Oct 1 2008
As a result of the Haber-Bosch process for synthesizing ammonia from atmospheric nitrogen, billions of people have been fed, millions have died in armed conflict and a cascade of environmental changes has been set in motion.
So suggests an article by scientists from four of the world's leading environmental research centers — including James Galloway, a University of Virginia professor of environmental sciences. The article will be published Tuesday in Nature Geoscience.
The article appears 100 years after Fritz Haber filed his patent on the "synthesis of ammonia from its elements" for which he was later awarded the 1918 Nobel Prize in Chemistry.
Lead author Jan Willem Erisman of the Energy Research Centre of the Netherlands said: "The increasing demand for food and biofuels makes efficient use of nitrogen fertilizer and more sustainable energy a challenge for many. [The] Haber-Bosch [process] is perhaps the most significant invention of the 20th century, yet it has many side effects. Now we need a new invention that changes the world just as much, but without the environmental impact."
The article describes a world transformed by, and highly dependent upon, Haber-Bosch nitrogen. This extra nitrogen has allowed large-scale production of explosives, leading to millions of casualties. On the other hand, it has created an enormous chemical industry that produces materials and goods for society.
The major impact, however, has been the large-scale production of fertilizers supporting almost half of the world's population through increased food production.
While the use of nitrogen as a fertilizer has brought enormous benefits, the loss of fertilizer nitrogen to the environment also has many side effects, including reduced biodiversity and the formation of marine algal blooms. Nitrogen compounds endanger the quality of drinking water and contribute to air pollution as well as climate change, affecting life quality and the health of large parts of the population.
Future scenarios suggest that such problems will become more extreme, with a potential doubling of fertilizer use predicted over the coming century. This demand is partly driven by the growing requirement for "nitrogen-hungry" biofuels. These environmental challenges highlight the need for a new invention, as transforming as the Haber-Bosch process that would benefit both society and the global environment.
The article concludes by arguing that today's society is dependent on a nitrogen-based economy and discusses some of the challenges we are likely to face in the next 100 years.
"Human ingenuity gave the world the ability to transform inert nitrogen gas into a commodity that supports food production for half of the world," U.Va.'s Galloway said. "It is now up to human ingenuity to insure that food production can occur without the cascade of damages due to nitrogen losses to the environment."
Galloway, founding chairman of the International Nitrogen Initiative and a co-winner of the 2008 Tyler Prize for environmental science, is a longtime contributor to the growing understanding of how nitrogen cycles endlessly through the environment.
The global nitrogen challenge is an issue that is set to receive more attention. The European Commission is funding the NitroEurope project, a consortium of more than 60 research institutions, to investigate the effect of nitrogen on global warming. Its results will feed into the work of the Task Force on Reactive Nitrogen, recently established by the United Nations Economic Commission for Europe.
Mark Sutton of the UK's Centre for Ecology & Hydrology, who is co-chairman of the UN task force and one of the feature's authors, commented: "It is remarkable how a century of Haber-Bosch nitrogen has transformed all our lives. Without it, half of us might not be alive today.
"At the same time, the environmental impacts of nitrogen cut across all global change issues. To reduce these effects, we must improve nitrogen use efficiency, especially in food production."
The research program of Erisman and colleagues at the Energy Research Centre of the Netherlands further highlights the role of bioenergy in the nitrogen cycle. They are developing second-generation technology for bioenergy and biofuels that will contribute to limiting fertilizer use in the future.