What amazes many environmental advocates to this day is how the widespread adoption of synthetic chemical pesticides, herbicides and fertilizers for use in agriculture was dubbed the ¡°Green Revolution,¡± when in fact this post-World War II paradigm shift in the way we produce food has wreaked untold havoc on the environment, food quality and human health.
Agricultural output has certainly increased as a result of these changes, but with the vast majority of the world¡¯s farms now relying on petroleum-derived synthetic chemicals to grow crops and petroleum-derived fuels to drive the engines of production¡ªmodern agriculture has become overwhelmingly toxic to the atmosphere and is hastening global warming. The Intergovernmental Panel on Climate Change (IPCC) reports that agricultural land use contributes 12 percent of global greenhouse gas emissions; here in the U.S. almost 20 percent of our carbon dioxide emissions come from agricultural sources.
Intensive use of chemicals isn¡¯t good for our nutrition intake, either. Overworked, depleted agricultural soils generate fruits and vegetables with fewer nutrients and minerals than those produced by farmers decades ago. And much of the food we eat is laced with chemicals that end up in our bloodstreams.
Beyond its effect on the food we put in our bodies, modern agriculture generates large amounts of nitrogen, phosphorous and other fertilizers running off into our streams, rivers and oceans, compromising not only the quality of our drinking water and the health of riparian ecosystems, but also causing those huge oxygen-depleted ocean dead zones we hear about in coastal areas such as the Gulf of Mexico.
Yet another issue with modern farming is the amount of animal waste generated and concentrated in small areas, which creates unsanitary and potentially dangerous conditions for the animals and humans alike. And the widespread use of antibiotics on farm animals to keep disease in check results in the development of stronger strains of bacteria that resist the antibiotics used by humans to ward off infection and sickness.
Also, many worry about the potential impacts of the widespread use of genetic engineering, whereby genes in plants, animals and microorganisms are manipulated to select for specific traits. These genetically modified organisms, reports Greenpeace, ¡°can spread through nature and interbreed with natural organisms,¡± thus contaminating the natural environment in unforeseeable and uncontrollable ways.
The good news is that rapidly increasing consumer demand for healthier food is forcing agribusiness to see the wisdom of moving away from business-as-usual. Organic farming, which eschews chemical fertilizers and pesticides in favor of more natural choices, holds considerable promise for greening up our agricultural systems. According to the U.S. Department of Agriculture, organic cropland acreage averaged 15 percent increases between 2002 and 2008, although certified organic cropland and pasture accounted for only about 0.6 percent of U.S. total farmland in 2008. So we still have along way to go.
CONTACTS: IPCC, www.ipcc.ch; USDA, www.ers.usda.gov/Data/Organic.
Dear EarthTalk: Why can¡¯t plastics of all types, instead of being initially sorted, simply be melted together to be separated later? It must be a monumental and error-prone task to separate truckloads of plastics.
-- L. Schand, via e-mail
The reason plastics aren¡¯t typically melted together and then separated later is a matter of both physics and economics. When any of the seven common types of plastic resins are melted together, they tend to separate and then set in layers. The resulting blended plastic is structurally weak and difficult to manipulate. While the layered plastic could in theory be melted again and separated into its constituent resins, the energy inputs required to do so would make such a process cost prohibitive.
As a result, recycling facilities sort their plastics first and then melt them down only with other items made of the same type of resin. While this process is labor-intensive, the recycling numbers on the bottom of many plastic items make for quicker sorting. Many recycling operations are not only reducing sizable amounts of waste from going into landfills but are also profitable if managed correctly.
Manufacturers of plastic items choose specific resins for different applications. Recycling like items together means the reclaimed polymer can be used to create new items just like their virgin plastic forebears. The seven common types of plastic are: #1 Polyethylene terephthalate (PET or PETE); #2 High-density polyethylene (HDPE); #3 Polyvinyl chloride (PVC); #4 Low-density polyethylene (LDPE); #5 Polypropylene (PP); #6 Polystyrene (PS); and #7 Other/Mixed (O). One complicating factor is trying to recycle unmarked plastics and those embossed with a #7 (representing mixed resins, also known as polycarbonate). According to Earth911, a leading online source for finding recyclers for specific types of items across the United States, in some cases #7 plastics can be ¡°down-cycled¡± into non-renewable resin; in other cases recycling operations just send their unmarked and #7 plastics into local landfills.
But even though recycling operations have developed relatively efficient systems for generating reclaimed resins, many environmentalists recommend that consumers still avoid plastics as much as possible. ¡°Simply recycling these products does not negate the environmental damage done when the resource is extracted or when the product is manufactured,¡± reports EcoCycle, a Colorado-based non-profit recycler with an international reputation as an innovator in resource conservation. The group adds that over the past half century, the use of disposable packaging¡ªespecially plastic¡ªhas increased by more than 10,000 percent.
Along these lines, products (or packaging) made out of reusable metal, glass or even wood are preferable to equivalent items made from plastic. For starters, an item of metal, glass or wood can be re-used by someone else or recycled much more efficiently than plastic when it does reach the end of its useful life to you. Wood products and other items crafted out of plant material¡ªeven so-called ¡°polylactic acid (PLA) plastic¡± made from plant-based agricultural wastes¡ªcan be composted along with your yard waste and food scraps, either in your backyard or, if your town or city offers it, through your municipal collection system. Happy reducing, reusing and recycling!
CONTACTS: Earth911, www.earth911.com; EcoCycle, www.ecocycle.org.
Dear EarthTalk: Why don¡¯t we reprocess and re-use our nuclear waste like France does? Would it be possible for us to start doing so?
-- Albert Jukowsky, Silver Spring, Md.
Reprocessing nuclear waste to extract more energy from it, while expensive and controversial, is indeed to this day still practiced in France, the UK, Russia, India and Japan¡ªbut not in the United States, where it was invented. The process involves breaking down spent nuclear fuel chemically and recovering fissionable material for use in new fuels. Proponents tout the benefit of reducing the amount of nuclear waste, resulting in less highly radioactive material that needs to be stored safely.
Nuclear reprocessing was first developed in the U.S. as part of the World War II-era Manhattan Project to create the first atomic bomb. After the war, the embryonic nuclear power industry began work to reprocess its waste on a large scale to extend the useful life of uranium, a scarce resource at the time. But commercial reprocessing attempts faltered due to technical, economic and regulatory problems. Anti-nuclear sentiment and the fear of nuclear proliferation in the 1970s led President Jimmy Carter to terminate federal support for further development of commercial reprocessing. The military did continue to reprocess nuclear waste for defense purposes, though, until the collapse of the Soviet Union and the end of the Cold War made continuous ramping up of our nuclear arsenal unnecessary.
More recently, George W. Bush pushed a plan, the Global Nuclear Energy Project (GNEP), to promote the use of nuclear power and subsidize the development of a new generation of ¡°proliferation-resistant¡± nuclear reprocessing technologies that could be rolled out to the commercial nuclear energy sector. Federal scientists came up with promising spins on reprocessing nuclear fuel while minimizing the resulting waste. But in June of 2009 the Obama administration cancelled GNEP, citing cost concerns.
Proponents of nuclear power¡ªand of reprocessing in particular¡ªwere far from pleased with GNEP¡¯s axing, especially in light of Obama¡¯s earlier decision to close Yucca Mountain as the U.S.¡¯s future nuclear waste repository. ¡°GNEP may have gone away, but the need to recycle spent fuel in this country is more important than ever because of the government¡¯s stupid decision to close Yucca Mountain,¡± said Danny Black of the Southern Carolina Alliance, a regional economic development group, on the Ecopolitology blog. ¡°Without Yucca Mountain, the pressure is on the industry to do more with recycling.¡±
But a 2007 report by the nonprofit Institute for Energy and Environmental Research (IEER) would seem to justify Obama¡¯s decision. IEER found that nuclear reprocessing would actually increase our volume of nuclear waste six fold. IEER also reported that France, which runs the world¡¯s most efficient reprocessing operation, spends about two cents per kilowatt hour more for electricity generated from reprocessed nuclear fuel compared to that generated from fresh fuel. IEEE further reports that the costs to build the breeder plants needed to convert spent nukes into usable fuel would ¡°create intolerable costs and risks.¡±
For now, U.S. nuclear plants will continue to store waste on site, with spent rods cooled in pools of water for upwards of a year and then moved into thick steel and concrete caskets. While proliferation and terrorism have long been risks associated with hosting nuclear plants on American soil, recent events in Japan underscores that even Mother Nature poses a threat. As such, advocates of reprocessing probably stand little chance of reviving plans in a political climate now so hostile to nuclear development.
CONTACTS: Ecopolitology, www.ecopolitology.org; IEER, www.ieer.org.
Dear EarthTalk: I understand that fast-food giant YUM! Brands, owner of KFC, is under fire by Greenpeace and others for rainforest destruction. What¡¯s the story?
-- Betsy Barnard, Wellesley, Mass.
YUM! Brands, which operates 38,000 fast food restaurants in 110 countries (including not only KFC but also Pizza Hut, Taco Bell, WingStreet, A&W and Long John Silver¡¯s), has come under fire of late from Greenpeace and other rainforest advocacy groups for sourcing palm oil, paper and other goods from suppliers notorious for destroying tropical rainforests in Indonesia and elsewhere. While McDonald¡¯s and Burger King have worked in recent years to cut their ties with palm oil and logging companies linked to rainforest destruction,
