Technology

Published on September 15th, 2010 | by Earth Policy Institute

6

The Limits and Potential of Plant-Based Energy


By Lester R. Brown

As oil and natural gas reserves are being depleted, the world’s attention is increasingly turning to plant-based energy sources. These include food crops, forest industry byproducts, sugar industry byproducts, plantations of fast-growing trees, crop residues, and urban tree and yard wastes—all of which can be used for electrical generation, heating, or the production of automotive fuels.

The potential use of plant-based sources of energy is limited because even corn—the most efficient of the grain crops—can convert just 0.5 percent of solar energy into a usable form. In contrast, solar PV or solar thermal power plants convert roughly 15 percent of sunlight into a usable form, namely electricity. In a land-scarce world, energy crops cannot compete with solar electricity, much less with the far more land-efficient wind power.

Burning Plant-Based Materials for Heat & Power

In the forest products industry, including both sawmills and paper mills, waste has long been used to generate electricity. U.S. companies burn forest wastes both to produce process heat for their own use and to generate electricity for sale to local utilities. The 11,000 megawatts in U.S. plant-based electrical generation comes primarily from burning forest waste.

Wood waste is also widely used in urban areas for combined heat and power production, with the heat typically used in district heating systems. In Sweden, nearly half of all residential and commercial buildings are served with district heating systems. As recently as 1980, imported oil supplied over 90 percent of the heat for these systems, but by 2007 oil had been largely replaced by wood chips and urban waste.

In the United States, St. Paul, Minnesota—a city of 275,000 people—began to develop district heating more than 20 years ago. It built a combined heat and power plant to use tree waste from the city’s parks, industrial wood waste, and wood from other sources. The plant, using 250,000 tons or more of waste wood per year, now supplies district heating to some 80 percent of the downtown area. This shift to wood waste largely replaced coal, thus simultaneously cutting carbon emissions by 76,000 tons per year and providing a sustainable source of heat and electricity.

The sugar industry recently has begun to burn cane waste to cogenerate heat and power. This received a big boost in Brazil, when companies with cane-based ethanol distilleries realized that burning bagasse, the fibrous material left after the sugar syrup is extracted, could simultaneously produce heat for their fermentation process and generate electricity that they could sell to the local utility. This system, now well established, is spreading to sugar mills in other countries.

Within cities, garbage is also burned to produce heat and power after, it is hoped, any recyclable materials have been removed. In Europe, waste-to-energy plants supply 20 million consumers with heat. France, with 128 plants, and Germany, with 67 plants, are the European leaders. In the United States, some 89 waste-to-energy plants convert 20 million tons of waste into power for 6 million consumers. It would, however, be preferable to work toward a zero-garbage economy where the energy invested in combustible materials could largely be recovered by recycling.

Until we get zero waste, the methane (natural gas) produced in existing landfills as organic materials in buried garbage decompose can also be tapped to produce industrial process heat or to generate electricity in combined heat and power plants. The 35-megawatt landfill-gas power plant planned by Puget Sound Energy and slated to draw methane from Seattle’s landfill will join more than 100 other such power plants in operation in the United States.

Near Atlanta, Interface—the world’s largest manufacturer of industrial carpet—convinced the city to invest $3 million in capturing methane from the municipal landfill and to build a nine-mile pipeline to an Interface factory. The natural gas in this pipeline, priced 30 percent below the world market price, meets 20 percent of the factory’s needs. The landfill is projected to supply methane for 40 years, earning the city $35 million on its original investment while reducing costs for Interface.

Plant-Based Fuels: More Cost than Opportunity?

Crops are also used to produce automotive fuels. In 2009 the world produced 19 billion gallons of fuel ethanol and 4 billion gallons of biodiesel. Half of the ethanol came from the United States, a third from Brazil, and the remainder from a dozen or so other countries, led by China, Canada, and France. Germany and France are responsible for a combined 30 percent of the world’s biodiesel output; the other major producers are the United States, Argentina, Brazil, Spain, and Italy.

Once widely heralded as the alternative to oil, crop-based fuels have come under closer scrutiny in recent years, raising serious doubts about their feasibility. In the United States, which surged ahead of Brazil in ethanol production in 2005, the near doubling of output during 2007 and 2008 helped to drive world food prices to all-time highs. In Europe, with its high goals for biodiesel use and low potential for expanding oilseed production, biodiesel refiners are turning to palm oil from Malaysia and Indonesia, driving the clearing of rainforests for palm plantations.

Corn being harvested for conversion into ethanol

In a world that no longer has excess cropland capacity, every acre planted in corn for ethanol means another acre must be cleared somewhere for crop production. An early 2008 study led by Tim Searchinger of Princeton University that was published in Science showed that when including the land clearing in the tropics, expanding U.S. biofuel production increased annual greenhouse gas emissions dramatically instead of reducing them, as more narrowly based studies claimed.

Another study published in Science, this one by a team from the University of Minnesota, reached a similar conclusion. Focusing on the carbon emissions associated with tropical deforestation, it showed that converting rainforests or grasslands to corn, soybean, or palm oil biofuel production led to a carbon emissions increase—a “biofuel carbon debt”—that was at least 37 times greater than the annual reduction in greenhouse gases resulting from the shift from fossil fuels to biofuels.

The case for crop-based biofuels was further undermined when a team led by Paul Crutzen, a Nobel Prize–winning chemist at the Max Planck Institute for Chemistry in Germany, concluded that emissions of nitrous oxide, a potent greenhouse gas, from the synthetic nitrogen fertilizer used to grow crops such as corn and rapeseed for biofuel production can negate any net reductions of CO2 emissions from replacing fossil fuels with biofuels, thus making biofuels a threat to climate stability. Although the U.S. ethanol industry rejected these findings, the results were confirmed in a 2009 report from the International Council for Science, a worldwide federation of scientific associations.

The more research is done on liquid biofuels, the less attractive they become. Fuel ethanol production today relies almost entirely on sugar and starch feedstocks, but work is now under way to develop efficient technologies to convert cellulosic materials into ethanol. Several studies indicate that switchgrass and hybrid poplars could produce relatively high ethanol yields on marginal lands, but there is no low-cost technology for converting cellulose into ethanol today or in immediate prospect.

A third report published in Science indicates that burning cellulosic crops directly to generate electricity to power electric cars yields 81 percent more transport miles than converting the crops into liquid fuel. The question is how much could plant materials contribute to the world’s energy supply. Based on a study from the U.S. Departments of Energy and Agriculture, we estimate that using forest and urban wood waste, as well as some perennial crops such as switchgrass and fast-growing trees on nonagricultural land, the United States could develop more than 40 gigawatts of electrical generating capacity by 2020 (1 gigawatt = 1,000 megawatts). For the global Plan B, we estimate that worldwide, biomass could quadruple to contribute 200 gigawatts of capacity by 2020, playing a relatively small yet important role in the new energy economy.


Adapted from Chapter 5, “Stabilizing Climate: Shifting to Renewable Energy” in Lester R. Brown, Plan B 4.0: Mobilizing to Save Civilization (New York: W.W. Norton & Company, 2009), available on-line at www.earthpolicy.org/index.php?/books/pb4

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Photo credit: KOMUnews at Flickr under a Creative Commons license



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  • http://www.zerowasteeurope.eu JM

    You say: “Within cities, garbage is also burned to produce heat and power after, it is hoped, any recyclable materials have been removed.”. Well, sadly studies prove that more than 50% of the waste burnt in Europe is recyclable and that those countries that burn more waste they also happen to be generating more waste than those who burn less.

    I think that if you really want to promote sustainability you should refrain from supporting burning waste. Burning limited resources to extract a tiny portion of the energy that was involved its production process clashes with the very definition of sustainability you claim to defend.

  • http://www.stopspewingcarbon.org Meg Sheehan

    It’s quite shocking to see you promoting burning garbage and landfill gas as a pathway to a sustainable future. Do you realize that billions of taxpayer and ratepayer dollars that go into subsidizing burning this stuff? And that we ratepayers and taxpayers are footing the bill, since burning it qualifies for lucrative “renewable energy credits” in the “renewable portfolio standards” of almost 43 states?

    The big waste management companies that own and operate landfills and garbage incinerators make millions, and promoting them totally undermines the need to reduce, reuse and recycle. Where’s the industry incentive when they get paid billions to burn our garbage or bury in in landfills to make “waste to energy” methane!

    Please study the facts, Mr. Brown. I’ve been an admirer of yours since my sustainable economics class at Colgate University in the 1970s – I hope you’ll revise your position.

  • Denny Haldeman

    Lester…
    I’ve long been a fan of Worldwatch Institute and your work. However, it seems that groups like yours tend to get excruciatingly focused on certain aspects of “solutions” out of context with many pieces of the larger picture.

    Waste to energy schemes are defacto recyling killers, large sources of C02 emissions compared to recycling, and do not reflect the true costs of ash disposal, toxic emissions, and resource destruction by killing recycling intitiatives. Incinerators cannot function without the recyclable materials.

    When gourps like yours hype cellulosic fuels for power you neglect to address the declining soil fertility, depth, and health, soil carbon oxidation, loss of soil sequestration ability from repeated removals, and the consequences of using “marginal lands”, aka Conservation Reserve Program lands that are currently in reserve to protect biodiversity and habitat, water quality, and much highly erodable land from exploitation.

    There is no way to replace our current fossil fuel carbon demands with the annual growth of carbon sequestering plants without massive deforestation, replacement of native forests with yet more chemically dependent plantations, exacerbating already alarming rates of soil loss and nutrients, and conversion of critical food productive lands to short term biomass production doomed to play the soils out within decades.

    The carbon bomb of such actions is far from any sort of signifcant solution. It’s much like the “10% solution” of putting enough recycled content into a product to get the “green” seal thereby encouraging consumers to keep on consuming guilt free like there’s no tomorrow…which there will be if these schemes gain widespread acceptance.

    To embrace these earth liquidation sale schemes is counter-productive to us facing the reality that given our numbers and consumption levels, there is no other option available to humankind but to make difficult, needed transitions away from consumer culture, de-globalize economies to economies of scale, use less, be far more efficient, maximize conservation and evolve into the post-carbon world.

  • Ruth Duemler

    You ignored the health effects of biomass. The American Lung Association has come out against biomass and I’m sure that includes incinerators. Pollution from biomass and incinerators should not be downwind of population centers. Our Lane County Health Advisory Committee studied the health effects and recommended against biomass burning.

  • http://www.energyjustice.net RMida

    Here’s some light reading for you Lester to get more acquainted with the downsides to Biomass Energy, or see our Biomass Fact Sheet.

    Also see our relevant pages on Landfill Gas, Incineration , and Biofuels.

  • Pingback: Chapter 4, Lester Brown's Full Planet, Empty Plates | Sustainablog()

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