Technology, traditionally seen as the enemy of the environment, is likely to be a positive environmental force in the 21st century. Not only will technology help feed
10 billion to 12 billion people, but it also is likely to be central to improving the overall quality of life, according to Thomas E. Graedel, professor at the School of Forestry and Environmental Studies.
Graedel, who teaches industrial ecology, is an expert in helping corporations find ways to bring new products to market with the least environmental stress. "The emerging field of industrial ecology, which sometimes is termed the science and technology of sustainability, focuses on development that is sustainable over the long term," Graedel said Feb. 13 at the annual meeting of the American Association for the Advancement of Science in Philadelphia.
"Industrial ecology is not merely some feel-good movement, but a vital necessity in this time of concern about pollution hazards and finite natural resources," he said. "Indeed, it serves as the paradigm around which much industrial design and development activity centers. The word 'ecology' implies that one should conserve and reuse resources of all kinds."
The industrial process has four central players: the materials extractor or grower, the materials processor or manufacturer, the user and the scavenger. To the extent that each encourages recycling of materials, the industrial process evolves into a more efficient operation that has less environmental impact and more closely resembles a balanced biological ecosystem, Graedel says.
He gave several examples of ways to design more efficient products and recover materials through recycling. He also advocated techniques that make it possible to upgrade rather than discard products. Specifically, he recommended:
* Dematerialization, a process in which lesser amounts of materials are used to make products that perform the same functions as their predecessors. An example is the integrated circuit, Graedel says, in which packing density has increased exponentially since 1960.
* Less energy intensity, which means adopting manufacturing processes that require less energy and contribute less carbon dioxide to the global warming problem. The recent trend is toward decreased energy on the production line. Lower energy costs can mean higher profits.
* Mining residues, a concept that emphasizes recovering materials from old products and recycling them instead of mining them. A good example is recovering silver after photographic processing, which accounts for half of all silver used today. Technological priorities in research and development need to be redirected toward a "reuse" perspective, Graedel says.
* Upgrading, not discarding, a philosophy in which companies are reverting to the earlier approach of making modular components that can be replaced when they wear out or become obsolete. Some laptop computer companies, for example, advertise replaceable keyboards, interchangeable screens and alternative disc drives.
* Finding the need, which means making innovative design changes that meet specific needs. Graedel cited the microwave oven, which did not fill the need for a better traditional oven, but for rapid and efficient cooking. Its characteristics are almost all environmentally attractive as well: low energy use, small size and reduced materials consumption during manufacturing.
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