
  • Recycled under non-compliant conditions in Europe (3.15 million tons),
  • Scavenged for valuable parts (750,000 tons), or
  • Simply thrown in waste bins (750,000 tons). [64]

Guiyu

Guiyu in the Guangdong region of China is a massive electronic waste processing community. [50] [65] It is often referred to as the "e-waste capital of the world." Traditionally, Guiyu was an agricultural community; however, in the mid-1990s it transformed into an e-waste recycling center involving over 75% of the local households and an additional 100,000 migrant workers. [66] Thousands of individual workshops employ laborers to snip cables, pry chips from circuit boards, grind plastic computer cases into particles, and dip circuit boards in acid baths to dissolve the precious metals. Others work to strip insulation from all wiring in an attempt to salvage tiny amounts of copper wire. [67] Uncontrolled burning, disassembly, and disposal has led to a number of environmental problems such as groundwater contamination, atmospheric pollution, and water pollution either by immediate discharge or from surface runoff (especially near coastal areas), as well as health problems including occupational safety and health effects among those directly and indirectly involved, due to the methods of processing the waste.

Six of the many villages in Guiyu specialize in circuit-board disassembly, seven in plastics and metals reprocessing, and two in wire and cable disassembly. Greenpeace, an environmental group, sampled dust, soil, river sediment, and groundwater in Guiyu. They found very high levels of toxic heavy metals and organic contaminants in both places. [68] Lai Yun, a campaigner for the group found "over 10 poisonous metals, such as lead, mercury, and cadmium."

Guiyu is only one example of digital dumps but similar places can be found across the world in Nigeria, Ghana, and India. [69]

Other informal e-waste recycling sites

A pile of discarded TVs and computer monitors

Guiyu is likely one of the oldest and largest informal e-waste recycling sites in the world; however, there are many sites worldwide, including India, Ghana ( Agbogbloshie), Nigeria, and the Philippines. There are a handful of studies that describe exposure levels in e-waste workers, the community, and the environment. For example, locals and migrant workers in Delhi, a northern union territory of India, scavenge discarded computer equipment and extract base metals using toxic, unsafe methods. [70] Bangalore, located in southern India, is often referred as the "Silicon Valley of India" and has a growing informal e-waste recycling sector. [71] [72] A study found that e-waste workers in the slum community had higher levels of V, Cr, Mn, Mo, Sn, Tl, and Pb than workers at an e-waste recycling facility. [71]

Cryptocurrency e-waste

Bitcoin mining has also contributed to higher amounts in electronic waste. Bitcoin and other cryptocurrencies can be used for payment or speculation. Per de Vries & Stoll in the journal Resources, Conservation and Recycling the average bitcoin transaction yields 272 grams of electronic waste and generated approximately 112.5 million grams of waste in 2020 alone. [73] Other estimates indicate that the bitcoin network discards as much "small IT and telecommunication equipment waste produced by a country like the Netherlands," totalling to 30.7 metric kilotons every year. [73] Furthermore, the rate at which Bitcoin disposes of its waste exceeds that of major financial organizations such as VISA, which produces 40 grams of waste for every 100,000 transactions. [74]

A major point of concern is the rapid turnover of technology in the bitcoin industry which results in such high levels of e-waste. This can be attributed to the proof-of-work principle bitcoin employs where miners receive currency as a reward for being the first to decode the hashes that encode its blockchain. [75] As such, miners are encouraged to compete with one another to decode the hash first. [75] However, computing these hashes requires massive computing power which, in effect, drives miners to obtain rigs with the highest processing power possible. In an attempt to achieve this, miners increase the processing power in their rigs by purchasing more advanced computer chips. [75]

According to Koomey's Law, efficiency in computer chips doubles every 1.5 years, [76] meaning that miners are incentivized to purchase new chips to keep up with competing miners even though the older chips are still functional. In some cases, miners even discard their chips earlier than this timeframe for the sake of profitability. [73] However, this leads to a significant build up in waste, as outdated application-specific integrated circuits (ASIC computer chips) cannot be reused or repurposed. [75] Most computer chips used to mine bitcoin are ASIC chips, whose sole function is to mine bitcoin, rendering them useless for other cryptocurrencies or operation in any other piece of technology. [75] Therefore, outdated ASIC chips can only be disposed of since they are unable to be repurposed.

The bitcoin e-waste problem is further exacerbated by the fact that many countries and corporations lack recycling programs for ASIC chips. [73] Developing a recycling infrastructure for bitcoin mining may prove to be beneficial, though, as the aluminum heat sinks and metal casings in ASIC chips can be recycled into new technology. [73] Much of this responsibility falls onto Bitmain, the leading manufacturer of bitcoin, which currently lacks the infrastructure to recycle waste from bitcoin mining. [73] Without such programs, much of bitcoin waste ends up in landfill along with 83.6% of the global total of e-waste. [73]

Many argue for relinquishing the proof-of-work model altogether in favour of the proof-of-stake one. This model selects one miner to validate the transactions in the blockchain, rather than have all miners competing for it. [77] With no competition, the processing speed of miners' rigs would not matter. [73] Any device could be used for validating the blockchain, so there would be no incentive to use single-use ASIC chips or continually purchase new and dispose of old ones. [73] [77]

Environmental impact

Old keyboards and a mouse

The processes of dismantling and disposing of electronic waste in developing countries led to a number of environmental impacts as illustrated in the graphic. Liquid and atmospheric releases end up in bodies of water, groundwater, soil, and air and therefore in land and sea animals – both domesticated and wild, in crops eaten by both animals and humans, and in drinking water. [78]

One study of environmental effects in Guiyu, China found the following: [13]

  • Airborne dioxins – one type found at 100 times levels previously measured
  • Levels of carcinogens in duck ponds and rice paddies exceeded international standards for agricultural areas and cadmium, copper, nickel, and lead levels in rice paddies were above international standards
  • Heavy metals found in road dust – lead over 300 times that of a control village's road dust and copper over 100 times

The Agbogbloshie area of Ghana, where about 40,000 people live, provides an example of how e-waste contamination can pervade the daily lives of nearly all residents. Into this area—one of the largest informal e-waste dumping and processing sites in Africa—about 215,000 tons of secondhand consumer electronics, primarily from Western Europe, are imported annually. Because this region has considerable overlap among industrial, commercial, and residential zones, Pure Earth (formerly Blacksmith Institute) has ranked Agbogbloshie as one of the world's 10 worst toxic threats (Blacksmith Institute 2013). [79]

A separate study at the Agbogbloshie e-waste dump, Ghana found a presence of lead levels as high as 18,125 ppm in the soil. [80] US EPA standard for lead in soil in play areas is 400 ppm and 1200 ppm for non-play areas. [81] Scrap workers at the Agbogbloshie e-waste dump regularly burn electronic components and auto harness wires for copper recovery, [82] releasing toxic chemicals like lead, dioxins and furans [83] into the environment.

Researchers such as Brett Robinson, a professor of soil and physical sciences at Lincoln University in New Zealand, warn that wind patterns in Southeast China disperse toxic particles released by open-air burning across the Pearl River Delta Region, home to 45 million people. In this way, toxic chemicals from e-waste enter the "soil-crop-food pathway," one of the most significant routes for heavy metals' exposure to humans. These chemicals are not biodegradable— they persist in the environment for long periods of time, increasing exposure risk. [84]

In the agricultural district of Chachoengsao, in the east of Bangkok, local villagers had lost their main water source as a result of e-waste dumping. The cassava fields were transformed in late 2017, when a nearby Chinese-run factory started bringing in foreign e-waste items such as crushed computers, circuit boards and cables for recycling to mine the electronics for valuable metal components like copper, silver and gold. But the items also contain lead, cadmium and mercury, which are highly toxic if mishandled during processing. Apart from feeling faint from noxious fumes emitted during processing, a local claimed the factory has also contaminated her water. "When it was raining, the water went through the pile of waste and passed our house and went into the soil and water system. Water tests conducted in the province by environmental group Earth and the local government both found toxic levels of iron, manganese, lead, nickel and in some cases arsenic and cadmium. The communities observed when they used water from the shallow well, there was some development of skin disease or there are foul smells", founder of Earth, Penchom Saetang, said: "This is proof, that it is true, as the communities suspected, there are problems happening to their water sources." [85]

The environmental impact of the processing of different electronic waste components [86]
E-waste Component Process Used Potential Environmental Hazard
Cathode ray tubes (used in TVs, computer monitors, ATM, video cameras, and more) Breaking and removal of yoke, then dumping Lead, barium and other heavy metals leaching into the ground water and release of toxic phosphor
Printed circuit board (image behind table – a thin plate on which chips and other electronic components are placed) De-soldering and removal of computer chips; open burning and acid baths to remove metals after chips are removed. Air emissions and discharge into rivers of glass dust, tin, lead, brominated dioxin, beryllium cadmium, and mercury
Chips and other gold plated components Chemical stripping using nitric and hydrochloric acid and burning of chips PAHs, heavy metals, brominated flame retardants discharged directly into rivers acidifying fish and flora. Tin and lead contamination of surface and groundwater. Air emissions of brominated dioxins, heavy metals, and PAHs
Plastics from printers, keyboards, monitors, etc. Shredding and low temp melting to be reused Emissions of brominated dioxins, heavy metals, and hydrocarbons
Computer wires Open burning and stripping to remove copper PAHs released into air, water, and soil.

Depending on the age and type of the discarded item, the chemical composition of e-waste may vary. Most e-waste are composed of a mixture of metals like Cu, Al and Fe. They might be attached to, covered with or even mixed with various types of plastics and ceramics. E-waste has a horrible effect on the environment and it is important to dispose it with an R2 certifies recycling facility. [87]

Research

In May 2020, a scientific study was conducted in China that investigated the occurrence and distribution of traditional and novel classes of contaminants, including chlorinated, brominated, and mixed halogenated dibenzo-p-dioxins/dibenzofurans (PCDD/Fs, PBDD/Fs, PXDD/Fs), polybrominated diphenyl ethers (PBDEs), polychlorinated biphenyls (PCBs) and polyhalogenated carbazoles (PHCZs) in soil from an e-waste disposal site in Hangzhou (which has been in operation since 2009 and has a treatment capacity of 19.6 Wt/a). While the study area has only one formal emission source, the broader industrial zone has a number of metal recovery and reprocessing plants as well as heavy traffic on adjacent motorways where normal and heavy-duty devices are used. The maximum concentrations of the target halogenated organic compounds HOCs were 0.1–1.5 km away from the main source and overall detected levels of HOCs were generally lower than those reported globally. The study proved what researchers have warned, i. e. on highways with heavy traffic, especially those serving diesel powered vehicles, exhaust emissions are larger sources of dioxins than stationary sources. When assessing the environmental and health impacts of chemical compounds, especially PBDD/Fs and PXDD/Fs, the compositional complexity of soil and long period weather conditions like rain and downwind have to be taken into account. Further investigations are necessary to build up a common understanding and methods for assessing e-waste impacts. [88]

Information security

Discarded data processing equipment may still contain readable data that may be considered sensitive to the previous users of the device. A recycling plan for such equipment can support information security by ensuring proper steps are followed to erase the sensitive information. This may include such steps as re-formatting of storage media and overwriting with random data to make data unrecoverable, or even physical destruction of media by shredding and incineration to ensure all data is obliterated. For example, on many operating systems deleting a file may still leave the physical data file intact on the media, allowing data retrieval by routine methods.

Recycling

Computer monitors are typically packed into low stacks on wooden pallets for recycling and then shrink-wrapped.

Recycling is an essential element of e-waste management. Properly carried out, it should greatly reduce the leakage of toxic materials into the environment and militate against the exhaustion of natural resources. However, it does need to be encouraged by local authorities and through community education. Less than 20% of e-waste is formally recycled, with 80% either ending up in landfill or being informally recycled – much of it by hand in developing countries, exposing workers to hazardous and carcinogenic substances such as mercury, lead and cadmium. [89]

There are generally three methods of extracting precious metals from electronic waste, namely hydrometallurgical, pyrometallurgical, and hydro-pyrometallurgical methods. Each of these methods has its own advantages and disadvantages together with the production of toxic waste. [21]

One of the major challenges is recycling the printed circuit boards from electronic waste. The circuit boards contain such precious metals as gold, silver, platinum, etc. and such base metals as copper, iron, aluminum, etc. One way e-waste is processed is by melting circuit boards, burning cable sheathing to recover copper wire and open- pit acid leaching for separating metals of value. [13] Conventional method employed is mechanical shredding and separation but the recycling efficiency is low. Alternative methods such as cryogenic decomposition have been studied for printed circuit board recycling, [90] and some other methods are still under investigation. Properly disposing of or reusing electronics can help prevent health problems, reduce greenhouse-gas emissions, and create jobs. [91]

Consumer awareness efforts

A campaign to promote E-waste recycling in Ghana

The U.S. Environmental Protection Agency encourages electronic recyclers to become certified by demonstrating to an accredited, independent third party auditor that they meet specific standards to safely recycle and manage electronics. This should work so as to ensure the highest environmental standards are being maintained. Two certifications for electronic recyclers currently exist and are endorsed by the EPA. Customers are encouraged to choose certified electronics recyclers. Responsible electronics recycling reduces environmental and human health impacts, increases the use of reusable and refurbished equipment and reduces energy use while conserving limited resources. The two EPA-endorsed certification programs are Responsible Recyclers Practices (R2) and E-Stewards. Certified companies ensure they are meeting strict environmental standards which maximize reuse and recycling, minimize exposure to human health or the environment, ensure safe management of materials and require destruction of all data used on electronics. [92] Certified electronics recyclers have demonstrated through audits and other means that they continually meet specific high environmental standards and safely manage used electronics. Once certified, the recycler is held to the particular standard by continual oversight by the independent accredited certifying body. A certification board accredits and oversees certifying bodies to ensure that they meet specific responsibilities and are competent to audit and provide certification. [93]

Some U.S. retailers offer opportunities for consumer recycling of discarded electronic devices. [94] [95] In the US, the Consumer Electronics Association (CEA) urges consumers to dispose properly of end-of-life electronics through its recycling locator. This list only includes manufacturer and retailer programs that use the strictest standards and third-party certified recycling locations, to provide consumers assurance that their products will be recycled safely and responsibly. CEA research has found that 58 percent of consumers know where to take their end-of-life electronics, and the electronics industry would very much like to see that level of awareness increase. Consumer electronics manufacturers and retailers sponsor or operate more than 5,000 recycling locations nationwide and have vowed to recycle one billion pounds annually by 2016, [96] a sharp increase from 300 million pounds industry recycled in 2010.

The Sustainable Materials Management (SMM) Electronic Challenge was created by the United States Environmental Protection Agency (EPA) in 2012. [97] Participants of the Challenge are manufacturers of electronics and electronic retailers. These companies collect end-of-life (EOL) electronics at various locations and send them to a certified, third-party recycler. Program participants are then able publicly promote and report 100% responsible recycling for their companies. [98] The Electronics TakeBack Coalition (ETBC) [99] is a campaign aimed at protecting human health and limiting environmental effects where electronics are being produced, used, and discarded. The ETBC aims to place responsibility for disposal of technology products on electronic manufacturers and brand owners, primarily through community promotions and legal enforcement initiatives. It provides recommendations for consumer recycling and a list of recyclers judged environmentally responsible. [100] While there have been major benefits from the rise in recycling and waste collection created by producers and consumers, such as valuable materials being recovered and kept away from landfill and incineration, there are still many problems present with the EPR system including "how to ensure proper enforcement of recycling standards, what to do about waste with positive net value, and the role of competition," (Kunz et al.). Many stakeholders agreed there needs to be a higher standard of accountability and efficiency to improve the systems of recycling everywhere, as well as the growing amount of waste being an opportunity more so than downfall since it gives us more chances to create an efficient system. To make recycling competition more cost-effective, the producers agreed that there needs to be a higher drive for competition because it allows them to have a wider range of producer responsibility organizations to choose from for e-waste recycling. [101]

The Certified Electronics Recycler program [102] for electronic recyclers is a comprehensive, integrated management system standard that incorporates key operational and continual improvement elements for quality, environmental and health and safety performance. The grassroots Silicon Valley Toxics Coalition promotes human health and addresses environmental justice problems resulting from toxins in technologies. The World Reuse, Repair, and Recycling Association (wr3a.org) is an organization dedicated to improving the quality of exported electronics, encouraging better recycling standards in importing countries, and improving practices through "Fair Trade" principles. Take Back My TV [103] is a project of The Electronics TakeBack Coalition and grades television manufacturers to find out which are responsible, in the coalition's view, and which are not.

There have also been efforts to raise awareness of the potentially hazardous conditions of the dismantling of e-waste in American prisons. The Silicon Valley Toxics Coalition, prisoner-rights activists, and environmental groups released a Toxic Sweatshops report that details how prison labor is being used to handle e-waste, resulting in health consequences among the workers. [104] These groups allege that, since prisons do not have adequate safety standards, inmates are dismantling the products under unhealthy and unsafe conditions. [105]

Processing techniques

Recycling the lead from batteries

In many developed countries, electronic waste processing usually first involves dismantling the equipment into various parts (metal frames, power supplies, circuit boards, plastics), often by hand, but increasingly by automated shredding equipment. A typical example is the NADIN electronic waste processing plant in Novi Iskar, Bulgaria—the largest facility of its kind in Eastern Europe. [106] [107] The advantages of this process are the human worker's ability to recognize and save working and repairable parts, including chips, transistors, RAM, etc. The disadvantage is that the labor is cheapest in countries with the lowest health and safety standards.

In an alternative bulk system, [108] a hopper conveys material for shredding into an unsophisticated mechanical separator, with screening and granulating machines to separate constituent metal and plastic fractions, which are sold to smelters or plastics recyclers. Such recycling machinery is enclosed and employs a dust collection system. Some of the emissions are caught by scrubbers and screens. Magnets, eddy currents, and Trommel screens are employed to separate glass, plastic, and ferrous and nonferrous metals, which can then be further separated at a smelter.

Copper, gold, palladium, silver and tin are valuable metals sold to smelters for recycling. Hazardous smoke and gases are captured, contained and treated to mitigate environmental threat. These methods allow for safe reclamation of all valuable computer construction materials. Hewlett-Packard product recycling solutions manager Renee St. Denis describes its process as: "We move them through giant shredders about 30 feet tall and it shreds everything into pieces about the size of a quarter. Once your disk drive is shredded into pieces about this big, it's hard to get the data off". [109] An ideal electronic waste recycling plant combines dismantling for component recovery with increased cost-effective processing of bulk electronic waste. Reuse is an alternative option to recycling because it extends the lifespan of a device. Devices still need eventual recycling, but by allowing others to purchase used electronics, recycling can be postponed and value gained from device use.

In early November 2021, the U.S. state of Georgia announced a joint effort with Igneo Technologies to build an $85 million large electronics recycling plant in the Port of Savannah. The project will focus on lower-value, plastics-heavy devices in the waste stream using multiple shredders and furnaces using pyrolysis technology. [110]

Benefits of recycling

Recycling raw materials from end-of-life electronics is the most effective solution to the growing e-waste problem. [111] Most electronic devices contain a variety of materials, including metals that can be recovered for future uses. By dismantling and providing reuse possibilities, intact natural resources are conserved and air and water pollution caused by hazardous disposal is avoided. Additionally, recycling reduces the amount of greenhouse gas emissions caused by the manufacturing of new products. [112] Another benefit of recycling e-waste is that many of the materials can be recycled and re-used again. Materials that can be recycled include "ferrous (iron-based) and non-ferrous metals, glass, and various types of plastic." "Non-ferrous metals, mainly aluminum and copper can all be re-smelted and re-manufactured. Ferrous metals such as steel and iron also can be re-used." [113] Due to the recent surge in popularity in 3D printing, certain 3D printers have been designed (FDM variety) to produce waste that can be easily recycled which decreases the amount of harmful pollutants in the atmosphere. [114] The excess plastic from these printers that comes out as a byproduct can also be reused to create new 3D printed creations. [115]

Benefits of recycling are extended when responsible recycling methods are used. In the U.S., responsible recycling aims to minimize the dangers to human health and the environment that disposed and dismantled electronics can create. Responsible recycling ensures best management practices of the electronics being recycled, worker health and safety, and consideration for the environment locally and abroad. [116] In Europe, metals that are recycled are returned to companies of origin at a reduced cost. [117] Through a committed recycling system, manufacturers in Japan have been pushed to make their products more sustainable. Since many companies were responsible for the recycling of their own products, this imposed responsibility on manufacturers requiring many to redesign their infrastructure. As a result, manufacturers in Japan have the added option to sell the recycled metals. [118]

Improper management of e-waste is resulting in a significant loss of scarce and valuable raw materials, such as gold, platinum, cobalt and rare earth elements. As much as 7% of the world's gold may currently be contained in e-waste, with 100 times more gold in a tonne of e-waste than in a tonne of gold ore. [89]

Repair as waste reduction method

There are several ways to curb the environmental hazards arising from the recycling of electronic waste. One of the factors which exacerbate the e-waste problem is the diminishing lifetime of many electrical and electronic goods. There are two drivers (in particular) for this trend. On the one hand, consumer demand for low cost products militates against product quality and results in short product lifetimes. [119] On the other, manufacturers in some sectors encourage a regular upgrade cycle, and may even enforce it though restricted availability of spare parts, service manuals and software updates, or through planned obsolescence.

Consumer dissatisfaction with this state of affairs has led to a growing repair movement. Often, this is at a community level such as through repair cafės or the "restart parties" promoted by the Restart Project. [120]

The Right to Repair is spearheaded in the US by farmers dissatisfied with non-availability of service information, specialised tools and spare parts for their high-tech farm machinery. But the movement extends far beyond farm machinery with, for example, the restricted repair options offered by Apple coming in for criticism. Manufacturers often counter with safety concerns resulting from unauthorised repairs and modifications. [121]

An easy method of reducing electronic waste footprint is to sell or donate electronic gadgets, rather than dispose of them. Improperly disposed e-waste is becoming more and more hazardous, especially as the sheer volume of e-waste increases. For this reason, large brands like Apple, Samsung, and others have started giving options to customers to recycle old electronics. Recycling allows the expensive electronic parts inside to be reused. This may save significant energy and reduce the need for mining of additional raw resources, or manufacture of new components. Electronic recycling programs may be found locally in many areas with a simple online search; for example, by searching "recycle electronics" along with the city or area name.

Cloud services have proven to be useful in storing data, which is then accessible from anywhere in the world without the need to carry storage devices. Cloud storage also allows for large storage, at low cost. This offers convenience, while reducing the need for manufacture of new storage devices, thus curbing the amount of e-waste generated. [122]

Electronic waste classification

The market has a lot of different types of electrical products. To categorize these products, it is necessary to group them into sensible and practical categories. Classification of the products may even help to determine the process to be used for disposal of the product. Making the classifications, in general, is helping to describe e-waste. Classifications has not defined special details, for example when they do not pose a threat to the environment. On the other hand, classifications should not be too aggregated because of countries differences in interpretation. [123] The UNU-KEYs system closely follows the harmonized statistical (HS) coding. It is an international nomenclature which is an integrated system to allow classify common basis for customs purposes. [123]

Electronic waste substances

Several sizes of button and coin cell with 2 9v batteries as a size comparison. They are all recycled in many countries since they often contain lead, mercury and cadmium.

Some computer components can be reused in assembling new computer products, while others are reduced to metals that can be reused in applications as varied as construction, flatware, and jewellery. Substances found in large quantities include epoxy resins, fiberglass, PCBs, PVC (polyvinyl chlorides), thermosetting plastics, lead, tin, copper, silicon, beryllium, carbon, iron, and aluminum. Elements found in small amounts include cadmium, mercury, and thallium. [124] Elements found in trace amounts include americium, antimony, arsenic, barium, bismuth, boron, cobalt, europium, gallium, germanium, gold, indium, lithium, manganese, nickel, niobium, palladium, platinum, rhodium, ruthenium, selenium, [125] silver, tantalum, terbium, thorium, titanium, vanadium, and yttrium. Almost all electronics contain lead and tin (as solder) and copper (as wire and printed circuit board tracks), though the use of lead-free solder is now spreading rapidly. The following are ordinary applications:

Hazardous

Recyclers in the street in São Paulo, Brazil, with old computers
Hazardous waste material from e-waste
E-waste Component Electric Appliances in which they are found Adverse Health Effects
Americium The radioactive source in smoke alarms. It is known to be carcinogenic. [126]
Lead Solder, CRT monitor glass, lead–acid batteries, some formulations of PVC. A typical 15-inch cathode ray tube may contain 1.5 pounds of lead, [8] but other CRTs have been estimated as having up to 8 pounds of lead. Adverse effects of lead exposure include impaired cognitive function, behavioral disturbances, attention deficits, hyperactivity, conduct problems, and lower IQ. [127] These effects are most damaging to children whose developing nervous systems are very susceptible to damage caused by lead, cadmium, and mercury. [128]
Mercury Found in fluorescent tubes (numerous applications), tilt switches (mechanical doorbells, thermostats), [129] and ccfl backlights in flat screen monitors. Health effects include sensory impairment, dermatitis, memory loss, and muscle weakness. Exposure in-utero causes fetal deficits in motor function, attention, and verbal domains. [127] Environmental effects in animals include death, reduced fertility, and slower growth and development.
Cadmium Found in light-sensitive resistors, corrosion-resistant alloys for marine and aviation environments, and nickel–cadmium batteries. The most common form of cadmium is found in nickel–cadmium rechargeable batteries. These batteries tend to contain between 6 and 18% cadmium. The sale of nickel–cadmium batteries has been banned in the EU except for medical use. When not properly recycled it can leach into the soil, harming microorganisms and disrupting the soil ecosystem. Exposure is caused by proximity to hazardous waste sites and factories and workers in the metal refining industry. The inhalation of cadmium can cause severe damage to the lungs and is also known to cause kidney damage. [130] Cadmium is also associated with deficits in cognition, learning, behavior, and neuromotor skills in children. [127]
Hexavalent chromium Used in metal coatings to protect from corrosion. A known carcinogen after occupational inhalation exposure. [127]

There is also evidence of cytotoxic and genotoxic effects of some chemicals, which have been shown to inhibit cell proliferation, cause cell membrane lesion, cause DNA single-strand breaks, and elevate Reactive Oxygen Species (ROS) levels. [131]

Sulfur Found in lead–acid batteries. Health effects include liver damage, kidney damage, heart damage, eye and throat irritation. When released into the environment, it can create sulfuric acid through sulfur dioxide.
Brominated Flame Retardants ( BFRs) Used as flame retardants in plastics in most electronics. Includes PBBs, PBDE, DecaBDE, OctaBDE, PentaBDE. Health effects include impaired development of the nervous system, thyroid problems, liver problems. [132] Environmental effects: similar effects as in animals as humans. PBBs were banned from 1973 to 1977 on. PCBs were banned during the 1980s.
Perfluorooctanoic acid (PFOA) Used as an antistatic additive in industrial applications and found in electronics, also found in non-stick cookware ( PTFE). PFOAs are formed synthetically through environmental degradation. Studies in mice have found the following health effects: Hepatotoxicity, developmental toxicity, immunotoxicity, hormonal effects and carcinogenic effects. Studies have found increased maternal PFOA levels to be associated with an increased risk of spontaneous abortion (miscarriage) and stillbirth. Increased maternal levels of PFOA are also associated with decreases in mean gestational age (preterm birth), mean birth weight (low birth weight), mean birth length (small for gestational age), and mean APGAR score. [133]
Beryllium oxide Filler in some thermal interface materials such as thermal grease used on heatsinks for CPUs and power transistors, [134] magnetrons, X-ray-transparent ceramic windows, heat transfer fins in vacuum tubes, and gas lasers. Occupational exposures associated with lung cancer, other common adverse health effects are beryllium sensitization, chronic beryllium disease, and acute beryllium disease. [135]
Polyvinyl chloride (PVC) Commonly found in electronics and is typically used as insulation for electrical cables. [136] In the manufacturing phase, toxic and hazardous raw material, including dioxins are released. PVC such as chlorine tend to bioaccumulate. [137] Over time, the compounds that contain chlorine can become pollutants in the air, water, and soil. This poses a problem as human and animals can ingest them. Additionally, exposure to toxins can result in reproductive and developmental health effects. [138]

Generally non-hazardous

An iMac G4 that has been repurposed into a lamp (photographed next to a Mac Classic and a Motorola MicroTAC)
Recycling non-hazardous waste [139]
E-waste component Process used
Aluminum Nearly all electronic goods using more than a few watts of power ( heatsinks), ICs, electrolytic capacitors
Copper Copper wire, printed circuit board tracks, ICs, component leads
Germanium [125] 1950s–1960s transistorized electronics ( bipolar junction transistors)
Gold Connector plating, primarily in computer equipment
Lithium Lithium-ion batteries
Nickel Nickel–cadmium batteries
Silicon Glass, transistors, ICs, printed circuit boards
Tin Solder, coatings on component leads
Zinc Plating for steel parts

Human health and safety

Residents living near recycling sites

Residents living around the e-waste recycling sites, even if they do not involve in e-waste recycling activities, can also face the environmental exposure due to the food, water, and environmental contamination caused by e-waste, because they can easily contact to e-waste contaminated air, water, soil, dust, and food sources. In general, there are three main exposure pathways: inhalation, ingestion, and dermal contact. [140]

Studies show that people living around e-waste recycling sites have a higher daily intake of heavy metals and a more serious body burden. Potential health risks include mental health, impaired cognitive function, and general physical health damage [141] (see also Electronic waste#Hazardous). DNA damage was also found more prevalent in all the e-waste exposed populations (i.e. adults, children, and neonates) than the populations in the control area. [141] DNA breaks can increase the likelihood of wrong replication and thus mutation, as well as lead to cancer if the damage is to a tumor suppressor gene. [131]

Prenatal exposure and neonates' health

Prenatal exposure to e-waste has found to have adverse effects on human body burden of pollutants of the neonates. In Guiyu, one of the most famous e-waste recycling sites in China, it was found that increased cord blood lead concentration of neonates was associated with parents' participation in e-waste recycling processes, as well as how long the mothers spent living in Guiyu and in e-waste recycling factories or workshops during pregnancy. [140] Besides, a higher placental metallothionein (a small protein marking the exposure of toxic metals) was found among neonates from Guiyu as a result of Cd exposure, while the higher Cd level in Guiyu's neonates was related to the involvement in e-waste recycling of their parents. [142] High PFOA exposure of mothers in Guiyu is related to adverse effect on growth of their new-born and the prepotency in this area. [143]

Prenatal exposure to informal e-waste recycling can also lead to several adverse birth outcomes (still birth, low birth weight, low Apgar scores, etc.) and longterm effects such as behavioral and learning problems of the neonates in their future life. [144]

Children

Children are especially sensitive to e-waste exposure because of several reasons, such as their smaller size, higher metabolism rate, larger surface area in relation to their weight, and multiple exposure pathways (for example, dermal, hand-to-mouth, and take-home exposure). [145] [141] They were measured to have an 8-time potential health risk compared to the adult e-waste recycling workers. [141] Studies have found significant higher blood lead levels (BLL) and blood cadmium levels (BCL) of children living in e-waste recycling area compared to those living in control area. [146] [147] For example, one study found that the average BLL in Guiyu was nearly 1.5 times compared to that in the control site (15.3 ug/dL compared to 9.9 ug/dL), [146] while the CDC of the United States has set a reference level for blood lead at 5 ug/dL. [148] The highest concentrations of lead were found in the children of parents whose workshop dealt with circuit boards and the lowest was among those who recycled plastic. [146]

Exposure to e-waste can cause serious health problems to children. Children's exposure to developmental neurotoxins containing in e-waste such as lead, mercury, cadmium, chromium, arsenic, nickel [149] and PBDEs can lead to a higher risk of lower IQ, impaired cognitive function, exposure to known human carcinogens [149] and other adverse effects. [150] In certain age groups, a decreased lung function of children in e-waste recycling sites has been found. [140] Some studies also found associations between children's e-waste exposure and impaired coagulation, [151] hearing loss, [152] and decreased vaccine antibody tilters [153] in e-waste recycling area. For instance, nickel exposure in boys aged 8–9 years at an e-waste site leads to lower forced vital capacity, decrease in catalase activities and significant increase in superoxide dismutase activities and malondialdehyde levels. [149]

E-waste recycling workers

Agbogbloshie e-waste workers completing a burn for copper recovery, 2010

The complex composition and improper handling of e-waste adversely affect human health. A growing body of epidemiological and clinical evidence has led to increased concern about the potential threat of e-waste to human health, especially in developing countries such as India and China. For instance, in terms of health hazards, open burning of printed wiring boards increases the concentration of dioxins in the surrounding areas. These toxins cause an increased risk of cancer if inhaled by workers and local residents. Toxic metals and poison can also enter the bloodstream during the manual extraction and collection of tiny quantities of precious metals, and workers are continuously exposed to poisonous chemicals and fumes of highly concentrated acids. Recovering resalable copper by burning insulated wires causes neurological disorders, and acute exposure to cadmium, found in semiconductors and chip resistors, can damage the kidneys and liver and cause bone loss. Long-term exposure to lead on printed circuit boards and computer and television screens can damage the central and peripheral nervous system and kidneys, and children are more susceptible to these harmful effects. [154]

The Occupational Safety & Health Administration (OSHA) has summarized several potential safety hazards of recycling workers in general, such as crushing hazards, hazardous energy released, and toxic metals. [155]

Hazards applicable to recycling in general [155] [156]
Hazards Details
Slips, trips, and falls They can happen during collecting and transporting e-waste.
Crushing hazards Workers can be stuck or crushed by the machine or the e-waste. There can be traffic accidents when transporting e-waste. Using machines that have moving parts, such as conveyors and rolling machines can also cause crush accidents, leading to amputations, crushed fingers or hands.
Hazardous energy released Unexpected machine startup can cause death or injury to workers. This can happen during the installation, maintenance, or repair of machines, equipment, processes, or systems.
Cuts and lacerations Hands or body injuries and eye injuries can occur when dismantling e-waste that has sharp edges.
Noise Working overtime near loud noises from drilling, hammering, and other tools that can make a great noise lead to hearing loss.
Toxic chemicals (dusts) Burning e-waste to extract metals emits toxic chemicals (e.g. PAHs, lead) from e-waste to the air, which can be inhaled or ingested by workers at recycling sites. This can lead to illness from toxic chemicals.

OSHA has also specified some chemical components of electronics that can potentially do harm to e-recycling workers' health, such as lead, mercury, PCBs, asbestos, refractory ceramic fibers (RCFs), and radioactive substances. [155] Besides, in the United States, most of these chemical hazards have specific Occupational exposure limits (OELs) set by OSHA, National Institute for Occupational Safety and Health (NIOSH), and American Conference of Governmental Industrial Hygienists (ACGIH).

Occupational exposure limits (OELs) of some hazardous chemicals
Hazardous chemicals OELs (mg/m^3) Type of OELs
Lead (Pb) 0.05 [157] NIOSH recommended exposure limits (REL), time weighted average (TWA)
Mercury (Hg) 0.05 [158] NIOSH REL, TWA
Cadmium (Cd) 0.005 [159] OSHA permissible exposure limit (PEL), TWA
Hexavalent chromium 0.005 [160] OSHA PEL, TWA
Sulfur dioxide 5 [161] NIOSH REL, TWA

For the details of health consequences of these chemical hazards, see also Electronic waste#Electronic waste substances.

Informal and formal industries

Informal e-recycling industry refers to small e-waste recycling workshops with few (if any) automatic procedures and personal protective equipment (PPE). On the other hand, formal e-recycling industry refers to regular e-recycling facilities sorting materials from e-waste with automatic machinery and manual labor, where pollution control and PPE are common. [140] [162] Sometimes formal e-recycling facilities dismantle the e-waste to sort materials, then distribute it to other downstream recycling department to further recover materials such as plastic and metals. [162]

The health impact of e-waste recycling workers working in informal industry and formal industry are expect to be different in the extent. [162] Studies in three recycling sites in China suggest that the health risks of workers from formal e-recycling facilities in Jiangsu and Shanghai were lower compared to those worked in informal e-recycling sites in Guiyu. [141] The primitive methods used by unregulated backyard operators (e.g., the informal sector) to reclaim, reprocess, and recycle e-waste materials expose the workers to a number of toxic substances. Processes such as dismantling components, wet chemical processing, and incineration are used and result in direct exposure and inhalation of harmful chemicals. Safety equipment such as gloves, face masks, and ventilation fans are virtually unknown, and workers often have little idea of what they are handling. [163] In another study of e-waste recycling in India, hair samples were collected from workers at an e-waste recycling facility and an e-waste recycling slum community (informal industry) in Bangalore. [164] Levels of V, Cr, Mn, Mo, Sn, Tl, and Pb were significantly higher in the workers at the e-waste recycling facility compared to the e-waste workers in the slum community. However, Co, Ag, Cd, and Hg levels were significantly higher in the slum community workers compared to the facility workers.

Even in formal e-recycling industry, workers can be exposed to excessive pollutants. Studies in the formal e-recycling facilities in France and Sweden found workers' overexposure (compared to recommended occupational guidelines) to lead, cadmium, mercury and some other metals, as well as BFRs, PCBs, dioxin and furans. Workers in formal industry are also exposed to more brominated flame-retardants than reference groups. [162]

Hazard controls

For occupational health and safety of e-waste recycling workers, both employers and workers should take actions. Suggestions for the e-waste facility employers and workers given by California Department of Public Health are illustrated in the graphic.

Safety suggestion for e-waste recycling facilities employers and workers [156]
Hazards What must employers do What should workers do
General Actions include:
  1. Determine the hazards in the workplace and take actions to control them;
  2. Check and make correction to the workplace condition regularly;
  3. Supply safe tools and PPE to workers;
  4. Provide workers with training about hazards and safe work practice;
  5. A written document about injury and illness prevention.
Suggestions include:
  1. Wear PPE when working;
  2. Talk with employers about ways to improve working conditions;
  3. Report anything unsafe in the workplace to employers;
  4. Share experience of how to work safely with new workers.
Dust Actions include:
  1. Offer a clean eating area, cleaning area and supplies, uniforms and shoes, and lockers for clean clothes to the workers;
  2. Provide tools to dismantle the e-waste.

If the dust contains lead or cadmium:

  1. Measure the dust, lead and cadmium level in the air;
  2. Provide cleaning facilities such as wet mops and vacuums;
  3. Provide exhaust ventilation. If it is still not sufficient to reduce the dust, provide workers with respirators;
  4. Provide workers with blood lead testing when lead level is not less than 30 mg/m3.
Protective measures include:
  1. Clean the workplace regularly, and do not eat or smoke when dealing with e-waste;
  2. Do not use brooms to clean the workplace since brooms can raise dust;
  3. Before going home, shower, change into clean clothes, and separate the dirty work clothes and clean clothes;
  4. Test the blood lead, even if the employers do not provide it;
  5. Use respirator, check for leaks every time before use, always keep it on your face in the respirator use area, and clean it properly after use.
Cuts and lacerations Protective equipment such as gloves, masks and eye protection equipments should be provided to workers When dealing with glass or shredding materials, protect the hands and arms using special gloves and oversleeves.
Noise Actions include:
  1. Measure the noise in the workplace, and use engineering controls when levels exceed the exposure limit;
  2. Reduce the vibration of the working desk by rubber matting;
  3. Provide workers with earmuffs when necessary.
Wear the hearing protection all the time when working. Ask for the employer about the noise monitoring results. Test the hearing ability.
Lifting injuries Provide facilities to lift or move the e-waste and adjustable work tables. When handling e-waste, try to decrease the load per time. Try to get help from other workers when lifting heavy or big things.

See also

Policy and conventions:

Organizations:

Security:

General:

References

  1. ^ Kahhat, Ramzy; Kim, Junbeum; Xu, Ming; Allenby, Braden; Williams, Eric; Zhang, Peng (May 2008). "Exploring e-waste management systems in the United States". Resources, Conservation and Recycling. 52 (7): 956. doi: 10.1016/j.resconrec.2008.03.002.
  2. ^ Perkins, Devin N.; Drisse, Marie-Noel Brune; Nxele, Tapiwa; Sly, Peter D. (25 November 2014). "E-Waste: A Global Hazard". Annals of Global Health. 80 (4): 286–295. doi: 10.1016/j.aogh.2014.10.001. PMID  25459330. S2CID  43167397.
  3. ^ Sakar, Anne (12 February 2016). "Dad brought home lead, kids got sick". The Cincinnati Enquirer. Archived from the original on 29 March 2022. Retrieved 8 November 2019.
  4. ^ US EPA, OLEM (10 September 2019). "National Recycling Strategy". www.epa.gov.
  5. ^ "Electronic Hazardous Waste (E-Waste)". dtsc.ca.gov.
  6. ^ a b Baldé, C. P., et al., The Global E-waste Monitor 2017, UNU, ITU, ISWA, 2017
  7. ^ Marin, Johan (15 October 2022). "College of Saint Mary spreads sustainability awareness through recycling event". wowt.com. Retrieved 28 October 2022.
  8. ^ a b Morgan, Russell (21 August 2006). "Tips and Tricks for Recycling Old Computers". SmartBiz. Archived from the original on 15 April 2009. Retrieved 17 March 2009.
  9. ^ "Defining & categorization of wastes via the regulations". ITGreen. 2 June 2013. Archived from the original on 11 June 2013. Retrieved 21 June 2013.
  10. ^ "Ghana e-Waste Country Assessment" (PDF). SBC e-Waste Africa Project. Archived from the original (PDF) on 15 August 2011. Retrieved 29 August 2011.
  11. ^ a b c "A New Circular Vision for Electronics, Time for a Global Reboot". World Economic Forum. 24 January 2019. Retrieved 23 March 2021.
  12. ^ Smedley, Tim. The Guardian, 2013. Web. 22 May 2015. Smedley, Tim (18 November 2013). "Is Phonebloks really the future of sustainable smartphones?". The Guardian. Archived from the original on 21 December 2016. Retrieved 19 December 2016.
  13. ^ a b c Sthiannopkao, Suthipong; Wong, Ming Hung (2013). "Handling e-waste in developed and developing countries: Initiatives, practices, and consequences". Science of the Total Environment. 463–464: 1147–1153. Bibcode: 2013ScTEn.463.1147S. doi: 10.1016/j.scitotenv.2012.06.088. PMID  22858354.
  14. ^ "Statistics on the Management of Used and End-of-Life Electronics". US Environmental Protection Agency. Archived from the original on 5 February 2012. Retrieved 13 March 2012.
  15. ^ "Environment". ECD Mobile Recycling. Archived from the original on 24 April 2014. Retrieved 24 April 2014.
  16. ^ Blau, J (November 2006). "UN Summit on e-waste: Nokia, Vodafone and Others to Attend UN Summit on e-waste". CIO business magazine.[ permanent dead link]
  17. ^ Section, United Nations News Service (22 February 2010). "As e-waste mountains soar, UN urges smart technologies to protect health". United Nations-DPI/NMD – UN News Service Section. Archived from the original on 24 July 2012. Retrieved 12 March 2012.
  18. ^ a b "Urgent need to prepare developing countries for surges in E-Waste". Archived from the original on 31 May 2011.
  19. ^ Luthar, Breda (2011). "Class, Cultural Capital, and the Mobile Phone". Sociologický Časopis. 47 (6): 1091–1118. JSTOR  23535016.
  20. ^ Walsh, Bryan (8 March 2012). "E-Waste: How the New IPad Adds to Electronic Garbage". Time. Retrieved 22 May 2015.
  21. ^ a b Holuszko, Maria E.; Espinosa, Denise C. R.; Scarazzato, Tatiana; Kumar, Amit (10 January 2022). Holuszko, Maria E.; Kumar, Amit; Espinosa, Denise C.R. (eds.). Introduction, Vision, and Opportunities (1 ed.). Wiley. pp. 1–13. doi: 10.1002/9783527816392.ch1. ISBN  978-3-527-34490-1. S2CID  244687606.
  22. ^ "Archived copy" (PDF). Archived (PDF) from the original on 18 July 2015. Retrieved 22 May 2015.{{ cite web}}: CS1 maint: archived copy as title ( link)
  23. ^ Kozlan, Melanie (2 November 2010). "What is 'E-Waste' & How Can I Get Rid of It?!". Four Green Steps. Archived from the original on 30 November 2010.
  24. ^ "Poison PCs and toxic TVs" (PDF). Archived (PDF) from the original on 20 May 2011.
  25. ^ Ingenthron, Robin (31 March 2011). "Why We Should Ship Our Electronic "waste" to China and Africa". Motherboard.tv. Vice. Archived from the original on 21 July 2011.
  26. ^ Authored By Baldé, C., Forti, V., Gray, V., Kuehr, R. and Stegmann, P. (n.d.). Quantities, Flows, and Resources The Global E-waste Monitor 2017.
  27. ^ Authored By Baldé, C., Forti, V., Gray, V., Kuehr, R. and Stegmann, P. (2020). The Global E-waste Monitor 2020.
  28. ^ "International E-Waste Day: 57.4M Tonnes Expected in 2021 | WEEE Forum". weee-forum.org. 13 October 2021. Retrieved 11 January 2022.
  29. ^ Gill, Victoria (7 May 2022). "Mine e-waste, not the Earth, say scientists". BBC. Retrieved 8 May 2022.
  30. ^ "17 Shocking E-Waste Statistics In 2022 - The Roundup". theroundup.org. 12 August 2021. Retrieved 30 November 2022.
  31. ^ "GTF 2022". E-Waste Monitor. Retrieved 30 November 2022.
  32. ^ Forti, Vanessa (2 July 2020). "The Global E-Waste Monitor 2020: Quantities, Flows and the Circular Economy Potential". ResearchGate.
  33. ^ "E-Waste Legislative Framework Map". Mobile for Development. Retrieved 25 December 2020.
  34. ^ Ruediger, Kuehr (21 February 2018). "Developing Legislative Principles for e-waste policy in developing and emerging countries". Solving the E-Waste Problem: 24.
  35. ^ "Apple opposes EU plans to make common charger port for all devices". The Guardian. 23 September 2021. Retrieved 19 October 2021.
  36. ^ Peltier, Elian (23 September 2021). "In a setback for Apple, the European Union seeks a common charger for all phones". The New York Times. Retrieved 19 October 2021.
  37. ^ "One common charging solution for all". Internal Market, Industry, Entrepreneurship and SMEs – European Commission. 5 July 2016. Retrieved 19 October 2021.
  38. ^ Porter, Jon; Vincent, James (7 June 2022). "USB-C will be mandatory for phones sold in the EU 'by autumn 2024'". The Verge. Retrieved 7 June 2022.
  39. ^ ""Supporting the 2030 Agenda for Sustainable Development by enhancing UN system-wide collaboration and coherent responses on environmental matters"United Nations System-wide Response to Tackling E-waste" (PDF). unemg.org. 2017. Retrieved 23 March 2021.
  40. ^ "International Convention for the Prevention of Pollution from Ships (MARPOL)". www.imo.org. Archived from the original on 22 June 2015. Retrieved 17 January 2022.
  41. ^ Convention, Basel (22 March 1989). "Basel Convention > The Convention > Overview". Basel Convention Home Page. Retrieved 23 March 2021.
  42. ^ "The Montreal Protocol on Substances that Deplete the Ozone Layer". Ozone Secretariat. Retrieved 23 March 2021.
  43. ^ "Convention C170 – Chemicals Convention, 1990 (No. 170)". International Labour Organization. 6 June 1990. Retrieved 23 March 2021.
  44. ^ Convention, Stockholm (19 February 2021). "Home page". Stockholm Convention. Retrieved 23 March 2021.
  45. ^ Mercury, Minamata Convention on. "Minamata Convention on Mercury > Home". Minamata Convention on Mercury > Home. Retrieved 23 March 2021.
  46. ^ "The Paris Agreement". unfccc.int. Retrieved 23 March 2021.
  47. ^ Grossman, Elizabeth (10 April 2006). "Where computers go to die – and kill (4/10/2006)". Salon.com. Retrieved 8 November 2012.
  48. ^ a b Osibanjo, Oladele (1 December 2007). "The Challenge of Electronic Waste (E-waste) Management in Developing Countries". Waste Management & Research. 25 (6): 489–501. doi: 10.1177/0734242x07082028. PMID  18229743. S2CID  21323480.
  49. ^ Prashant, Nitya (20 August 2008). "Cash For Laptops Offers 'Green' Solution for Broken or Outdated Computers". Green Technology. Norwalk, Connecticut: Technology Marketing Corporation. Archived from the original on 19 January 2010. Retrieved 17 March 2009.
  50. ^ a b Basel Action Network; Silicon Valley Toxics Coalition (25 February 2002). "Exporting Harm: The High-Tech Trashing of Asia" (PDF). Seattle and San Jose. Archived (PDF) from the original on 9 March 2008.
  51. ^ Chea, Terence (18 November 2007). "America Ships Electronic Waste Overseas". Associated Press. Archived from the original on 22 December 2014.
  52. ^ Slade, Giles (2006). "Made To Break: Technology and Obsolescence in America". Harvard University Press. Archived from the original on 22 December 2012.
  53. ^ a b Carroll (January 2008). "High-Tech Trash". National Geographic Magazine Online. Archived from the original on 2 February 2008.
  54. ^ Ramzy Kahhat and Eric Williams (June 2009). "Product or Waste? Importation and End-of-Life Processing of Computers in Peru". Environmental Science and Technology. 43 (15). Center for Earth Systems Engineering and Management, Arizona State University / American Chemical Society: 6010–6016. Bibcode: 2009EnST...43.6010K. doi: 10.1021/es8035835. PMID  19731711.
  55. ^ Minter, Adam (7 March 2011). "Shanghai Scrap". Wasted 7/7. The Atlantic. Archived from the original on 23 March 2011. Retrieved 7 March 2011.
  56. ^ "Illegal e-waste exposed". Greenpeace International. Archived from the original on 11 July 2008.
  57. ^ "E-Trash Industry Poses Hazards to Workers". Archived from the original on 21 September 2008.
  58. ^ Simmons, Dan (14 October 2005). "British Broadcasting Corporation". BBC News. Archived from the original on 28 December 2006. Retrieved 3 January 2010.
  59. ^ "Electronic Waste in Ghana". YouTube. Archived from the original on 12 October 2016.
  60. ^ "Poisoning the poor – Electronic Waste in Ghana". Greenpeace International. Archived from the original on 8 August 2008.
  61. ^ "British Broadcasting Corporation". BBC News. 5 August 2008. Archived from the original on 18 February 2009. Retrieved 3 January 2010.
  62. ^ "British Broadcasting Corporation". BBC News. 27 November 2006. Archived from the original on 27 August 2010. Retrieved 3 January 2010.
  63. ^ Carney, Liz (19 December 2006). "British Broadcasting Corporation". BBC News. Archived from the original on 21 August 2009. Retrieved 3 January 2010.
  64. ^ "Archived copy" (PDF). Archived (PDF) from the original on 1 December 2017. Retrieved 10 August 2017.{{ cite web}}: CS1 maint: archived copy as title ( link)
  65. ^ Slade, Giles. "Computer age leftovers". Denver Post. Archived from the original on 8 December 2006. Retrieved 13 November 2006.
  66. ^ Wong, M.H. (2007). "Export of toxic chemicals – A review of the case of uncontrolled electronic-waste recycling". Environmental Pollution. 149 (2): 131–140. doi: 10.1016/j.envpol.2007.01.044. PMID  17412468.
  67. ^ "Electronic Waste Dump of the World". Sometimes-interesting.com. Archived from the original on 25 November 2012. Retrieved 23 November 2012.
  68. ^ "E-Waste Dump of the World". Seattletimes.com. Archived from the original on 21 December 2012. Retrieved 23 November 2012.
  69. ^ "Where does e-waste end up?". Greenpeace. Archived from the original on 29 July 2015.
  70. ^ Mukherjee, Rahul (2017). "Anticipating Ruinations: Ecologies of 'Make Do' and 'Left With'". Journal of Visual Culture. 16 (3): 287–309. doi: 10.1177/1470412917740884. S2CID  148682371.
  71. ^ a b Ngoc Ha, Nguyen; Agusa, Tetsuro; Ramu, Karri; Phuc Cam Tu, Nguyen; Murata, Satoko; Bulbule, Keshav A.; Parthasaraty, Peethmbaram; Takahashi, Shin; Subramanian, Annamalai; Tanabe, Shinsuke (2009). "Contamination by trace elements at e-waste recycling sites in Bangalore, India". Chemosphere. 76 (1): 9–15. Bibcode: 2009Chmsp..76....9H. doi: 10.1016/j.chemosphere.2009.02.056. PMID  19345395.
  72. ^ Needhidasan, S; Samuel, M; Chidambaram, R (2014). "Electronic waste- an emerging threat to the environment of urban India". Journal of Environmental Health Science and Engineering. 12 (1): 36. doi: 10.1186/2052-336X-12-36. PMC  3908467. PMID  24444377.
  73. ^ a b c d e f g h i de Vries, Alex; Stoll, Christian (1 December 2021). "Bitcoin's growing e-waste problem". Resources, Conservation and Recycling. 175. Elsevier: 105901. doi: 10.1016/j.resconrec.2021.105901. ISSN  0921-3449. S2CID  240585651.
  74. ^ Jana, Rabin K.; Ghosh, Indranil; Das, Debojyoti; Dutta, Anupam (2021). "Determinants of electronic waste generation in Bitcoin network: Evidence from the machine learning approach". Technological Forecasting and Social Change. 173 (C): 121101. doi: 10.1016/j.techfore.2021.121101.
  75. ^ a b c d e de Vries, Alex (17 April 2019). "Renewable Energy Will Not Solve Bitcoin's Sustainability Problem". Joule. 3 (4): 893–898. doi: 10.1016/j.joule.2019.02.007. ISSN  2542-4351. S2CID  169784459.
  76. ^ Koomey, Jonathan; Berard, Stephen; Sanchez, Marla; Wong, Henry (March 2011). "Implications of Historical Trends in the Electrical Efficiency of Computing". IEEE Annals of the History of Computing. 33 (3): 46–54. doi: 10.1109/MAHC.2010.28. ISSN  1934-1547. S2CID  8305701. Koomey's law describes a trend: "at a fixed computing load, the amount of battery you need will fall by a factor of two every year and a half.", Koomey wrote.
  77. ^ a b Saleh, Fahad (7 July 2020). "Blockchain Without Waste: Proof-of-Stake". SSRN  3183935.
  78. ^ Frazzoli, Chiara; Orisakwe, Orish Ebere; Dragone, Roberto; Mantovani, Alberto (2010). "Diagnostic health risk assessment of electronic waste on the general population in developing countries' scenarios". Environmental Impact Assessment Review. 30 (6): 388–399. doi: 10.1016/j.eiar.2009.12.004.
  79. ^ Heacock Michelle; Kelly Carol Bain; Asante Kwadwo Ansong; Birnbaum Linda S.; Bergman Åke Lennart; Bruné Marie-Noel; Buka Irena; Carpenter David O.; Chen Aimin; Huo Xia; Kamel Mostafa (1 May 2016). "E-Waste and Harm to Vulnerable Populations: A Growing Global Problem". Environmental Health Perspectives. 124 (5): 550–555. doi: 10.1289/ehp.1509699. PMC  4858409. PMID  26418733.
  80. ^ Caravanos, Jack (January 2013). "Exploratory Health Assessment of Chemical Exposures at E-Waste Recycling and Scrapyard Facility in Ghana". Journal of Health and Pollution. 3 (4): 11–22. doi: 10.5696/2156-9614-3.4.11.
  81. ^ "Lead Toxicity: What Are U.S. Standards for Lead Levels?". Agency for Toxicology Substances & Disease Registry. Retrieved 12 January 2019.
  82. ^ Chasant, Muntaka (9 December 2018). "Videos and Photos of Agbogbloshie, Ghana". ATC MASK. Archived from the original on 15 December 2018. Retrieved 13 January 2019.
  83. ^ "Poisoning the poor – Electronic Waste in Ghana". GREENPEACE. 5 August 2008. Retrieved 13 January 2019.
  84. ^ Noor, Jawad Al. "Impacts of e-waste in the environment". Academia.
  85. ^ Diss, South-East Asia correspondent Kathryn (16 July 2019). "This is the new dumping ground for the world's high-tech trash". ABC News. Retrieved 10 January 2020.
  86. ^ Wath, Sushant B.; Dutt, P. S.; Chakrabarti, T. (2011). "E-waste scenario in India, its management and implications" (PDF). Environmental Monitoring and Assessment. 172 (1–4): 249–262. doi: 10.1007/s10661-010-1331-9. PMID  20151189. S2CID  8070711.
  87. ^ Robinson, Brett H. (20 December 2009). "E-waste: An assessment of global production and environmental impacts". Science of the Total Environment. 408 (2): 183–191. Bibcode: 2009ScTEn.408..183R. doi: 10.1016/j.scitotenv.2009.09.044. ISSN  0048-9697. PMID  19846207. S2CID  4378676.
  88. ^ Multiple classes of chemical contaminations in soil from an e-waste disposal site in China: Occurrence and spatial distribution. Science of the Total Environment, volume 752, 15 January 2021, 141924, https://doi.org/10.1016/j.scitotenv.2020.1419
  89. ^ a b Tarter, Andrew (2013), "Environment Programme, UN (UNEP)", Environment Programme, UN (UNEP), Encyclopedia of Crisis Management, SAGE Publications, doi: 10.4135/9781452275956.n127, ISBN  978-1-4522-2612-5
  90. ^ Yuan, C.; Zhang, H. C.; McKenna, G.; Korzeniewski, C.; Li, J. (2007). "Experimental Studies on Cryogenic Recycling of Printed Circuit Board". International Journal of Advanced Manufacturing Technology. 34 (7–8): 657–666. doi: 10.1007/s00170-006-0634-z. S2CID  109520016.
  91. ^ Fela, Jen (April 2010). "Developing countries face e-waste crisis". Frontiers in Ecology and the Environment. 8 (3): 117. doi: 10.1890/1540-9295-8.3.116. JSTOR  20696446.
  92. ^ "Data Destruction". www.pureplanetrecycling.co.uk. Archived from the original on 18 May 2015. Retrieved 9 May 2015.
  93. ^ "E-cycling certification". Environmental Protection Agency. 2013. Archived from the original on 12 April 2013.
  94. ^ "Best Buy Recycles". Bestbuy.com. 2013. Archived from the original on 26 March 2013.
  95. ^ "Staples recycling and eco-stapling". Staples.com. 2013. Archived from the original on 18 March 2013.
  96. ^ "CEA – eCycle". ce.org. Archived from the original on 6 January 2015. Retrieved 6 January 2015.
  97. ^ "Sustainable Materials Management (SMM) Electronics Challenge". Sustainable Management of Electronics. US EPA. 22 September 2012. Retrieved 14 May 2019.
  98. ^ United States Environmental Protection Agency, Sustainable Materials Management Electronics Challenge. Retrieved from "SMM Electronics Challenge". Archived from the original on 3 April 2013. Retrieved 27 March 2013.
  99. ^ "Home – Electronics TakeBack Coalition". Electronicstakeback.com. Archived from the original on 26 February 2015. Retrieved 8 November 2012.
  100. ^ "How to Find a Responsible Recycler". Electronics TakeBack Coalition. Archived from the original on 8 May 2009.
  101. ^ Kunz, Nathan (2018). "Stakeholder Views on Extended Producer Responsibility and the Circular Economy". California Management Review. 60 (3): 45–70. doi: 10.1177/0008125617752694. S2CID  158615408.
  102. ^ "Default Parallels Plesk Panel Page". Certifiedelectronicsrecycler.com. Archived from the original on 22 December 2012. Retrieved 8 November 2012.
  103. ^ "Take Back My TV".
  104. ^ "E-waste recycling in U.S. prisons". 23 December 2006.
  105. ^ "E-Waste Problem Overview".
  106. ^ "40 Million BGN Invested in Bulgaria's 1st Appliances Recycle Plant". Sofia News Agency. 28 June 2010. Archived from the original on 12 October 2012. Retrieved 28 March 2011.
  107. ^ "Bulgaria Opens Largest WEEE Recycling Factory in Eastern Europe". Ask-eu.com. 12 July 2010. Archived from the original on 4 September 2011. Retrieved 28 March 2011.
  108. ^ "WEEE recycling resources". Simsrecycling.co.uk. Archived from the original on 6 January 2015. Retrieved 6 January 2015.
  109. ^ "Kwiat_Environmental Educatioin". Learning Ace.[ permanent dead link]
  110. ^ Leif, Dan (3 November 2021). "Igneo targets low-grade scrap electronics with $85M plant". Retrieved 28 November 2021.
  111. ^ Seif, Rania; Salem, Fatma Zakaria; Allam, Nageh K. (2023). "E-waste recycled materials as efficient catalysts for renewable energy technologies and better environmental sustainability". Environment, Development and Sustainability. 26 (3): 5473–5508. doi: 10.1007/s10668-023-02925-7. PMC  9848041. PMID  36691418.
  112. ^ "Benefits of Recycling". hardrawgathering.co.uk. Archived from the original on 6 January 2015. Retrieved 6 January 2015.
  113. ^ "What can be recycled from e-waste?". zerowaste.sa.gov.au. Archived from the original on 5 March 2016. Retrieved 29 February 2016.
  114. ^ "How to Print 3D Parts Better". sustainabilityworkshop.autodesk.com. Archived from the original on 27 February 2016. Retrieved 29 February 2016.
  115. ^ "Zero or close to zero waste". plasticscribbler.com. Archived from the original on 6 March 2016. Retrieved 29 February 2016.
  116. ^ Interagency Task Force on Electronics Stewardship. (20 July 2011). National Strategy for Electronics Stewardship
  117. ^ "THE FUTURE OF ELECTRONIC WASTE RECYCLING IN THE UNITED STATES: Obstacles and Domestic Solution" (PDF). sea.columbia.edu/. Archived (PDF) from the original on 3 October 2016. Retrieved 29 February 2016.
  118. ^ "Characteristics of E-waste Recycling System in Japan and China" (PDF). workspace.unpan.org. Archived (PDF) from the original on 12 October 2016. Retrieved 29 February 2016.
  119. ^ Cassidy, Nigel (2 May 2014). "Getting in a spin: Why washing machines are no longer built to last".
  120. ^ "The Restart Project". therestartproject.org.
  121. ^ Solon, Olivia (6 March 2017). "The Guardian: A right to repair: why Nebraska farmers are taking on John Deere and Apple". The Guardian.
  122. ^ "How to Reduce Electronic Waste and its Problems: 10 Simple Tips". 13 March 2018.
  123. ^ a b Forti V.; Baldé C.P.; Kuehr R. (2018). "E-waste Statistics: Guidelines on Classifications, Reporting and Indicators, second edition". The Global E-waste Statistics Partnership.
  124. ^ "Chemical fact sheet: Thallium". Spectrum Laboratories. Archived from the original on 21 February 2008. Retrieved 2 February 2008.
  125. ^ a b Hieronymi, Klaus (14 June 2012). E-Waste Management: From Waste to Resource. Routledge. ISBN  978-1-136-29911-7.
  126. ^ "Americium, Radioactive". TOXNET Toxicology Data Network. Archived from the original on 12 October 2016.
  127. ^ a b c d Chen, A.; Dietrich, K. N.; Huo, X.; Ho, S.-M. (2011). "Developmental Neurotoxicants in E-Waste: An Emerging Health Concern". Environmental Health Perspectives. 119 (4): 431–438. doi: 10.1289/ehp.1002452. PMC  3080922. PMID  21081302.
  128. ^ Chen, Aimin; Dietrich, Kim N.; Huo, Xia; Ho, Shuk-mei (1 April 2011). "Developmental neurotoxicants in e-waste: an emerging health concern". Environmental Health Perspectives. 119 (4): 431–438. doi: 10.1289/ehp.1002452. ISSN  1552-9924. PMC  3080922. PMID  21081302.
  129. ^ "Question 8" (PDF). 9 August 2013. Archived (PDF) from the original on 26 March 2009.
  130. ^ "Cadmium (Cd) – Chemical properties, Health and Environmental effects". Lenntech.com. Archived from the original on 15 May 2014. Retrieved 2 June 2014.
  131. ^ a b Wang Liulin; Hou Meiling; An Jing; Zhong Yufang; Wang Xuetong; Wang Yangjun; Wu Minghong; Bi Xinhui; Sheng Guoying; Fu Jiamo (2011). "The cytotoxic and genetoxic effects of dust and soil samples from E-waste recycling area on L02 cells". Toxicology and Industrial Health. 27 (9): 831–839. doi: 10.1177/0748233711399313. PMID  21421680. S2CID  208360586.
  132. ^ Birnbaum, LS; Staskal, DF (2004). "Brominated flame retardants: Cause for concern?". Environmental Health Perspectives. 112 (1): 9–17. doi: 10.1289/ehp.6559. PMC  1241790. PMID  14698924.
  133. ^ Wu, K.; Xu, X.; Peng, L.; Liu, J.; Guo, Y.; Huo, X. (2012). "Association between maternal exposure to perfluorooctanoic acid (PFOA) from electronic waste recycling and neonatal health outcomes". Environment International. 41: 1–8. doi: 10.1016/j.envint.2012.06.018. PMID  22820015.
  134. ^ Becker, Greg; Lee, Chris; Lin, Zuchen (July 2005). "Thermal conductivity in advanced chips: Emerging generation of thermal greases offers advantages". Advanced Packaging: 2–4. Archived from the original on 21 June 2000. Retrieved 4 March 2008.
  135. ^ "Health Effects". United States Department of Labor. Archived from the original on 12 October 2016. Retrieved 30 October 2016.
  136. ^ "Why BFRs and PVC should be phased out of electronic devices".
  137. ^ "Flame retardants & PVC in electronics".
  138. ^ "Polyvinyl Chloride (PVC)". Archived from the original on 10 July 2018. Retrieved 30 May 2018.
  139. ^ US EPA, OMS (10 November 2014). "Regulatory and Guidance Information by Topic: Waste – Guide for Industrial Waste Management". www.epa.gov.
  140. ^ a b c d Grant, Kristen; Goldizen, Fiona C; Sly, Peter D; Brune, Marie-Noel; Neira, Maria; van den Berg, Martin; Norman, Rosana E (December 2013). "Health consequences of exposure to e-waste: a systematic review". The Lancet Global Health. 1 (6): e350–e361. doi: 10.1016/s2214-109x(13)70101-3. ISSN  2214-109X. PMID  25104600.
  141. ^ a b c d e Song, Qingbin; Li, Jinhui (January 2015). "A review on human health consequences of metals exposure to e-waste in China". Environmental Pollution. 196: 450–461. doi: 10.1016/j.envpol.2014.11.004. ISSN  0269-7491. PMID  25468213.
  142. ^ Li, Yan; Huo, Xia; Liu, Junxiao; Peng, Lin; Li, Weiqiu; Xu, Xijin (17 August 2010). "Assessment of cadmium exposure for neonates in Guiyu, an electronic waste pollution site of China". Environmental Monitoring and Assessment. 177 (1–4): 343–351. doi: 10.1007/s10661-010-1638-6. ISSN  0167-6369. PMID  20714930. S2CID  207130613.
  143. ^ Wu, Kusheng; Xu, Xijin; Peng, Lin; Liu, Junxiao; Guo, Yongyong; Huo, Xia (November 2012). "Association between maternal exposure to perfluorooctanoic acid (PFOA) from electronic waste recycling and neonatal health outcomes". Environment International. 48: 1–8. doi: 10.1016/j.envint.2012.06.018. ISSN  0160-4120. PMID  22820015.
  144. ^ Xu, Xijin; Yang, Hui; Chen, Aimin; Zhou, Yulin; Wu, Kusheng; Liu, Junxiao; Zhang, Yuling; Huo, Xia (January 2012). "Birth outcomes related to informal e-waste recycling in Guiyu, China". Reproductive Toxicology. 33 (1): 94–98. doi: 10.1016/j.reprotox.2011.12.006. ISSN  0890-6238. PMID  22198181.
  145. ^ Bakhiyi, Bouchra; Gravel, Sabrina; Ceballos, Diana; Flynn, Michael A.; Zayed, Joseph (January 2018). "Has the question of e-waste opened a Pandora's box? An overview of unpredictable issues and challenges". Environment International. 110: 173–192. doi: 10.1016/j.envint.2017.10.021. ISSN  0160-4120. PMID  29122313.
  146. ^ a b c Huo, X; Peng, L; Xu, X; Zheng, L; Qiu, B; Qi, Z; Zhang, B; Han, D; Piao, Z (July 2007). "Elevated blood lead levels of children in Guiyu, an electronic waste recycling town in China". Environmental Health Perspectives. 115 (7): 1113–7. doi: 10.1289/ehp.9697. PMC  1913570. PMID  17637931.
  147. ^ Zheng, Liangkai; Wu, Kusheng; Li, Yan; Qi, Zongli; Han, Dai; Zhang, Bao; Gu, Chengwu; Chen, Gangjian; Liu, Junxiao (September 2008). "Blood lead and cadmium levels and relevant factors among children from an e-waste recycling town in China". Environmental Research. 108 (1): 15–20. Bibcode: 2008ER....108...15Z. doi: 10.1016/j.envres.2008.04.002. ISSN  0013-9351. PMID  18514186.
  148. ^ "Lead". Centers of Disease Control and Prevention. 19 September 2019. Archived from the original on 11 September 2017.
  149. ^ a b c Lebbie, Tamba S.; Moyebi, Omosehin D.; Asante, Kwadwo Ansong; Fobil, Julius; Brune-Drisse, Marie Noel; Suk, William A.; Sly, Peter D.; Gorman, Julia; Carpenter, David O. (11 August 2021). "E-Waste in Africa: A Serious Threat to the Health of Children". International Journal of Environmental Research and Public Health. 18 (16): 8488. doi: 10.3390/ijerph18168488. ISSN  1660-4601. PMC  8392572. PMID  34444234.
  150. ^ Chen, Aimin; Dietrich, Kim N.; Huo, Xia; Ho, Shuk-mei (April 2011). "Developmental Neurotoxicants in E-Waste: An Emerging Health Concern". Environmental Health Perspectives. 119 (4): 431–438. doi: 10.1289/ehp.1002452. ISSN  0091-6765. PMC  3080922. PMID  21081302.
  151. ^ Zeng, Zhijun; Huo, Xia; Zhang, Yu; Xiao, Zhehong; Zhang, Yuling; Xu, Xijin (12 May 2018). "Lead exposure is associated with risk of impaired coagulation in preschool children from an e-waste recycling area". Environmental Science and Pollution Research. 25 (21): 20670–20679. doi: 10.1007/s11356-018-2206-9. ISSN  0944-1344. PMID  29752673. S2CID  21665670.
  152. ^ Liu, Yu; Huo, Xia; Xu, Long; Wei, Xiaoqin; Wu, Wengli; Wu, Xianguang; Xu, Xijin (May 2018). "Hearing loss in children with e-waste lead and cadmium exposure". Science of the Total Environment. 624: 621–627. Bibcode: 2018ScTEn.624..621L. doi: 10.1016/j.scitotenv.2017.12.091. ISSN  0048-9697. PMID  29272831.
  153. ^ Lin, Xinjiang; Xu, Xijin; Zeng, Xiang; Xu, Long; Zeng, Zhijun; Huo, Xia (January 2017). "Decreased vaccine antibody titers following exposure to multiple metals and metalloids in e-waste-exposed preschool children". Environmental Pollution. 220 (Pt A): 354–363. doi: 10.1016/j.envpol.2016.09.071. ISSN  0269-7491. PMID  27692881.
  154. ^ Mulvaney, Dustin (3 May 2011). Green Technology: An A-to-Z Guide – Google Books. SAGE Publications. ISBN  978-1-4522-6624-4.
  155. ^ a b c "Recycling | Consumer Electronics". www.osha.gov. Retrieved 24 November 2018.
  156. ^ a b "Electronic Waste Recycling: Working Safely" (PDF).
  157. ^ "OSHA Occupational Chemical Database | Occupational Safety and Health Administration". www.osha.gov. Retrieved 13 December 2018.
  158. ^ "OSHA Occupational Chemical Database | Occupational Safety and Health Administration". www.osha.gov. Retrieved 13 December 2018.
  159. ^ "OSHA Occupational Chemical Database | Occupational Safety and Health Administration". www.osha.gov. Retrieved 13 December 2018.
  160. ^ "OSHA Occupational Chemical Database | Occupational Safety and Health Administration". www.osha.gov. Retrieved 13 December 2018.
  161. ^ "OSHA Occupational Chemical Database | Occupational Safety and Health Administration". www.osha.gov. Retrieved 13 December 2018.
  162. ^ a b c d Ceballos, Diana Maria; Dong, Zhao (October 2016). "The formal electronic recycling industry: Challenges and opportunities in occupational and environmental health research". Environment International. 95: 157–166. doi: 10.1016/j.envint.2016.07.010. ISSN  0160-4120. PMID  27568575.
  163. ^ "Electronic waste | Britannica". 6 March 2024.
  164. ^ Ngoc Ha, Nguyen; Agusa, Tetsuro; Ramu, Karri; Phuc Cam Tu, Nguyen; Murata, Satoko; Bulbule, Keshav A.; Parthasaraty, Peethmbaram; Takahashi, Shin; Subramanian, Annamalai; Tanabe, Shinsuke (2009). "Contamination by trace elements at e-waste recycling sites in Bangalore, India". Chemosphere. 76 (1): 9–15. Bibcode: 2009Chmsp..76....9H. doi: 10.1016/j.chemosphere.2009.02.056. PMID  19345395.
  165. ^ "ADISA website". Asset Disposal and Information Security Alliance. Archived from the original on 29 May 2015. Retrieved 9 May 2015.

Further reading

External links