# 1-6: Nitrogen Cycle, Sulfur Cycle; Tropospheric Ozone

1-6: En Español 1-6: Em Português
Eugene S. Takle

Nitrous Oxide

Nitrous Oxide

In this unit we examine another trace gas in the atmosphere whose concentrations are observed to be increasing. Nitrous oxide, $N$2O, is a colorless, odorless, non-reactive gas that is very stable in the troposphere (lifetime of 110-168 years). It should not be confused with $NO$2, NO, or other oxides of nitrogen. Nitrous oxide concentrations have been steadily increasing with time, as shown in Figure 1a which reports measurements at several locations since 1977. It is important to note that the units of these measurements are parts per billion by volume (ppbv). Nitrous oxide concentrations then are about one fifth of methane concentrations and about a thousand times smaller than carbon dioxide.

Data over a longer time scale as derived from ice cores show that over the last 2,000 years nitrous oxide concentrations were nearly constant at about 280 ppbv until about the beginning of the Industrial Revolution, at which time there began a fairly dramatic increase which continues today at about 0.2 to 0.3% per year.

Sources of Nitrous Oxide

Sources of Nitrous Oxide

We know the sources of nitrous oxide. Natural sources include oceans, tropical soils, wet forests, dry savannas, and extra-tropical forests. Total emissions are about 4-10 x 1012 grams, or 4-10 Tg. Anthropogenic sources include cultivated soils (including use of nitrogen fertilizers), biomass burning and other combustion processes, and acid production processes. The largest known process for destruction of nitrous oxide is stratospheric photolysis (breakdown by solar energy, principally ultraviolet radiation). From these estimates (Figure 2) we can see that in spite of large uncertainty, human contributions to the nitrous oxide loading of the atmosphere are comparable with natural sources and are likely the cause of the 3-4.5 Tg per year increase in the amount of nitrous oxide in the atmosphere. Because of their long lifetime (stability) in the troposphere, natural removal processes are incapable stemming this increase.

Agricultural use of nitrogen fertilizer is a significant anthropogenic source of nitrous oxide. As shown in Figure 3, China is a big user, followed (according to these data) by the former Soviet Union, the United States, and India. During talks with state officials on my recent trip to Russia, I learned that the present economic difficulties in that country have significantly reduced their availability of fertilizers and pesticides, so this chart may not reflect current conditions.

In a later summary information we will be coming back to the physics and chemistry of the stratosphere and will revisit the problems caused by nitrous oxide in the stratosphere.

Other Oxides of Nitrogen

Other Oxides of Nitrogen

Other oxides of nitrogen also are being added to the atmosphere in increased amounts. Anthropogenic emissions of nitrogen compounds in the US, as reported by EPA, are shown in Figure 4.

NO and $NO$2 are gases are collectively taken together with $NO$3 aerosol to comprise what we call $NO$X. Annual $NO$X emissions in the US over the last 80 years have increased dramatically, from less than 1 to about 22 Tg (teragrams, or millions of metric tons). On a global basis natural sources of $NO$X include soils (5-20 Tg annually) and lightning (2-20 Tg annually) and give an annual total amount of 8 to 41 Tg. Anthropogenic sources contribute annually about 27 to 38 Tg from fossil fuel combustion, biomass burning, and tropospheric aircraft. These numbers suggest that humans are emitting oxides of nitrogen to the atmosphere in total annual amounts that are comparable in magnitude to natural sources (Figure 5).

Nitrogen Cycle

Nitrogen Cycle

In order to understand how nitrogen moves throughout the earth/ocean/atmosphere environment, we need to look at the nitrogen cycle, which gives the sources and sinks of nitrogen and the fluxes between these reservoirs, as shown in Figure 6. These values may be subject to large errors and are for illustration only. The main concept to draw from this figure is that there are two components of the nitrogen cycle: the right hand side represents tropospheric interactions and interchange with the surface for $NO$X, and the left hand side describes nitrous oxide, which is considered separately. The components on the right hand side are all part of the rapid cycle: being quite reactive, these constituents will cycle into and out of the lower atmosphere within a couple weeks. But, of course, since we continue to put in more all the time, there is this continuous supply in the atmosphere. However, if we were able to switch off all of natural and anthropogenic sources, the atmospheric concentrations of these molecules would rapidly deplete to zero within a couple of weeks.

Also shown are the different pathways and transformations throughout these various cycles. So, for instance, some nitrogen enters the atmosphere as NO, is transformed to $NO$2, and then may go back into the soils as $NO$2 or it may be converted to $NO$3 in an aerosol and then be rained out or deposited out as a dry particle. The gas may form into particles directly or attach to rain droplets and eventually end up back in the soil or in the ocean. A similar description applies to the various transformations of ammonia ($NH$3).

Nitrous oxide, on the other hand, follows a different pathway: it experiences no chemical transformation or rainout or dry deposition in the troposphere. Once emitted, the nitrous oxide molecule drifts throughout the lower atmosphere, possibly for decades, until it makes a chance visit to the lower stratosphere where it is broken down by ultraviolet light into O and N or NO. The Ns can form $N$2, but the NO is available to participate in ozone depletion. The point of Figure 7 is that, of the nitrogen compounds emitted at the surface by natural or anthropogenic process, only nitrous oxide lives long enough to migrate to the stratosphere to create problems at that level. Oxides of nitrogen in the lower atmosphere cause acid rain problems, as we will see later, but they do not contribute significantly to global warming or ozone depletion.

There are several unanswered questions relating to nitrogen movement through the biosphere, atmosphere and soil. These questions are being addressed through intensive research on biogeochemicals in the lower troposphere.

Nitrogen is one of the primary soil nutrients needed by plants, and in some (particularly agricultural) ecosystems it is a limiting factor for vigorous plant growth. As nitrogen in the form of nitrates or ammonia is deposited on the soil from anthropogenic releases, the excess nitrogen will be taken up by plants until the natural removal rate is reached. Different land use categories (plant types) have different capacities for removing nitrogen. For instance, boreal forests can remove about 15 kg/ha/y whereas arable farm land or rich pasture can remove 40 kg/ha/y or more.

A recent research summary by Anne Simon Moffat (Science 279, 988-989) points out the critical nature of a global overload of nitrogen compounds. Fixed nitrogen (ammonia, nitrogen oxides) is beginning to overwhelm a wide range of forest, lake, river, and coastal ecosystems. One "ecological service" of natural ecosystems is to absorb or breakdown these compounds, but the increased volume of nitrogen compounds is increasingly overwhelming these natural systems.

Sources of Excess Nitrogen

Sources of Excess Nitrogen

Sources of the excess nitrogen include increased use of nitrogen fertilizer and nitrates produced from fossil fuel combustion. It is estimated that humans produce 60% of the fixed nitrogen deposited on land each year, which is far more than can be absorbed by agricultural and natural ecosystems. These changes reduce biological diversity by preferential growth and possible ecosystem takeover by species that thrive in high nitrogen levels.

Nitrogen that is not used by plants may be immobilized in the soil by mineralization or other processes that prevent its translocation. Nitrogen that is not used by plants or immobilized in place will contribute to leaching - loss of nitrogen to ground water or surface water.

Sulfur Emissions

Sulfur Emissions

Sulfur emissions to the atmosphere in the US due to anthropogenic sources have also increased, as was shown in Figure 8. Emissions of sulfur per year from 1860 to 1980 in the US have risen from about 10 Tg to a peak of about 32 Tg in 1970. Environmental regulations have reduced these emissions substantially in recent years in the US and many developed countries that can afford to install sulfur emissions abatement equipment. Developing countries experiencing rapid growth or that use high-sulfur coal and low-technology combustion equipment are contributing to growing emissions.

The main global source of anthropogenic sulfur is burning of high-sulfur coal, which contributes 70-80 Tg of sulfur per year, mostly in the form of sulfur dioxide ($SO$2). Biomass burning contributes 0 .8 to 2.5 Tg to the global total. Natural sources include ocean production of dimethyl sulfide (DMS), soil and plant production of DMS and hydrogen sulfide ($H$2S). Volcanoes, which of course are episodic sources, may contribute 7 to 10 Tg annually. Figure 9 clearly shows that anthropogenic emissions now dominate natural sources of sulfur in the atmosphere.

Sulfur compounds, like $SO$2 , are short-lived species in the atmosphere that are subject to chemical transformation, washout, and dry deposition and lead to acid precipitation problems. SO2 is a gas that condences to particulate SO4 within a few hours after being emitted into the atmoshpere. We know of sulfur dioxide as a pollutant because it reacts with water ($H$2O) to form sulfuric acid ($H$2SO4). If we were able to switch off all the power plants and other anthropogenic as well as natural sources of sulfur, we could eliminate most of the sulfur from the atmosphere in a couple of weeks.

Sulfur Cycle

Sulfur Cycle

The sulfur cycle (Figure 10) can be divided into a cycle over water and a cycle over land. In comparison with the nitrogen cycle, we notice immediately that the sulfur cycle has no connection to the stratosphere, since there are no long-lived species of sulfur. Sulfur, of course, is a problem in the troposphere as an air pollutant. We will come back to this in a future unit.

Figure 11 shows a simulation of sulfate ($SO$4) concentrations in the lower atmosphere (at a level of 900 hectopascals, which is about a kilometer above the earth's surface) over the earth. The numbers plotted are dimensionless ratios of total concentration of anthropogenic plus natural sulfate divided by the concentration based on natural emissions. Highly populated and industrial areas of the eastern part of the U.S. and eastern Europe have highest concentrations. Concentrations over Asia are increasing, particularly in the industrial area of southeast China. Of course, as the Chinese industrialization rapidly increases, this problem is likely to increase.

A recent finding, and one that has put environmentalists in a perplexing dilemma, is that there also is a secondary effect of sulfur dioxide in the earth's atmosphere. Although it is not a greenhouse gas, it does contribute to the radiation balance of the earth. In the presence of clouds, atmospheric $SO$2 becomes dissolved in the water droplets and forms weak sulfuric acid, $H$2SO4. Such clouds observed from space appear brighter than natural clouds, suggesting that these clouds are reflecting more solar radiation than natural clouds. This process is called cloud brightening and reduces the amount of solar energy entering the earth/atmosphere/ocean system, thereby contributing to a cooling of the planet . The net result of burning fossil fuels containing sulfur (mainly coal) is that the emitted $CO$2 leads to global warming and the $SO$2 leads to global cooling. Environmentalists have fought for years to have $SO$2 emissions reduced, but one result of these efforts seems to be that global warming will be exacerbated. The relative amounts of warming and cooling will be discussed in Unit 1-12.

Another possible linkage of sulfur to global change is the role of dimethylsulfide (DMS) in formation of clouds over ocean areas. DMS is produced naturally in ocean areas by biological activity. Studies have shown that DMS can promote the production of cloud condensation nuclei, which are favored particles for cloud droplet growth. Therefore, an abundance of marine plant life can produce sufficient amounts of DMS to enhance local cloud formation and possibly increased precipitation. This constitutes a direct link between the biosphere and local meteorology. It also opens the possibility that there might be a link between changes in the stratospheric ozone and local meteorology in that, for instance, increased ultraviolet levels over the ocean could suppress ocean biology, which in turn would reduce the emission of DMS, which could reduce cloudiness and precipitation in ocean areas. We don't know enough about the magnitude of this effect to evaluate its importance in relation to other global change processes.

Several other questions relating to the sulfur cycle and its component fluxes and reservoirs indicate that much research remains to be done on this trace gas.

Phosphorus

Phosphorus

Phosphorus is another element that is used by plants both on land and in the ocean, and so phosphorus availability in soils and in the ocean is a regulator of biological activity. There are many unanswered questions relating to the phosphorus cycle. The mechanisms controlling the availability of phosphorus in terrestrial soils and how these mechanisms respond to processes such as acid deposition, fire, and deforestation are not well known. By these land-use practices, we might be creating imbalances in the availability of other nutrients that plants need. What is the flux of marine phosphorus to the oceans? How has it changed in the past and how is it changing today? What are the consequences of these changes? Many issues remain unanswered.

It should be apparent from these questions and from our consideration of other chemical cycles that it is not possible to consider any of these individual elements such as carbon, nitrogen, sulfur, or phosphorus alone. Plants are mainly carbon (and of course water), but they need nitrogen, sulfur, and phosphorus to flourish. So a complete understanding of the carbon cycle requires an understanding of the larger system known by the term of biogeochemical cycles. Other trace gases of lesser global importance also are lumped into this general category because they may participate in the one or more of the many pathways followed by the major chemicals in their natural cycles.

Tropospheric Ozone

Tropospheric Ozone

Tropospheric ozone is a chemical that may be a trace constituent of natural biogeochemical cycles, but which presents an environmental problem primarily due to large anthropogenic sources in major cities. In future learning units we will discuss the problem of diminishing amounts of ozone in the stratosphere, but for now we are focusing on an excess of ozone in the lower levels in the atmosphere. Ozone is a very reactive chemical that interacts with plant and animal living tissue in a detrimental way. It can reduce lung functioning in humans and suppress plant growth enough to reduce yields of agricultural and horticultural crops.

Ozone is formed in the troposphere by various chemical reactions involving a combination of the oxides of nitrogen, reactive volatile organic compounds (VOC) produced by a combination of exhaust from automobiles in the form of unburned hydrocarbons, and diatomic oxygen in the presence of sunlight (Figure 12). High atmospheric temperatures and/or intense radiation at high altitudes are required to form ozone.

Typical reactions to create ozone include nitrogen dioxide being illuminated by sunlight in the wavelength region of 295 and 430 microns to give NO plus an oxygen. The free oxygen combines with diatomic oxygen in the presence of another molecule (to give a momentum balance) to produce ozone. A rapid ozone destruction reaction consists of NO interacting with ozone to produce $NO$2 and $O$2. With ozone continually being produced and destroyed by these two reactions, an equilibrium condition is established in which the intermediate constituent, namely ozone, exists at a concentration determined by the ratio of the abundance of $NO$2 and NO. Oxidation of photochemically reactive VOCs forms highly reactive chemical species known as free radicals, which are capable of converting NO and $NO$2 without the destruction of $O$3. As a result, these volatile organic compounds, mainly produced by automobiles, can interfere with the natural ozone destruction process and allow ozone concentrations to become elevated.

If any one of the four ingredients ($NO$X, VOC, $O$2, and sunlight) is absent, ozone concentrations diminish. Morning and evening rush-hour traffic in major cities on clear warm days provide the sufficient amounts of all ingredients, but elimination of any one reduces ozone levels significantly.

Anything that is susceptible to oxidation is a potential target for the adverse effects of elevated ozone concentrations (Figure 13). The human lung, for instance, particularly for people who have respiratory problems, can experience diminished functioning or reduced capacity. Figures 14, 15, 16, and 17 show examples of estimated yield losses for a variety of agricultural and horticultural crops due to elevated ozone levels.

Soybeans, for instance, under an ozone concentration of 0.081 parts per million will experience about a 30% loss of yield. The EPA threshold standard for ozone is 0.12 ppm, so even at levels below the EPA standard, soybeans could suffer loss of yield.

Other grain crops, such as wheat for instance, seem to be less vulnerable than soybeans. A quick scan of the vegetables listed also shows that ozone concentrations below the EPA standard will lead to significant yield reductions in all varieties.