Fight climate change on two fronts.Byline: Bob Doppelt For The Register-Guard Can we solve global warming global warming, the gradual increase of the temperature of the earth's lower atmosphere as a result of the increase in greenhouse gases since the Industrial Revolution. ? Will solutions require reverting to the Stone Age? Some warming is now inevitable. To avoid severe climate change - which economists believe would trigger a Great Depression magnitude drop in gross domestic product - and to eventually allow the climate to restabilize, scientists say global emissions must level off by 2015 and be reduced by about 80 percent or more by mid-century. We need to cut emissions by about 2 percent a year for the next 42 years. Although success will require big shifts in thinking, behavior and energy systems, numerous assessments show that it is possible to reduce emissions by 80 percent if we act quickly. Dramatically increased energy efficiency and use of renewable energy Renewable energy utilizes natural resources such as sunlight, wind, tides and geothermal heat, which are naturally replenished. Renewable energy technologies range from solar power, wind power, and hydroelectricity to biomass and biofuels for transportation. are two core elements of a winning strategy. The United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. produces the least output from the energy it consumes of any industrialized in·dus·tri·al·ize v. in·dus·tri·al·ized, in·dus·tri·al·iz·ing, in·dus·tri·al·iz·es v.tr. 1. To develop industry in (a country or society, for example). 2. country. As a result, we are the most carbon dioxide-intensive nation, producing twice the emissions levels of northern Europe and Japan. Just through business-as-usual efficiency improvements, the United States produces about 1 percent more GDP GDP (guanosine diphosphate): see guanine. annually per watt of energy consumed than the previous year. But greater gains have been achieved. The early 1980s oil shock triggered efficiency improvements averaging 3.4 percent. Through tough standards for appliances and buildings, etc., since the mid-1970s California essentially has been able to hold per capita [Latin, By the heads or polls.] A term used in the Descent and Distribution of the estate of one who dies without a will. It means to share and share alike according to the number of individuals. energy use constant while per capita use nationwide rose by nearly 50 percent. California's economy seems to have done just fine, thank you, despite these requirements. When Americans are motivated, the amount of energy wasted through inefficient design, construction, maintenance and use of buildings, industrial processes and vehicles can be reduced substantially. In fact, a study by American Solar Energy Society The American Solar Energy Society (ASES) is dedicated to advancing the U.S. toward a sustainable energy economy. ASES publishes Solar Today magazine, organizes the National Solar Tour, produces the National Solar Energy Conference, and advocates for policies to promote the research found that about 57 percent of the carbon displacement needed over the next decades could be achieved through increased efficiency. Every utility, government and business should thus kick into high gear programs to acquire every watt of efficiency possible. This is the fastest and cheapest way to achieve the goal of leveling off emissions by 2015. Ironically, the savings produced by increased efficiency often lead people to use more energy. Per capita use falls while aggregate use rises. For efficiency actually to reduce emissions, a cap must be established that limits and systematically reduces the amount of carbon emitted annually. The second core element of a victorious emission reduction strategy is likely to be a shift to the use of electricity produced with renewable energy. Buildings, machinery and eventually vehicles can be powered electrically. Wind and solar energy solar energy, any form of energy radiated by the sun, including light, radio waves, and X rays, although the term usually refers to the visible light of the sun. - including solar photovoltaics, solar hot water Solar hot water refers to water heated by solar energy. Solar heating systems are generally composed of solar thermal collectors, a fluid system to move the heat from the collector to its point of usage, and a reservoir or tank for heat storage and subsequent use. heating and solar thermal power plants - have the theoretical potential to supply all the energy the nation needs. Wave power, biomass, non-food based biofuels and other renewables, if and when they become commercially viable, would add even more supply. Renewables, however, have constraints. Solar doesn't produce power at night, for instance, and the best locations for wind power often are far from major population areas. Many of these issues are being resolved or will be fixed in the coming decades. Costs also are a factor, but they are rapidly dropping as these industries get to scale. Tax incentives and payments for power from utilities already make solar economically viable for many Oregon businesses. The potential of renewables should not be underestimated. A new report by the Renewable Energy Network for the 21st Century projects that by 2030, renewables could provide about 40 percent of U.S. energy needs after efficiency is taken into account. This finding suggests that energy efficiency and renewables combined have the potential to provide most, if not all of the reductions needed to achieve the 80 percent goal. Could Eugene meet its energy needs though efficiency and solar power? A back-of-the-envelope calculation The phrase back-of-the-envelope calculations (abbreviated "BotEC") refers to rough calculations that, while not rigorous, test or support a point. They are far more than a guess but far less than a proof. The phrase is generally used in mathematics, physics and engineering. shows that the Eugene Water & Electric Board would need to cover 263.3 million square feet, or just 4 percent of its service area, with solar panels to power Eugene with solar energy. Ray Neff Dr. Ray Neff a retired health sciences professor at Indiana State University with a chemistry background is a leading proponent of an alternative history theory about the assassination of Abraham Lincoln and his killer John Wilkes Booth. , one of my graduate students, calculates that more than four times this much space would be available if solar systems were installed on the rooftops of commercial buildings in west Eugene, almost all of which have good solar access, plus the Valley River Center Valley River Center is a shopping mall located in Eugene, Oregon. As the largest shopping center south of Portland and north of San Francisco, this mall comprises over 130 local and national stores and restaurants. , the fairgrounds n. pl. 1. same as fairground. and the Autzen Stadium The stadium is tucked between the Willamette River and Coburg Hills. The uniquely shaped bowl blends in with the wooded Eugene landscape. The shape also allows for unique acoustics, making it one of the loudest stadiums in NCAA Football for its capacity. parking lots. I'm not suggesting that Eugene or any other community immediately shift to full solar, although the notion should not be discounted. A different mix of renewables may make more sense in the future. Additional solar and other renewables also will be needed to power local transportation. My point is that options currently are or likely will soon exist to move major portions of the economy toward the 80 percent reduction target. So, global warming is solvable. Climate solutions will not be without costs. But success will avoid Depression-era size impacts, while creating thousands of jobs and in other ways leaving all of us better off. We need leadership that speaks the truth about the climate tsunami roaring toward us, along with aggressive policies to bring about a sustainable energy future. <hr noshade size="1"> Bob Doppelt (bob-cwch@att.net), director of resource innovations and the Climate Leadership Initiative at the University of Oregon The University of Oregon is a public university located in Eugene, Oregon. The university was founded in 1876, graduating its first class two years later. The University of Oregon is one of 60 members of the Association of American Universities. , is writing a series of columns on climate change for The Register-Guard. |
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