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<blockquote>Extended Producer Responsibility is a concept where manufacturers and importers of products should bear a significant degree of responsibility for the environmental impacts of their products throughout the product life-cycle, including upstream impacts inherent in the selection of materials for the products, impacts from manufacturers’ production process itself, and downstream impacts from the use and disposal of the products.  Producers accept their responsibility when designing their products to minimise life-cycle environmental impacts, and when accepting legal, physical or socio-economic responsibility for environmental impacts that cannot be eliminated by design.</blockquote>
<blockquote>Extended Producer Responsibility is a concept where manufacturers and importers of products should bear a significant degree of responsibility for the environmental impacts of their products throughout the product life-cycle, including upstream impacts inherent in the selection of materials for the products, impacts from manufacturers’ production process itself, and downstream impacts from the use and disposal of the products.  Producers accept their responsibility when designing their products to minimise life-cycle environmental impacts, and when accepting legal, physical or socio-economic responsibility for environmental impacts that cannot be eliminated by design.</blockquote>
Education is also essential to drawing a better circle in the material life cycle of new media technologies.

Revision as of 13:18, 15 December 2010

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Neoliberalism in a ("mystical") nut-"shell"

"Dust thou art, and unto dust thou shalt return." –Genesis 3:19

"The tradition of all dead generations weighs like a nightmare on the brains of the living." –Marx, The Eighteenth Brumaire

Your iPhone is sleek and beautiful. It was designed in California and made in China. It contains within its form—the form of the commodity—the blood of the subaltern exploited for its production. It will soon be obsolete, ready to be burned in order to harvest the precious metals inside. It will soon turn into toxic dust. This is a dossier about this blood and this dust.

Mineral Extraction, or, Why There is No Software and "Immaterial Labor" is Bullshit

An open pit mine in Australia. The striation of a thousand plateaus. The striation of the earth produces a smooth commodity.

The electronic devices that proliferate the lives of those of us on the fortunate side of the “digital divide”—if, indeed, such qualitative judgments are warranted—begin life as raw minerals in the crust of the earth. It is these unrefined kernels that are used to create the “mystical shell” (Marx 1976, 103) of our iPod, iPhone, iPad—in short, our iWorld. But before we can fetishize the sleek shells that Apple designs in California, the materials required to operate the complex computers inside must be harvested from the ground, often at great expense to the environment and human health.

Hard and Soft: Labor and Ware

As neoliberal capitalism becomes more and more reliant on electronic devices to act as the lubrication of the digital economy, the extant to which the world runs on miniaturized semiconductors and circuit boards becomes ever clearer. But we must remember a point that Elizabeth Grossman, a leading eco-journalist, makes in her polemical treatise High Tech Trash, namely: “miniaturization is not dematerialization” (2006, 9). The move to high tech labor conducted largely with the use of electronic devices likes cell phones and lap tops does not mean that all sense of materialism is lost. Indeed, it takes a vast amount of raw materials to make the sleek digital devices that have rendered increasing proportion of the labor performed in the developed world “immaterial.” (Hardt and Negri’s discussion [2000] of “immaterial labor” and its attendant and derivative forms, such as “affective labor,” is probably the most influential in the literature.) As Grossman pointedly puts it, “As we become increasingly dependent on the rapid electronic transfer of information, while telling ourselves that we are moving beyond the point were economics depend on the obvious wholesale exploitation of natural resources, we are also creating a new world of toxic pollution that may prove far more difficult to clean up than any we have known before” (9). The belief that the information economy has delivered us from the soot of the industrial age to the aseptic world of microchips is dead wrong; as Sean Cubitt points out, “In theory, digital communications substitute for energy-hungry transportation, encourage people to stay home in villages rather than risk the desperate conditions of the slums, and prepare economies for transition to the supposedly weightless condition of the advanced information economies. The sad truth is that digital technologies are more, not less polluting and energy-hungry than predecessor media like film and print” (Cubitt 2009). (The title of this dossier is borrowed from Cubitt.)

There are many places in the world were labor is far from immaterial. For example, in the sites in which the minerals used to produce the metals and plastics that are used in the construction of electronics, the labor of the men and women earning a living is very material, embodied, dangerous, and far from the high tech. The extraction of these minerals is usually done in mines that wreak environmental havoc. The shocking conditions of these mines, the networked flows of money and violence are inevitably involved in such a lucrative endeavor, stand in striking contrast to Wired-style, cyber-Utopic discourses of intellectual labor divorced from the dirty modes of production of the past. The work done in office cubicles starts in giant pit mines in all corners of the globe, it wouldn’t be possible otherwise:

Mines that stretch for miles across the Arizona dessert, that tunnel deep under the boreal forests of northern Sweden, and others on nearly every continent produce ore and metals that end up in electronic gadgets on desktops, in pockets, purses and briefcases, and pressed close to ears all around the world. In a region of the Democratic Republic of the Congo wracked by horrific civil war, farmers have left their land to work in lucrative but dangerous, landslide-prone coltan mines. Sale of this ore, which is used in the manufacture of cell phones and other devices, have helped finance that war as well as the fighting between Uganda and Rwanda in this mineral-rich region of Africa. Although they are mostly hidden, metals make up over half the material in the world’s approximately one million computers. A typical desktop computer can contain nearly thirty pounds of metal, and metals are used in all electronics that contain semi-conductors and circuit boards (which are themselves 30 to 50 percent metal)—from big plasma screen TVs to tiny cell phones. (Grossman 2006, 2-3)

We are often unaware of what exists inside the mystical shell of our gleaming electronics; this is especially so in the case of Apple products, for instance, which explicitly strive for intuitive interfaces with few working parts, clean lines and glassy surfaces. Apple’s aesthetic is one that Deleuze and Guattari would describe as “smooth” (1987, 474-500). (It is in the “smooth space” that the “war machine develops” [474], and “the smooth itself can be drawn and occupied by diabolical powers of organization” [480].) What lies inside the shell?

Of the slightly more than half of the materials in a typical desktop computer that are metals, the most likely to be found are copper, aluminum, lead, gold zinc, nickel, tin, silver, and iron, along with platinum, palladium, mercury, cobalt, antimony, arsenic, barium, beryllium, cadmium, chromium, selenium, and gallium. Some metals—aluminum and iron, for example—are used structurally. Others, particularly the heavy metals (cadmium, lead, mercury, and other metallic elements that have high molecular weights), are used in circuit boards, semiconductors, lamps, and batteries. (Grossman 2006, 18)

Metals like copper, which is considered the best nonprecious metal conductor of electricity (Grossman 2006, 22-23), are mined in huge open pits. Copper is “used in semiconductors, circuit boards, CRTs [cathode-ray tubes], high-tech telecommunications, and in the wiring for these and other electronic—both high-tech and those of earlier generations” (23). As the production of electronic devices has increased, so has copper consumption: since the 1970s it has almost doubled (23). The mining of copper is an extremely costly business; it “requires vast amounts of capital, energy, water, and human resources” (25). Mining is a very dirty business. “In the United States, mining releases more toxins than any other industry” (25). The environmental damage done is wide-ranging and long-term, beyond the obviously enormous crater that an open pit mine cuts into the surface of the earth. For example, “[s]ome toxic by-products of mining and metals processing—arsenic, lead, and cadmium—travel with runoff into surrounding streams and groundwater. Some are deposited as tailings—the material that’s discarded after the valuable ores have been extracted. . . . Tailings from copper mines contain sulfites and often a number of other metals, including lead, arsenic, cadmium, and zinc. When exposed to air and water, sulfites create sulfuric acid, which is very corrosive and is acutely toxic to aquatic life” (26). These affects of copper mining are devastating to the eco-system of surrounding environs, but it doesn’t have to be this way: much more could be done to lessen the need for new copper extraction. Copper is one hundred percent recyclable, and “[w]hile about 90 percent of a computer’s copper can be recoverable and used again, only about 10 percent of high-tech electronics are recycled. This means that about 90 percent of the copper that goes into PCs and similar electronics is never used again and, therefore, that most of the copper used in electronics is newly minted” (25). Another process of extraction, on a much smaller scale but no less ruinous for all involved, is that of coltan. Coltan’s “origins provide a strange cautionary tale about the global supply chain and the source of raw materials that goes into high-tech products” (Grossman 2006, 45). As journalist Blaine Harden describes it:

Coltan is the muck-caked counterpoint to the brainer-than-though, environmentally friendly image of the high-tech economy. The wireless world would grind to a halt without it. Coltan, once it is refined in American and European factories, becomes tantalum, a metallic element that is a superb conductor of electricity, highly resistant to heat. Tantalum powder is a vital ingredient in the manufacture of capacitors, the electronic components that control the flow of current inside miniature circuit boards. Capacitors made of tantalum can be found inside almost every laptop, pager, personal digital assistant and cell phone. (Harden 2001)
Super-purified silica sand is processed into wafers. This antiseptic setting belies the toxic conditions of silica's refinement.

Stores of raw coltan can be found in North Kivu Province, in the eastern portion of the worn-torn Democratic Republic of the Congo. Sales of coltan ore “have helped finance the brutal fighting within the DRC and between Uganda and Rwanda . . . Between 1998 and early 2005, the war, hunger and disease have killed approximately 3.8 million people (Grossman 2006, 46). The conditions for mining coltan are primeval, “with people standing knee and thigh deep in muddy water working with hammers, pickaxes, and shovels, sluicing ore through plastic wash tubs and bark-stripped trees” (47). So why is coltan mining such a large part of the economy of the Congo if the working conditions are so deplorable? Harden explains:

All a miner has to do is chop down great swaths of the forest, gouge S.U.V.-size holes in streambeds with pick and shovel and spend days up to his crotch in muck while sloshing water around in a plastic washtub until coltan settles to the bottom. (Coltan is three times heavier than iron, slightly lighter than gold.) If he is strong and relentless and the digging is good, a miner can produce a kilogram a day. Earlier this, year, that was worth $80—a remarkable bounty in a region where most people live on 20 cents a day. (Harden 2001)

Coltan is only the latest in the long history of exploitation of the Congo—from King Leopold II in the late 19th century to the CIA’s assassination of Patrice Lumumba, the Congo’s first democratically elected prime minister, in the 1960s in order to secure access to cobalt and copper (Harden 2001). Yet, for all of this history of violence and oppression, for many Congolese faced with a possible U.N.-backed embargo of coltan from the region, “the only thinkg worse than mining coltan is not mining it” (Harden 2001).

One reason why it is so ideologically tempting to ignore the harsh realities of the production of high tech products is that there is widespread misperceptions about some fundamental distinctions to be made regarding the ontological processes at work in these machines. As Grossman notes, “It hasn’t helped us come to grips with high tech’s waste that when thinking about high tech many of us blur the distinction between hardware and software, forgetting that in addition to armies of computer-science jocks encoding the next operating system or search engine, high tech also means tons of chemicals, metals, and plastics” (2006, 12). Hardware must precede software, just as material labor precedes so-called “immaterial labor.” Friedrich Kittler has taken this thesis to its logical (if patently absurd) conclusion in his essay “There is No Software,” where he also argues that it is a mistake to blur the distinctions between hardware and software. He describes a scenario in which

criminal law, at least in Germany, has recently abandoned the very concept of software as mental property; instead, it defines software as necessarily a material thing. The high court’s reasoning, according to which no computer program could ever run without the corresponding electrical charges in silicon circuitry, can illustrate the fact that the virtual undecidability between software and hardware by no means follows, as systems theorists would like to believe, from a simple variation of observation on points. On the contrary, there are good grounds to assume the indispensability and, consequently, the priority of hardware in general. (1997, 152)

Hardware most be considered the dominant force. We must not forget it is the material substrate—made up of numerous minerals wrenched from the earth—that allows for the connectivity of the informatic economy. As Kittler says:

Precisely this maximal connectivity, on the other, physical side, defines nonprogrammable systems, be they waves or beings. That is why these systems show polynomial growth in complexity and, consequently, why only computations done on nonprogrammable machines could keep up with them. In all evidence, this hypothetical, but all too necessary, type of machine would constitute sheer hardware, a physical device working amidst physical devices and subject to the same bounded resources. Software in the usual sense of an ever-feasible abstraction would not exist any longer. The procedures of these machines, though still open to an algorithmic notation, should have to work essentially on a material substrate whose very connectivity would allow for cellular reconfigurations. (154-55)

Kittler can help to remind us that it is the material substrate itself—in our case, minerals and ores—that allows for “maximal connectivity” and “cellular reconfigurations”—connectivities and reconfigurations that are the sine qua non of capitalism’s present, most advanced stage.


How we became posthuman.

We can clearly see the worldwide proliferation of open pit mining as an advanced stage in the “metabolic rift” that Marx describes in first volume of Capital. Today, we are in the age of the hyper-rift. As Alexander Galloway explains, “Marx uses the term ‘metabolic,’ derived from the dynamic flows of biological processes, as an adjective to describe a relationship that is harmonious, systemic, and self-regulating, and in which skills and resources are evenly balanced yet constantly updated through a relationship of equilibrium” (2004, 93). The rift comes, as John Bellamy Foster, Bruce Clark, and Richard York (FCY) describe it, in “the robbing of the soil of the countryside of nutrients and the sending of these nutrients to the cities in the form of food and fiber, where they ended up contributing to pollution. This rupture in the soil nutrient cycle undermined the regenerative capacities of the ecosystem” (2010, 45-46). The large-scale accumulation of minerals is the next step in the industrial agriculture of the 19th century that Marx was responding to. He writes in Capital:

All progress in capitalist agriculture is a process in the art, not only of robbing the worker, but of robbing the soil; all progress in increasing the fertility of the soil for a given time is a progress towards ruining the more long-lasting sources of that fertility. . . . Capitalist production, therefore, only develops the techniques and the degree of combination of the social process of production by simultaneously undermining the original sources of all wealth—the soil and the worker. (Marx 1976, 638; qtd. in FCY 2010, 80)

Likewise, new sites of metal ore, new technologies and techniques for extracting these minerals, more flexible supply chains—all only undermine the future ecology of the earth and the health of humankind.

See Žižek in action here: http://www.youtube.com/watch?v=iGCfiv1xtoU. As Steven Shaviro has recently suggested, “there is no going back on the network and its circuits of celebrity and control. There is no possibility of reverting to an earlier, supposedly clearer and more honest state of affairs. The only way out is the way through. The only possible oppositional stance is one of embracing these new control technologies, generalizing them, and opening them up without reserve” (2010, 116).

E-waste, or, How the World Does Dirt

Truck loaded with e-waste

"digital wizardry relies on a complex array of materials: metals, elements, plastics, and chemical compounds. Each tidy piece of equipment has a story that begins in mines, refineries, factories, rivers, and aquifers and ends on pallets, in dumpsters, and in landfills all around the world."-Grossman, High Tech Trash

As consumer electronics become an important, if not, predominant form of commodity being consumed in many countries around the world, the concern regarding such technologies obsolesces and subsequent disposal has become an increasingly germane issue facing the contemporary world. What’s now know as “e-waste” or “electronic waste” has increasingly become one of the worlds most problematic forms of disposable product.

Because these electronics often contain hazardous chemicals or other toxic materials (such as Copper, antimony, beryllium, barium, zinc, chromium, silver, nickel, and chlorinated and phosphorus-based compounds, as well as polychlorinated biphenyls (PCBs), nonyphenols, and phthalates) (Grossman 2006), their safe disposal require specialized forms of waste management or handling. Unfortunately, such concerns are all to often disregarded by the economy of “fast and cheep” disposal that dominate much e-waste’s eventual destinations, mostly in different parts of Asia and continental Africa, which first world companies and citizens alike are more than willing to turn a blind eye to. In this section, we will be entering a world of waste and circulation, the veritable dark underbelly to Marx’s ‘abode of production’, where the only thing more exploitative than the conditions under which many of the worlds consumer electronics are produced is the manner in which they are disposed of.

The Emergence of E-Waste

“Over the past two decades or more, rapid technological advances have doubled the computing capacity of semiconductor chips almost every eighteen months, bringing us faster computers, smaller cell phones, more efficient machinery and appliances, and an increasing demand for new products. Yet this rushing stream of amazing electronics leaves in its wake environmental degradation and a large volume of hazardous waste— waste created in the collection of the raw materials that go into these products, by the manufacturing process, and by the disposal of these products at the end of their remarkably short lives.” -Grossman, High Tech Trash

From the emergence of the digital age, industrial nations engaged in the never ending proliferation of electronics and other informational devices have been engaged in a relentless cycle of technological growth where preexisting (and often functional) electronic and communications infrastructure is continuously replaced by newer updated versions. As a result of this continuous drive to replace older (and not so old) electronics with new ones, many advanced nations around the world have increasingly found themselves with a growing surplus of obsolete electronics ranging from cell phones, home computers, and an assortment of other industrial and consumer electronics. While in the 1970s and 80s the problem of accounting for (i.e. developing a systematic program for dealing with the safe disposal and/or recycling of such products) discarded electronics seemed like an issue to be dealt with in the distant future, by the 1990s the massive proliferation of personal electronics and their ever accelerating rate of obsolescence expanded to a proportion that threatened to literally bury many advanced nations under a mountain of electronic waste (Rich, 2006).

The material composition of personal computers

According to environmental journalist Elizabeth Grossman, as of 2005 there were approximately 1 billion personal computers and over a billion cells phones in use around the world (Grossman, 2006). Unsurprisingly, the highest concentrations of consumer electronics exist in the worlds wealthiest nations. In the United States alone, Americans own over 200 million personal computers, with nearly “five hundred PC’s per thousand people,” standing as the highest per capita concentrations of computers for any large country internationally. Following the U.S., the next most “PC populous” regions are “Europe, Canada, Hong Kong, Japan, South Korea, and Australia, which all average about two hundred to five hundred PCs per thousand people. In northern Europe the concentration of computers approaches that of the United States, and matches it in Scandinavia. Moving south and east, the number of PCs decreases to about fifty to two hundred per thousand people in Spain, Portugal, and eastern Europe.”(Grossman 2006). In the developing world, India and China have become some of the fastest growing markets for consumer electronics. Nationally, India is estimated to have about 5 PC’s per every thousand of its over one billion inhabitants, with a growth rate of ownership at about 40% per year (Grossman, 2006). Similarly in China, where the economy has experienced an exponential amount of industrial and commercial growth, there is approximately ten to fifty PC’s per every thousand people, a ratio that is currently increasing at a staggering rate.

Today it is estimated that Americans, with a population of roughly 290 Million, own over 2 billion pieces of high-tech consumer electronics (Grossman, 2006). Making up this demographic is a staggering density of electronic ownership:

Americans own over 200 million computers, well over 200 million televisions, and over 150 million cell phones. With some five to seven million tons of this stuff becoming obsolete each year, 11 high-tech electronics are now the fastest growing municipal waste stream, both in the United States and in Europe. In Europe, where discarded electronics create about six million tons of solid waste each year, the volume of e-waste— as this trash has come to be called— is growing three times faster than the rest of the European Union’s municipal solid waste combined. (Grossman 2006, p.7)

What accounts for this exponential rise in the amount of electronic waste accumulating around the world? The first thing to consider is the rapid rate at which high tech electronics have proliferated over the last few decades in many of the advanced industrial nations. To illustrate this point it suffices to look back on the growth of sales rates of consumer electronics. Take for example the sales rate of consumer electronics in the U.S. between 1997 and 2002, which quadrupled during that period (Grossman 2006). Or even more staggering the growth of cell phone ownership during roughly the same time (1997-2003), which grew from approximately 15 million subscribers to over 740 million in the countries that make up the Organization for Economic Cooperation and Development (including the United States, Canada, Japan, Mexico, South Korea, Australia, New Zeeland, EU countries, Sweden, Iceland, Turkey, and many other eastern European countries) (Grossman 2006).

Taking into account the massive proliferation of electronic goods in conjunction with their dwindling life-spans and almost negligible resale values, it is little wonder that e-waste has reached such a staggering proportion. As Grossman instructively points out:

As technology continues to evolve, and the system of production that keeps costs relatively low persists, any incentive that may exist for most consumers to repair or otherwise extend the life of high-tech electronics disappears. Unless this equation changes, we will continue to acquire newer and newer models, tossing more out as we go along. (Grossman 2006)

Given the low incentives for both producers and consumers to systematically reuse obsolete electronic goods, what appears as the only alternative is to develop systems for their recycling or disposal. Yet such technologies present a serious problem for recycling because of the toxic components that they contain. Instead of incurring the costs (both economic and environmental) of reclaiming the precious metals contained in these electronics, many choose to sell them off at cut rate prices to what are known as “trash brokers” or “waste traders”, who then broker deals with countries, often developing, with an inexpensive, abundant labor force and poorly enforced global rules on waste trade. Such is the circuit through which the world’s most dangerous waste finds its way from the advanced to the developing world, with disastrous health and environmental costs. (Grossman 2006)

E-Waste Distribution: The Asymmetrical Division of Waste

Who gets the trash?

In order to divert... obsolete toxic materials from our own landfills in the west,“Recyclers” came forward offering to take them away. For this service there is a collection fee. These agents then sell to Chinese scrap buyers, thereby making money on both ends of the transaction. Everything from massive switching stations, industrial computers, hospital technology, old schoolroom computers—in short, all obsolete electronics, even old rotary phones, are today packed into containers, then shipped to China and other developing nations. Edward Burtynsky, Photographic Works.

Although estimates are uncertain, it is said that roughly eighty per cent of North America’s electronic waste is exported internationally, with about ninety per cent ending up in Mainland China as its final destination (Grossman, 2006) Because of the hazardous nature of much e-waste, processing it poses serious risks even in the most technologically advanced facilities. In China, the disposal of e-waste consists of fare from ideal procedures where:

[in] outdoor workshops, people bang apart the computers and toss bits of metal into brick furnaces that look like chimneys. Split open, the electronics release a stew of toxic materials -- among them beryllium, cadmium, lead, mercury and flame retardants -- that can accumulate in human blood and disrupt the body's hormonal balance. Exposed to heat or allowed to degrade, electronics' plastics can break down into organic pollutants that cause a host of health problems, including cancer. Wearing no protective clothing, workers roast circuit boards in big, uncovered woklike pans to melt plastics and collect valuable metals. Other workers sluice open basins of acid over semiconductors to remove their gold, tossing the waste into nearby streams. (Grossman 2006)
Women picking through wires torn out of computers. The wires are sorted by day and burned by night in this village. The families live right in the burnyards. Cancer causing polycyclic aromatic hydrocarbons and dioxins will result from burning wires made from PVC and brominated flame retardants. Guiyu, China. December 2001.

According to Jim Puckett the director of the Basel Action Network (BAN), an environmental advocacy organization that tracks hazardous waste, such conditions represent the literal dirty “underbelly of our consumptive cyberage lifestyle” (Grossman, 2006). As Puckett explains, most of the reclamation of e-waste in China can be divided into two types, ‘sham’ and ‘dirty’ recycling:

Waste trade for recycling as witnessed in developing countries falls into two categories. It will either be “sham recycling” where wastes are not really recycled at all, but simply burned or dumped, or “dirty recycling” which involves polluting operations including weak downstream management of residuals that jeopardizes health of the importing country’s populace and environment. Most often, both types of recycling are involved as it is rare indeed when 100% of a waste stream can be recycled. In fact, with some waste streams large proportions of the wastes are simply dumped. Either one of these recycling scenarios - sham or dirty, or a combination of the two, equates to a transfer of pollution from rich to poorer countries. (BAN, 2010).

While the disposal of e-waste in China perhaps represents the leading edge of such exploitive practices, the asymmetrical cost of toxic waste is a problem facing even the most advanced nations:

Historically, hazardous waste recycling has proven to be an environmental nightmare even in rich developed countries. For example, a full 11% of US Superfund priority sites that were required to be cleaned up at enormous costs were caused by recycling operations. And it’s not just an historical problem. For example, in the US, existent secondary metals smelters are notorious polluters and that is the reason no new smelters are being planned for the US. Thus highly polluting secondary industry such as smelting is migrating to poorer countries where pollution regulations are more lax or less enforced and costs can be readily externalized. (BAN, 2010).

E-waste: A Provisional Response

Resulting from the emerging magnitude of e-waste as a problem of global concern, many people from both the advanced and developing world have began to take notice of the problem. Since the late 90s, ecological activist groups such as BAN and Greenpeace, have been working to spread awareness of the potential danger of e-waste as well as develop legislation to curb its asymmetrical distribution to developing nations:

In 1994, the Basel Convention on the Control of Transboundary Movements of Hazardous Wastes and their Disposal banned all exports of hazardous wastes for final disposal and recycling from developed to developing countries. The Parties to the Convention included recycling in the total ban due to the knowledge that export of hazardous waste for recycling from developed to developing countries, also works in contradiction to the obligations of the Basel

Convention. These obligations include the achievement of national self-sufficiency in hazardous waste management and environmentally sound management of wastes through waste prevention. (BAN 2010)

As proponents of such measures point out:

The concerns that necessitated the ban are not limited to the technical capacity of a facility operating in a developing countries but extend to one of the primary objectives of the ban -- providing incentives to manage hazardous wastes via upstream solutions of clean production and toxics use reduction, rather than through downstream approaches of recycling and disposal. By eliminating cost externalities made possible by free trade in wastes to developing countries, the waste crisis is more appropriately solved at source through green design and clean production. (BAN 2010)

As the ecological problematic posed by e-waste becomes increasingly apparent, it remains unclear what steps must be taken to stem the tide of environmental degradation and health risks of the digital consumer age. While activism and international regulation mark a first step, such measures have failed to mobilize the large scale change that their authors and participants might have hoped for. In this respect the movement for ecological change, like other attempts at globally effective actions, has been confronted by what might be characterized as the fundamental problematic of large scale political action today; how to mobilize change across a globally shifting terrain of difference and control. To such a question their has yet to be adequate theorization, but perhaps one might begin by following Slovenian theorist Slavoj Žižek’s proposal expressed in a recent article in the New Statesmen, where fallowing Alain Badiou he explains:

It is instructive, here, to return to the four elements of what the French Marxist philosopher Alain Badiou calls the "eternal idea" of revolutionary politics. What is demanded, first, is strict egalitarian justice: worldwide norms of per capita energy consumption should be imposed, stopping developed nations from poisoning the environment at the present rate while blaming developing countries, from Brazil to China, for ruining our shared environment.

Second, terror: the ruthless punishment of all those who violate the imposed protective measures, including severe limitations of liberal "freedoms" and the technological control of prospective lawbreakers. Third, voluntarism: the only way to confront the threat of ecological catastrophe is by means of collective decision-making that will arrest the "spontaneous" logic of capitalist development (Walter Benjamin, in his essay "On the Concept of History", pointed out that the task of a revolution is to "stop the train" of history that runs towards the precipice of global catastrophe - an insight that has gained new weight with the prospect of ecological catastrophe).

Last but not least, trust in the people: the wager that the large majority of the people support these severe measures, see them as their own and are ready to participate in their enforcement. We should not be afraid to encourage, as a combination of terror and trust in the people, the resurgence of an important figure in all egalitarian-revolutionary terror - the "informer" who denounces culprits to the authorities. (In the case of the Enron scandal, Time magazine was right to celebrate the insiders who tipped off the financial authorities as true public heroes.)

While Žižek's proposal for stricter global discipline might strike some as a regressive return to more hard line (vulgar) Marxist politics, the problematic of a revolutionary program for the digital age remains the site where radical and conservative politics alike seem to falter against the impregnable cliff of the future. What is made clear by the current state of affairs is that to not act is no longer an option. As Deleuze says," It’s not a question of worrying or of hoping for the best, but of finding new weapons."(Deleuze, 1995)

The Aesthetics of Waste

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E-waste is horrifying

“To recreate, if not beauty, than aesthetic dimensions… in trash itself. That’s the true love of the world.”- Žižek, Examined Life

"Being a spectator of calamities taking place in another country is a quintessential modern experience, the cumulative offering of more than a century and a half worth of those professional, specialized tourists known as journalists." Sontag, Regarding the Pain of Others

The (Political) Economy of the Dump

Landfill Design

“The U.S. IT industry has been quite outspoken about the need to maintain open global markets for product waste management. Electronic waste constitutes nearly 5 percent of the U.S. municipal solid-waste stream and is growing rapidly.” (Smith et al. 265)

As outlined throughout this text, economies of obsolescence, rapid technological advancement, and a complicated global exchange of e-waste demand critical attention to implement more lasting solutions to the waves of solid waste flowing across geographies. We can look to Jofre and Morioka (2006) for a summary of the trajectories electronic hardware can take at the end of its useful existence.

End-of-Life Strategies

1. Re-use

2. Servicing

3. Remanufacturing

4. Recycling

5. Disposal

Option 1 represents an ideal at odds with contemporary marketing and production. Servicing is often more expensive than buying a new model. Remanufacturing, seldom cost-effective in developed countries, introduces ethical problems entangled in e-waste import/export. And, in practice, 4 and 5 are collapsed together over time. “But even if e-cycling is done under safe labor conditions in the USA, the molecular danger within the computers is just postponed, not eliminated. This is all recycling is. We are in a marginally better situation because the lead and cadmium are not entering air, water and ground through technologies of disposal at this point. But the system that introduced them, and continues to introduce them, chugs along unabated, and growing.” (MacBride) This brings us back to the thousands of landfills scattered across the US that simply cannot hide trash from us forever. Unsightliness aside, the cool, rational illustration of modern landfill design displays how toxins from trash like e-waste live just above a water table that they will eventually enter into.


“Very soon, the sheer volume of e-waste will compel America to adopt design strategies that include not just planned obsolescence but planned disassembly and reuse as part of the product life cycle.” (Slade 281)

A way forward requires factoring the total environmental impact of electronic components into the cost of their sale and manufacture. The Organisation for Economic Co-operation and Development (OECD) has defined a progressive agenda in the form of Extended Producer Responsibility.

Extended Producer Responsibility is a concept where manufacturers and importers of products should bear a significant degree of responsibility for the environmental impacts of their products throughout the product life-cycle, including upstream impacts inherent in the selection of materials for the products, impacts from manufacturers’ production process itself, and downstream impacts from the use and disposal of the products. Producers accept their responsibility when designing their products to minimise life-cycle environmental impacts, and when accepting legal, physical or socio-economic responsibility for environmental impacts that cannot be eliminated by design.

Education is also essential to drawing a better circle in the material life cycle of new media technologies.


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