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RECYCLING OF SCRAPPED ELECTRONICS STUDIED
07 October 2004 - Massachusetts Institute of Technology

MIT researchers have developed new metrics for assessing the performance of firms that recycle scrapped electronic equipment, a major source of toxic pollutants.

MIT researchers have developed new metrics for assessing the performance of firms that recycle scrapped electronic equipment, a major source of toxic pollutants. The metrics focus not just on how much of a firm's incoming waste is processed but also on the quality and reusability of the materials produced from it, a consideration critical to overall resource efficiency.

To assess the performance of electronics recycling firms, people have focused mainly on the most easily measured indicator: the fraction of a firm's incoming waste stream that ends up as landfill. But minimizing landfill is not enough, according to the MIT researchers.

'Recycling companies will tell their customers, 'Virtually none of your material is going to landfill.' While we recognize that that's important, we also know that not all end uses are equal,' said Randolph E Kirchain Jr, an assistant professor in the Department of Materials Science and Engineering and the Engineering Systems Division. 'For example, it's preferable to take a pound of recovered plastic and use it to make new components than to use it as roadbed filler.'

The quality of the recovered material determines its potential uses. If the quality is sufficiently high, the material can be reused by manufacturers, reducing the need to extract and consume new materials.

Almost a billion obsolete computers and other electronic devices are scrapped each year, and four out of five of them end up in basements or on sidewalks rather than in recycling facilities. But the electronics recycling business is expected to grow quickly. Regulations on handling large-scale electronics waste streams are becoming more stringent, and public concern is growing about the shipping of electronics to countries not equipped to handle toxic and hazardous materials.

Kirchain worked with Frank Field III, a senior research associate in the Center for Technology, Policy and Industrial Development, and Jennifer R. Atlee, a graduate student in the Engineering Systems Division, and colleagues in the Materials Systems Laboratory to develop measures of assessing electronics recycling firms. The team drew on its 10 years' experience studying another recycling industry--automobiles.

To identify recycling firms and processes that achieve good materials recovery, the researchers use price as an indicator of quality. 'We hypothesize that the price that's received for those [recovered] materials is an indicator of the quality of the materials. A buyer will pay more for materials they can use in manufacturing components than for materials going into a roadbed,' said Kirchain.

They also used two value-based metrics--value retention and value-added. Value retention measures how well the value of materials is maintained all the way from their first use to their recovery. Value added compares the price of the recovered material to the price the recycler paid or was paid to take it away.

In case studies of three US firms, the researchers found that the value-based metrics worked well and were easy to use. The researchers stress that their materials-only analysis is just a baseline and does not incorporate the effect of device or component reuse. They also note that other criteria could be used to assess the performance of recyclers. Examples include toxicity, emissions, energy use, and operating costs. In the long run, a variety of independent metrics could lead to significant improvements in recycling efficiency.

'We're interested in measures of performance that will lead to the best electronics-recycling practices. But if we really understand the recycling process, we may also be able to help manufacturers of original equipment make design and materials choices that will make recovering, recycling, and reusing materials less expensive,' said Kirchain.

This research marks the beginning of a long-term MIT effort to develop analytical methods and tools that the electronics industry can use to identify and select materials, product designs and process technologies that will improve the sustainability of materials use. It was supported by the Alliance for Global Sustainability.

Elizabeth Thomson
Massachusetts Institute of Technology
+1 617 258 5402

http://mit-pbg.mit.edu

About: Massachusetts Institute of Technology
The mission of MIT is to advance knowledge and educate students in science, technology, and other areas of scholarship that will best serve the nation and the world in the 21st century.

The Institute is committed to generating, disseminating, and preserving knowledge, and to working with others to bring this knowledge to bear on the world's great challenges. MIT is dedicated to providing its students with an education that combines rigorous academic study and the excitement of discovery with the support and intellectual stimulation of a diverse campus community. We seek to develop in each member of the MIT community the ability and passion to work wisely, creatively, and effectively for the betterment of humankind.

The Massachusetts Institute of Technology - a coeducational, privately endowed research university - is dedicated to advancing knowledge and educating students in science, technology, and other areas of scholarship that will best serve the nation and the world in the 21st century. The Institute has more than 900 faculty and 10,000 undergraduate and graduate students. It is organized into five Schools - Architecture and Planning, Engineering, Humanities, Arts, and Social Sciences, Management, and Science - and the Whitaker College of Health Sciences and Technology. Within these are twenty-seven degree-granting departments, programs, and divisions. In addition, a great deal of research and teaching takes place in interdisciplinary programs, laboratories, and centers whose work extends beyond traditional departmental boundaries. The board of trustees, known as the Corporation, consists of about 75 national and international leaders in higher education, business and industry, science, engineering and other professions. Forty-seven alumni, faculty, researchers and staff have won Nobel Prizes.

William Barton Rogers, the Institute's founding President, believed that education should be both broad and useful, enabling students to participate in "the humane culture of the community" and to discover and apply knowledge for the benefit of society. His emphasis on "learning by doing," on combining liberal and professional education, and on the value of useful knowledge, continues to be at the heart of MIT's educational mission.

MIT's commitment to innovation has led to a host of scientific break-throughs and technological advances. Achievements of the Institute's faculty and graduates have included the first chemical synthesis of penicillin and vitamin A, the development of inertial guidance systems, modern technologies for artificial limbs, and the magnetic core memory that made possible the development of digital computers. Exciting current areas of research and education include neuroscience and the study of the brain and mind, bioengineering, the environment and sustainable development, information sciences and technology, new media, financial technology, and entrepreneurship.

University research is one of the mainsprings of growth in an economy increasingly defined by technology. In the first national study of the economic impact of a research university, "The Impact of Innovation," the BankBoston Economics Department found that graduates of MIT have founded 4,000 firms, translating their knowledge into products, services, and jobs. These firms, in 1994, employed over one million people and generated worldwide revenues of $232 billion.

MIT has forged educational and research collaborations with other universities, governments, and companies throughout the nation and the world, and draws its faculty and students from every corner of the globe. The result is a vigorous mix of people, ideas, and programs dedicated to enhancing the world's wellbeing.

Most (70 percent) of the research conducted on the MIT campus is supported by the US government, but the Institute is a national leader in the amount of such funding received from private industry (nearly 20 percent).


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  • From Massachusetts Institute of Technology
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