Save our Seas Part 1: Oceans and Global Warming
January 20, 2007

by Dr. Mae-Wan Ho		print version
		print version (graphics)

[This is the first in a multi-part series on the critical condition of Earth's oceans which first appeared in ISIS Magazine, the Journal of the Institute of Science in Society.]

Oceans of life

Oceans are vast, deep, and mysterious. They cover 71 percent of the earth’s surface and contain approximately 97 percent of the earth’s water [1]. The average depth of the ocean is almost 4 000 metres [2], and nearly half the area is over 3 000 metres deep.

The oceans are home to the majority of plant and animal life on earth, accounting for 90 percent of the world’s living biomass, and many new species are being discovered from the depths. The Census of Marine Life (COML), an international alliance of scientists from 70 countries, discovered some 13 000 new species in 2003 alone [3]. COML is amassing data to create a map of the distribution of 38 000 marine species from plankton to whales.

According to one theory, life on earth originated around hydrothermal vents in the deep seafloor that heat up the water to 450 C [2]. Rare creatures living there today are still able to obtain energy from chemical reactions in the same way as the primordial life forms, and do not need to depend directly or indirectly on photosynthesis for food like 99.97 percent of the biosphere.

Oceans and climate

Oceans affect climate in many ways [4]. As the major reservoir of water, oceans dominate the movement of water, supplying most of the water vapour in the atmosphere by evaporation. Of this evaporated water, 91 percent is returned to the oceans as precipitation, the remainder is transported and precipitated over landmasses. Runoff and groundwater from land flow back to the oceans [5].

The oceans and the atmosphere are tightly linked, and together form the most dynamic component of the earth’s climate system. They bring moisture to coastal areas that may be carried inland by the wind. Typhoons and hurricanes form over the oceans, and as oceans get warmer these will be more frequent.

Oceans store heat. When the earth’s surface cools or is heated up by the sun, the temperature change is greater and faster over land than over the oceans. One consequence of the ocean’s ability to absorb more heat is that it cools the surrounding when it is hot and warms it when it is cold, which is why maritime climates tend to be less extreme than continental.

Winds and currents are constantly moving the ocean’s waters. Surface currents flowing north or south transport heat, and carry warmed or cooled water several thousand kilometres, thereby ameliorating the extremes of heat or cold. Deep ocean currents also flow across the globe [6]. The Gulf Stream Drift, for example, is powered by cold, dense, salt-laden water sinking off the north polar coastal regions and moving south in the depths, pushing the surface warm water from the tropical and subtropical Atlantic (including some from the Gulf of Mexico) up north to bathe the shores of Western Europe, producing a climate that is surprisingly mild for that latitude.

Global warming and melting of the polar icecaps freshens the surface water, reducing its density and preventing it from sinking. As a result, the Gulf Stream slows down, or may even reverse, bringing severe winters to northern Europe while the rest of the earth heats up [7].  In places where cold deep waters come up to the surface, as near San Francisco in California USA, the climate is as cool as Dublin in Ireland -- 600 km further north.

Oceans and the carbon cycle

Oceans play a fundamental role in climate change through the Carbon Cycle (Box 1). The major driver of the Carbon Cycle is the biosphere, which depends entirely on the ability of green plants, algae and certain bacteria to produce food for themselves and other organisms through photosynthesis. For that reason they are called primary producers.  

On land, the primary producers are almost all higher plants: trees, shrubs, grasses, ferns, mosses. In the oceans, however, the primary producers are algae, especially microscopic phytoplankton floating in the surface layers of water [9] (see Box 2).

Phytoplankton the green fuse of life in the oceans

Although comprising only 0.2 percent of the earth’s total biomass, phytoplankton is responsible for nearly 50 percent of the earth’s primary production on account of its prodigious rate of growth, which is why it can support the incredibly rich and diverse marine community from zooplankton to whales.

Phytoplankton inhabits the top 100 m or so of seawater, limited by the availability of light. Photosynthesis can still take place at 1 percent of the light level and phytoplankton grows best not right at the surface, but further down at about 100 m where the water is richer in nutrients such as nitrogen, phosphorous and iron.

Most of the carbon in the upper ocean is recycled, but some of it sinks into the deeper waters to feed the other organisms or to become buried in the seafloor. And as organisms die, their bodies also sink to the seafloor where decomposers feed on them to release carbon dioxide and other nutrients. As a result the deep waters are rich in nutrients.

In certain regions of the ocean, currents interacting with the coast or with other currents or both bring the cold deep nutrient-rich ocean water to the surface. This ‘upwelling’ is important for keeping the phytoplankton productive.

The latest evidence, obtained by towing a video camera submerged in the surface layers of the ocean, suggests that nitrogen-fixing cyanobacteria growing there may be supplying up to 50 percent of the nitrogen required for the phytoplankton [10].

The enormous food web in the oceans that depend on phytoplankton makes phytoplankton the most important primary producer. It is unique among primary producers for growing at the fastest rates, with doubling times from hours to days depending on the conditions [11]. Because of its prodigious rate of growth, phytoplankton population also determines carbon balance in the oceans, which will impact on climate change

For phytoplankton to thrive there must be an appropriate supply of nutrients. Too little, and the phytoplankton will fail to grow, too much all at once from agricultural runoffs sewage or other industrial pollutants, and algal blooms will result that could become toxic to fish, livestock and humans eating shellfish that feed on the phytoplankton and accumulate the toxins [12].

Moreover, the water must not be too warm, or too acid. All these conditions are deteriorating on account of global warming, bringing the prospect of a collapse in the marine biota, and turning the oceans into a massive carbon source that would further aggravate global warming.

We need urgent action to protect our oceans from pollution and over-exploitation. At the same time, we need to replace fossil fuels with the many renewable energy options that already exist.

>>Save Our Seas Part Two: Oceans -- Carbon Sink or Source?

References

1. Ocean, Wikipedia, http://en.wikipedia.org/wiki/Ocean
2. Gjerde KM. Ecosystems and Biodiversity in Deep Waters and High Seas, UNEP Regional Seas Report an Studies No. 178,  UNEP/IUCN, Switzerland, 2006.
3.  “Science taps into ocean secrets”, BBC News 22 November 2004, http://news.bbc.co.uk/2/hi/science/nature/4033555.stm
4. The Carbon Cycle, Earth observatory, NASA, http://earthobservatory.nasa.gov/Library/CarbonCycle/carbon_cycle2.html
5. The hydrologic cycle, PhyscalGeography.net, 1999-2006, http://www.physicalgeography.net/fundamentals/8b.html
6. Bunyard P. Why Gaia needs rainforests. Science in Society 2003, 20, 24-26, http://www.i-sis.org.uk/isisnews.php
7. Ho MW. Global warming and then the big freeze. Science in Society 2003, 20, 28-29.
8. Understanding the global carbon cycle, Woods Hole Research Center, 2004, http://www.whrc.org/carbon/index.htm
9. Primary Production, wikipedia, http://en.wikipedia.org/wiki/Primary_production
10. Kolber ZS. Getting a better picture of the ocean’s nitrogen budget. Science 2006, 312, 1479-80.
11. Algal bloom dynamics,  Harmful Algal Bloom Program, Northwest Fisheries Science Center, http://www.nwfsc.noaa.gov/hab/habs_toxins/phytoplankton/algal_dynamics.html
12. The rise in toxic tides. What’s behind the ocean bloom? Science NewsOnline, 1997, http://www.sciencenews.org/pages/sn_arc97/9_27_97/bob1.htm
    
    

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    Dr. Mae-Wan Ho is a Visiting Reader in Biology at London Open University and a Visiting Biophysics Professor at Catania University in Sicily. She has been one of the most influential figures of the last decade in the debate within the scientific community regarding the use of genetically modified organisms. She is a highly respected global scientific figure and a well-known critic of neo-Darwinism and reductionist thought in Biology and Physics. Dr. Ho has authored hundreds of scientific articles and many books on a variety of subjects.
    
    In 1999, she founded The Institute of Science in Society (ISIS), a London-based nonprofit organization that works globally to promote social responsibility and sustainability in scientific research and scientific practice.
    
    ISIS provides extensive online archives of articles, scientific papers, and press releases written by Dr. Ho and her colleagues related to biotechnology, including genetically modified organisms, sustainable agriculture, environmental issues, Gaia theory, holistic health, nanotechnology and alternative energy.
    
    ISIS also co-ordinates global campaigns including the The Global Campaign for a GM-Free Sustainable World and Sustainable World: A Global Initiative.

    
    A fully referenced illustrated version of this article is posted on ISIS members' website.

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