Too much of a good thing means that human activities overload ecosystems with nitrogen and while the resulting ecological damage is serious, but could be reduced by wider use of more sustainable, time-honoured practices
Humans are overloading ecosystems with nitrogen through the burning of fossil fuels and an increase in nitrogen-producing industrial and agricultural activities, according to a new study. While nitrogen is an element that is essential to life, it is an environmental scourge at high levels.
According to the study, excess nitrogen that is contributed by human activities pollutes fresh waters and coastal zones, and may contribute to climate change. Nevertheless, such ecological damage could be reduced by the adoption of time-honoured sustainable practices.
Appearing in the 8 October 2010 edition of Science and conducted by an international team of researchers, the study was partially funded by the National Science Foundation.
The nitrogen cycle
The nitrogen cycle – which has existed for billions of years – transforms non-biologically useful forms of nitrogen found in the atmosphere into various biologically useful forms of nitrogen that are needed by living things to create proteins, DNA and RNA, and by plants to grow and photosynthesise. The transformation of biologically useful forms of nitrogen to useful forms of nitrogen is known as nitrogen fixation.
Mostly mediated by bacteria that live in legume plant roots and soils, nitrogen fixation and other components of the nitrogen cycle weave and wind through the atmosphere, plants, subsurface plant roots, and soils; the nitrogen cycle involves many natural feedback relationships between plants and microorganisms.
According to the Science paper, since pre-biotic times, the nitrogen cycle has gone through several major phases. The cycle was initially controlled by slow volcanic processes and lightning and then by anaerobic organisms as biological activity started. By about 2.5 billion years ago, as molecular oxygen appeared on Earth, a linked suite of microbial processes evolved to form the modern nitrogen cycle.
Human impacts on the nitrogen cycle
However, the start of the 20th century, human contributions to the nitrogen cycle began skyrocketing. ‘In fact, no phenomenon has probably impacted the nitrogen cycle more than human inputs of nitrogen into the cycle in the last 2.5 billion years,’ says Rutgers University’s Paul Falkowski, a member of the research team.
‘Altogether, human activities currently contribute twice as much terrestrial nitrogen fixation as natural sources, and provide around 45% of the total biological useful nitrogen produced annually on Earth,’ says Falkowski. Much of the human contributions of nitrogen into ecosystems come from an 800% increase in the use of nitrogen fertilizers from 1960 to 2000.
Another problem: Much of nitrogen fertilizer that is used worldwide is applied inefficiently. As a result, about 60% of the nitrogen contained in applied fertilizer is never incorporated into plants and so is free to wash out of root zones, and then pollute rivers, lakes, aquifers and coastal areas through eutrophication. (Eutrophication is a process caused by excess nutrients that depletes oxygen in water bodies and ultimately leads to the death of animal life.)
In addition, some reactions involving nitrogen release nitrogen oxide into the atmosphere. Nitrogen oxide is a greenhouse gas that has 300 times (per molecule) the warming potential of carbon dioxide. In addition, nitrogen oxide destroys stratospheric ozone, which protects the earth from harmful ultraviolet (UV-B) radiation.
Methods to reduce nitrogen overloading
‘Natural feedbacks driven by microorganisms will likely produce a new steady-state over time scales of many decades,’ says Falkowski. ‘Through this steady state, excess nitrogen added from human sources will be removed at rates equivalent to rates of addition, without accumulating.’
Meanwhile, however, the Earth’s population is approaching 7 billion people, and so ongoing pressures for food production are continuing to increase. ‘There is no way to feed people without fixing huge amounts of nitrogen from the atmosphere, and that nitrogen is presently applied to crop plants very ineffectively.’ says Falkowski.
Therefore, unless promising interventions are taken, the damage done by humans to the Earth’s nitrogen cycle will persist for decades or centuries. These promising interventions, which would be designed to reduce the need to use fertilizers that add nitrogen to ecological systems, could include:
- •Using systematic crop rotations that would supply nitrogen that would otherwise be provided by fertilizers;
- •Optimising the timing and amounts of fertilizer applications, adopting selected breeding techniques or developing genetically engineered varieties of plants that would increase the efficiency of nitrogen use;
- •Using traditional breeding techniques to boost the ability of economically important varieties of wheat, barley and rye to interact favourably with the microbial communities associated with plant root systems and do so in ways that enhance the efficiency of nitrogen use.
‘While the processes of eutrophication have been recognised for many years, only recently have scientists been able to begin placing the anthropogenic processes in the context of an understanding of the broader biogeochemical cycles of the planet,’ says Robert Burnap, an NSF program director. This is an important article because it concisely develops this understanding and also provides reasonable predictions regarding the economic and policy dimensions of the problem.’
Source: National Science Foundation
caption: At Lake Atitlan in Guatemala, excess nitrogen promotes algae growth, which leads to eutrophication. Over-nourished by excess nutrients including nitrogen, which drains from nearby farms, swirls of blue-free algae form. The eventual decay of the algae robs the water of oxygen, and thereby creates a dead zone where other plants and animals cannot survive. (Image: NASA Earth Observatory image by Jesse Allen, based on data from the NASA/GSFC/METI/ERSDAC/JAROS, and U.S./Japan ASTER Science Team)