| February 11, 2004 Cities Built on Fertile Lands Affect Climate While cities provide vital habitat for human beings to thrive, it appears U.S. cities have been built on the most fertile soils, lessening contributions of these lands to Earth’s food web and human agriculture, according to a study by NASA researchers and others. Although cities account for just 3 percent of the continental U.S. land area, the loss of plant growth due to urban use roughly offsets the gain made by agricultural expansion. Marc Imhoff, NASA researcher and lead author of a current paper, and co-author Lahouari Bounoua, of NASA and University of Maryland, College Park, added that throughout history humans have settled in areas with the best lands for growing food. “Urbanization follows agriculture — it’s a natural and important human process,” said Imhoff.Throughout history, highly productive agricultural land brought food, wealth and trade to an area, all of which fostered settlements. “Urbanization is not a bad thing. It’s a very useful way for societies to get together and share resources,” said Bounoua. “But it would be better if it were planned in conjunction with other environmental factors.” Studies like this one, which appears in the current issue of Remote Sensing of Environment, may lead to smarter urban-growth strategies in the future. The researchers used two satellites offering a combination of daytime and nighttime Earth observation data and a biophysical computer model to derive estimates of annual Net Primary Productivity (NPP). NPP measures plant growth by describing the rate at which plants use carbon from the atmosphere to build new organic matter through photosynthesis. NPP fuels Earth’s complex food web and quantifies amounts of carbon dioxide, a greenhouse gas, which plants remove from the atmosphere. Nighttime-lights data from the Defense Meteorological Satellite Program and a vegetation-classification map created at NASA’s Goddard Institute of Space Studies, New York, were used to portray urban, peripheral and non-urban areas across the United States. In this way, the researchers calculated the extent and locations of U.S. urban and agricultural land. In addition, observations from the Advanced Very High Resolution Radiometer instrument, aboard the National Oceanic and Atmospheric Administration’s polar orbiting satellites, were used to calculate the Normalized Difference Vegetation Index. This index is a measure of plant health, based on the principle that plants absorb solar radiation in the red part of the spectrum of sunlight used for photosynthesis during plant growth. These data were then entered into a Stanford University computer model to derive NPP. The computer model created a potential pre-urban American landscape, which was used to compare and estimate the reduction of NPP due to current urban-land transformation. For the continental United States, when compared to the pre-urban landscape, modern cities account for a 1.6 percent annual decline in NPP. This loss offsets the gain in NPP of 1.8 percent annually from increased farmlands. The result is striking, given the small area that cities cover, relative to agricultural areas. A reduction of this magnitude has vastly unknown consequences for biological diversity, but it translates to less available energy for the species that make up Earth’s complex food web. The loss of highly fertile lands for farming also puts pressure on other means to meet the food and fiber needs of an increasing population. On the local scale, urbanization can increase NPP, but only where natural resources are limited. It brings water to arid areas, and “urban heat islands” extend the growing season around the urban fringe in cold regions. These benefits, however, do not offset the overall negative impact of urbanization on NPP. NASA scientists developed the city lights map, and the U.S. Geological Survey used a technique to create the Normalized Difference Vegetation Index data. Research partners include the University of Maryland’s Earth System Science Interdisciplinary Center, the World Wildlife Fund, and the Center for Conservation Biology at Stanford University. For more information and images on the Internet, visit:
http://www.gsfc.nasa.gov/topstory/2004/ 0202cityland.html For more information about NASA on the Internet, visit:
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Contacts: Elvia H. Thompson
Headquarters, Washington
(Phone: 202/358-1696) Krishna Ramanujan
Goddard Space Flight Center, Greenbelt, Md.
(Phone: 607/273-2561) | |
Comparing Post-Urban U.S. to Pre-Urban U.S., Difference in Total Annual Net Primary Production
This graphic compares modern U.S. annual Net Primary Production (NPP) to a computer-derived estimate of what the annual NPP would be in the absence of urbanization. The graphic shows areas with reductions or gains in NPP as a result of urban development. NPP measures plant growth by describing the rate at which plants use carbon from the atmosphere to build new organic matter through photosynthesis. Units are in grams of carbon per meter squared. Credit: Marc Imhoff/NASA 
U.S. Urbanization and Net Primary Production
a) The top map (shown in thumbnail) depicts urbanized areas across the continental U.S. The map was generated from nighttime satellite images from the Defense Meteorological Satellite’s Operational Linescan System (DMSP/OLS) collected from October 1994 to March 1995. Red indicates urban areas; yellow marks those smaller towns, and suburbs on the peripheries of cities, or peri-urban areas; and black represents non-urban or rural areas. b) The lower map (shown in full-size image) shows simulated total annual NPP for the U.S. at 1x 1km horizontal resolution. Units for NPP are in grams of carbon per square meter. Credit: Marc Imhoff/NASA 
Seasonal dynamics of the impact of urbanization on NPP for the Mid-Atlantic Region of the U.S.
These two graphs show how urbanization influences the seasonal dynamics of NPP in the Mid-Atlantic Region of the US. The Mid-Atlantic region defined here includes (New Jersey, Delaware, Maryland, Virginia, and North Carolina). NPP in urban areas is higher than non-urban areas in the cold months thereby extending the growing season. However, NPP in urban areas is greatly reduced during the warm months when compared to non-urbanized areas. The warm season reduction is more than enough to offset the cold season gains. a) The top graph (shown in thumbnail) shows monthly mean NPP rates for urban areas (diamonds, red), peri-urban (squares, yellow), and non-urban (triangles, green) areas. b) The lower graph (shown in full-size image) shows the differences between modern annual urbanized NPP rates and pre-urban NPP month by month. The graph depicts the losses (negative, red) or gains (positive, green) in NPP rates resulting from urbanization (urban - non-urban). Units for NPP are in grams of carbon per meter squared.
Bars represent ± 1 standard deviation. Credit: Marc Imhoff/NASA |
