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AIR QUALITY ISSUES, Who Cares ?

26 Desember 2009   15:07 Diperbarui: 26 Juni 2015   18:45 142
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Air pollution is the human introduction into the atmosphere of chemicals, particulate matter, or biological materials that cause harm or discomfort to humans or other living organisms, or damages the environment. Air pollution causes deaths and respiratory disease. Air pollution is often identified with major stationary sources, but the greatest source of emissions is mobile sources, mainly automobiles. Gases such as carbon dioxide, which contribute to global warming, have recently gained recognition as pollutants by climate scientists, while they also recognize that carbon dioxide is essential for plant life through photosynthesis. The atmosphere is a complex, dynamic natural gaseous system that is essential to support life on planet Earth. Stratospheric ozone depletion due to air pollution has long been recognized as a threat to human health as well as to the Earth's ecosystems. Actualy primary pollutant are release in a harmful form. Secondary pollutant, by contrast, become hazadous after reaction in the air. Photochemical oxidants which is compound created by reaction driven by solar energy and atmospheric acids are probably the most important secondary pollutant. Fugitive or nonpoint source, emission are those that do not go through a smokestack. By far most massive examples of this category is dust fri]om soil erosion, strip mining, rock crushing and building construction. Leaking valves and pipe joints contributes as much as 90 percent of the hydrocarbons and volatile organic chemicals emitted from oil refines and chemial plants.

CATEGORIES OF AIR POLLUTANT

Pollutants can be classified as either primary or secondary. Usually, primary pollutants (major Pollutant) are substances directly emitted from a process, such as from a volcanic eruption, the carbon monoxide gas from a motor vehicle exhaust or sulfur dioxide released from factories.The examples for primary pollutant is sulfur dioxide, Nitrogen Oxides, Carbon monoxide, Particulate material, Volatile organic compound, Lead and other toxic compound. Secondary pollutants are not emitted directly. Rather, they form in the air when primary pollutants react or interact. An important example of a secondary pollutant is ground level ozone - one of the many secondary pollutants that make up photochemical smog. Sometimes pollutants may be both primary and secondary that is, they are both emitted directly and formed from other primary pollutants. In this part we will explain more details about major pollutant which Primary Pollutant.

MAJOR POLLUTANT

Sulfur Dioxides , is a colourless, corrosive that damages both plants animals. Once in atmosphere, it can be further oxidized to sulfur trioxide

which is react with water vapor or dissolves in water droplets to form Sulfuric Acid
a major component of acid rain. Sulfur Dioxides and Sulfate ions are probably second only to smoking as cause of air pollutant related health damage. Sulfate Particles and droplets also reduce visibility in the United States by as much as 80 percent.

Nitrogen Oxides

are highly reactive gases formed when combustion initiates reaction between atmospheric nitrogen and oxygen. The initial product nitric oxide, oxidized further in the atmosphere to nitrogen dioxides, a reddish brown gas that gives photochemical smog its distinctive colour. This is because these gas convert readily from one form to the other. The general term
is used to describe these gases. Nitrogen oxides combine with water to form nitric acid (
which is also a mojor component of acid precitipation. Excess Nitrogen in water is causing eutrophication of inland waters and coastal seas. It may also encourage the growth of weedy species that crowd out native plant.

Carbon Monoxide (CO) is less common than the principal form of atmospheric carbon, carbon dioxide (

), but more dangerous , CO is a colorless, odourless but highly toxic gas produced mainly by incomplete combustion of fuel (coal, oil, charcoal, wood or gas ). CO inhibits respiration in animals by binding irreversibly to hemoglobin. In the United States, two thirds of the CO emission are created by internal combustion engines in transportation. Land clearing fires and cooking fires also are major sources. About 90 percent of the CO in the air is consumed in photochemical reaction that produce ozone

Particulate materials includes dust, ash, soot, lint, smoke, pollen, spores, algal cell, and many other suspended materials. Aerosol or extremely minute particles or liquid droplets suspended in the air, are icluded in this class. Particulates often are the most apparent form of air pollution, since they reduce visibility and leave dirty deposits on windows, painted surfaces, and textils. Breathable particles smaller than 2.5 micro are among the most dangerous of this group because they can damage lung tissues. Asbestos fibers and cigarette smoke are among the most dangerous respirable particles in urban and indoor air because they are carcinongenic.

Volatile Organic compound (VOCs) are organic gases. Plants, bogs, and termittes are the largest sources of VOCs especially isoprenes (

),terpenes (
) and Methane (
). These volatile hydrocarbon are generally oxidized to CO and
in the atmosphere. More dangerous synthetic organic chemical such as benzene, toluene, formaldehyde, vinyl chloride, phenol, chlroform and trichloroethylene, are release by human activities.Principles sources are incompetely burned fuel from vehicles, power plants, chemical plants and petroleum refineries. These chemical play an important role in the formation of photochemical oxidants.

Photochemical oxidants are product of secondary atmospheric reaction driven by solar energy. One of the most important of these reaction involves formation of singlet atomic oxygen by splitting nitrogen dioxide. This atomic oxygen react with another molecule of (

) to make ozone (
). Although ozone is important in the stratosphere in ambient air it is highly reactive and damage vegetation, animal tissues and buildings materials. Ozone acrid biting odor is a distinctive characteristic of photochemical smog.

Toxic metal and halogens are chemical elements that are toxic when concentrated and released in the enviroment. Principles metals of concern are lead, mercury, arsenic, nickel, beryllium, cadmium, thallium, uranium, cesium , and plutonium. Halogens which is fluorine chlorine, bromine and iodinevare highlly reactive toxic elements. Most of these materials are mined and used in fuels, especially coal. Lead and mercury are widespreads neurotoxins that damage the nervous system. By some estimate, 20 percent of all innercity children suffer some degree of development retardation from high enviromental lead level. Long range transport of lead and merury throung the air is causing bioaccumulation in remote aquatic ecosystems such as arctic lakes and seas. Chlorine is a toxic halogen widely used in bleach, plastics and others products Methyl bromide a powerful fungicide used in agriculture and chlorofluorocarbon are also implicated in ozone Depletion.

AIR POLLUTION INDEX (API)

The Air Quality Index (AQI) is a standardized indicator of the air quality in a given location. It measures mainly ground-level ozone and particulates (except the pollen count), but may also include sulfur dioxide, and nitrogen dioxide. Various agencies around the world measure such indices, though definitions may change between places. The United States Environmental Protection Agency (EPA) and the Meteorological Service of Canada (MSC) differ on what AQI structure and health classification is used:

Health classifications used by the EPA:


  • 0-50 Good is usually green
  • 51-100 Moderate is usually yellow
  • 101-150 Unhealthy for sensitive groups is usually orange
  • 151-200 Unhealthy is usually red
  • 201-300 Very unhealthy is usually purple
  • 301-500 Hazardous is usually maroon


The EPA's AQI 100 corresponds to 0.08 ppm ozone, and to other levels for other pollutants. Source: EPA. The AQI standards in Canada are relatively more stringent. The current health classifications used by the Meteorological Service of Canada (MSC) are as follows:


  • 0-25*: Good (green)
  • 26*-50: Fair (yellow)
  • 51-100: Poor (orange)
  • 101+: Very poor (red)

The air quality in Malaysia is reported as the API or Air Pollution Index. Four of the index's pollutant components (i.e., carbon monoxide, ozone, nitrogen dioxide and sulfur dioxide) are reported in ppmv but PM10 particulate matter is reported in μg/m³. Unlike the American AQI, the index number can exceed 500. Above 500, a state of emergency is declared in the reporting area. Usually, this means that non-essential government services are suspended, and all ports in the affected area closed. There may also be a prohibition on private sector commercial and industrial activities in the reporting area excluding the food sector.

API

Air Pollution
Level

Health Implications

0 - 25

Low

None expected.

26 - 50

Medium

None expected for the general population.

51 - 100

High

Acute health effects are not expected but chronic effects may be observed if one is persistently exposed to such levels.

100 - 200

Very High

People with existing heart or respiratory illnesses may notice mild aggravation of their health conditions. Generally healthy individuals may also notice some discomfort.

201 - 500

Severe

People with existing heart or respiratory illnesses may experience significant aggravation of their symptoms. There may also be widespread symptoms in the healthy population (e.g. eye irritation, wheezing, coughing, phlegm and sore throats).

EFFECT OF AIR POLLUTANT

Health effects

The World Health Organization states that 2.4 million people die each year from causes directly attributable to air pollution, with 1.5 million of these deaths attributable to indoor air pollution. Epidemiological studies suggest that more than 500,000 Americans die each year from cardiopulmonary disease linked to breathing fine particle air pollution. A study by the University of Birmingham has shown a strong correlation between pneumonia related deaths and air pollution from motor vehicles.Worldwide more deaths per year are linked to air pollution than to automobile accidents. Published in 2005 suggests that 310,000 Europeans die from air pollution annually. Direct causes of air pollution related deaths include aggravated asthma, bronchitis, emphysema, lung and heart diseases, and respiratory allergies. The US EPA estimates that a proposed set of changes in diesel engine technology (Tier 2) could result in 12,000 fewer premature mortalities, 15,000 fewer heart attacks, 6,000 fewer emergency room visits by children with asthma, and 8,900 fewer respiratory-related hospital admissions each year in the United States. The worst short term civilian pollution crisis in India was the 1984 Bhopal Disaster. Leaked industrial vapors from the Union Carbide factory, belonging to Union Carbide, Inc., U.S.A., killed more than 2,000 people outright and injured anywhere from 150,000 to 600,000 others, some 6,000 of whom would later die from their injuries. The United Kingdom suffered its worst air pollution event when the December 4 Great Smog of 1952 formed over London. In six days more than 4,000 died, and 8,000 more died within the following months. An accidental leak of anthrax spores from a biological warfare laboratory in the former USSR in 1979 near Sverdlovsk is believed to have been the cause of hundreds of civilian deaths. The worst single incident of air pollution to occur in the United States of America occurred in Donora, Pennsylvania in late October, 1948, when 20 people died and over 7,000 were injured. The health effects caused by air pollutants may range from subtle biochemical and physiological changes to difficulty in breathing, wheezing, coughing and aggravation of existing respiratory and cardiac conditions. These effects can result in increased medication use, increased doctor or emergency room visits, more hospital admissions and premature death. The human health effects of poor air quality are far reaching, but principally affect the body's respiratory system and the cardiovascular system. Individual reactions to air pollutants depend on the type of pollutant a person is exposed to, the degree of exposure, the individual's health status and genetics.

Plant are sensitive to pollutants

In the early days of industrialzation, fumes from furnaces, smelters refineries and chemical plants often destroyed vegetation and created desolated, barren landscapes around minig and manufacturing centers. The copper-nickel smelter at Sudbury, ontario is a spectacular examples. There are two probably ways that air pollutant damage plant. They can damage sensitive cell membrane, much as irritants do in human lungs. Toxic level of oxidants produce discoloration and then necrotic spot. However the symtoms are vague and difficult to saperate from disease or insect damage. Pollutant can also act as hormones, disrupting plant metabolism growth and development. Certain combination of enviromental factor have synergistic effect in which the injuries caused by exposure to two factor together is more than the sum of exposure to each factor individually. For instances white pine seedling exposed to subthreshold concentration of ozone and sulfur dioxide individually do not suffer any visible injury. If the same concentration of pollutants are given together however, visibles damages occurs.

Smog and Haze Reduce the visibility

We have only recently realized that pollutant affect rural areas as well as cities. Even supposely pristine places such as our national park are suffering from air pollution. Grand Canyon National Park , Where maximum visibility used to be 300 km is now so smoggy on some winter days that visitor cant see the opposite rim only 20 km across the canyon. Mining operation, Smelter and power plant (some of which were moved to the desert to improved air quality in cities such as los angeles ). Are main culprits. Huge region are affected by pollution. A gigantic “ haze blob” as much as 3000 km across cover much of eastern united states in summer cutting visibility as much as 80 percent.People become accustomed to these condition and don’t realize that the air once was clear. Studies indicates, however that if all human made source of air pollution were shut down, the air would clear up in few days and there would be about 150 km visibility nearly everywhere, rather than the 15 km to which we have become accustomed

Acid deposition

Acid precipitation, the deposition of wet acidic solution or dry acidic particles from the air, became widely recognized as a polution problem only the last 20 years. But the concept has been recognized since the 1850s .we describes acidity in terms of pH with substances below pH7 being acidic. Normal unpoluted rain generally has a pH about 5.6 due to carbonic acid created when rainwater react with carbon dioxides in the air. Downwind of industrial areas, rainfall acidity can reach level pH 4.3, more than ten time as acidic as normal rain. Acid fog, snow, mist and dew can deposit damaging acid on plant in water system and on building. Furthermore fallout of dry sulfate and nitrate particles can account for as much as half of the acidic in some areas.

GLOBAL WARMING

Global warming is the increase in the average measured temperature of the Earth's near-surface air and oceans since the mid-20th century, and its projected continuation. The average global air temperature near the Earth's surface increased 0.74 ± 0.18 °C (1.33 ± 0.32 °F) during the 100 years ending in 2005. The Intergovernmental Panel on Climate Change (IPCC) concludes most of the observed increase in globally averaged temperatures since the mid-twentieth century is very likely due to the observed increase in anthropogenic greenhouse gas concentrations via an enhanced greenhouse effect. Natural phenomena such as solar variation combined with volcanoes probably had a small warming effect from pre-industrial times to 1950 and a small cooling effect from 1950 onward. These basic conclusions have been endorsed by at least 30 scientific societies and academies of science, including all of the national academies of science of the major industrialized countries. While individual scientists have voiced disagreement with some findings of the IPCC, the overwhelming majority of scientists working on climate change agree with the IPCC's main conclusions. Climate model projections summarized by the IPCC indicate that average global surface temperature will likely rise a further 1.1 to 6.4 °C (2.0 to 11.5 °F) during the twenty-first century.This range of values results from the use of differing scenarios of future greenhouse gas emissions as well as models with differing climate sensitivity. Although most studies focus on the period up to 2100, warming and sea level rise are expected to continue for more than a thousand years even if greenhouse gas levels are stabilized. The delay in reaching equilibrium is a result of the large heat capacity of the oceans. Increasing global temperature is expected to cause sea levels to rise, an increase in the intensity of extreme weather events, and significant changes to the amount and pattern of precipitation, likely leading to an expanse of tropical areas and increased pace of desertification.

Other expected effects of global warming include changes in agricultural yields, modifications of trade routes, glacier retreat, mass species extinctions and increases in the ranges of disease vectors. Remaining scientific uncertainties include the amount of warming expected in the future, and how warming and related changes will vary from region to region around the globe. Most national governments have signed and ratified the Kyoto Protocol aimed at reducing greenhouse gas emissions, but there is on going political and public debate worldwide regarding what, if any, action should be taken to reduce or reverse future warming or to adapt to its expected consequences. The term "global warming" refers to increase in the Instrumental temperature record due mostly to Greenhouse Gases (GHGs), of which human activities are the primary cause. As greenhouse gases increase, the effect is projected to increase. The United Nations Framework Convention on Climate Change (UNFCCC) uses the term "climate change" for human-caused change, and "climate variability" for other changes. The term "climate change" recognizes effects in addition to rising temperatures. The term "anthropogenic global warming" is sometimes used when focusing on human-induced changes.

Greenhouse Effect

The detailed causes of the recent warming remain an active field of research, but the scientific consensus is that the increase in atmospheric greenhouse gases due to human activity caused most of the warming observed since the start of the industrial era. This attribution is clearest for the most recent 50 years, for which the most detailed data are available. The greenhouse effect was discovered by Joseph Fourier in 1824 and was first investigated quantitatively by Svante Arrhenius in 1896. It is the process by which absorption and emission of infrared radiation by atmospheric gases warm a planet's lower atmosphere and surface.

Recent increases in atmospheric carbon dioxide (CO2). The monthly CO2 measurements display small seasonal oscillations in an overall yearly uptrend; each year's maximum is reached during the Northern Hemisphere's late spring, and declines during the Northern Hemisphere growing season as plants remove some CO2 from the atmosphere.Existence of the greenhouse effect as such is not disputed. Naturally occurring greenhouse gases have a mean warming effect of about 33 °C (59 °F), without which Earth would be uninhabitable.[17][18] On Earth, the major greenhouse gases are water vapor, which causes about 36–70 percent of the greenhouse effect (not including clouds); carbon dioxide (CO2), which causes 9–26 percent; methane (CH4), which causes 4–9 percent; and ozone, which causes 3–7 percent. The issue is how the strength of the greenhouse effect changes when human activity increases the atmospheric concentrations of some greenhouse gases.

Human activity since the industrial revolution has increased the concentration of various greenhouse gases, leading to increased radiative forcing from CO2, methane, tropospheric ozone, CFCs and nitrous oxide. Molecule for molecule, methane is a more effective greenhouse gas than carbon dioxide, but its concentration is much smaller so that its total radiative forcing is only about a fourth of that from carbon dioxide. Some other naturally occurring gases contribute small fractions of the greenhouse effect; one of these, nitrous oxide (N2O), is increasing in concentration owing to human activity such as agriculture. The atmospheric concentrations of CO2 and CH4 have increased by 31% and 149% respectively since the beginning of the industrial revolution in the mid-1700s. These levels are considerably higher than at any time during the last 650,000 years, the period for which reliable data has been extracted from ice cores. From less direct geological evidence it is believed that CO2 values this high were last attained 20 million years ago. Fossil fuel burning has produced approximately three-quarters of the increase in CO2 from human activity over the past 20 years. Most of the rest is due to land-use change, in particular deforestation. The present atmospheric concentration of CO2 is about 385 parts per million (ppm) by volume. Human activities have caused the atmospheric concentrations of carbon dioxide and methane to be higher today than at any point during the last 650,000 years . Future CO2 levels are expected to rise due to on going burning of fossil fuels and land-use change. The rate of rise will depend on uncertain economic, sociological, technological, and natural developments, but may be ultimately limited by the availability of fossil fuels. The IPCC Special Report on Emissions Scenarios gives a wide range of future CO2 scenarios, ranging from 541 to 970 ppm by the year 2100. Fossil fuel reserves are sufficient to reach this level and continue emissions past 2100, if coal, tar sands or methane clathrates are extensively used.

In asmuch as the greenhouse effect is due to human activity, it is a forcing effect that is separate from forcing due to climate variability.

EFFECT OF THE GLOBAL WARMING

The effects of global warming on the environment and human life are numerous, varied, accelerating and taking scientists studying global warming by surprise. Scenarios studied by the Intergovernmental Panel on Climate Change (IPCC) predict that global warming will continue and get worse much faster than was expected even in their last report. The IPCC reports attribute many specific natural phenomena to human causes. The expected long range effects of recent climate change may already be observed. Rising sea levels, glacier retreat, Arctic shrinkage, and altered patterns of agriculture are cited as direct consequences of human activities. Predictions for secondary and regional effects include extreme weather events, an expansion of tropical diseases, changes in the timing of seasonal patterns in ecosystems, and drastic economic impact. Concerns have led to political activism advocating proposals to mitigate, eliminate, or adapt to it. The 2007 Fourth Assessment Report by the IPCC includes a summary of the expected effects.

Physical impacts

Extreme weather

Storm strength leading to extreme weather is increasing, such as the power dissipation index of hurricane intensity. Kerry Emanuel writes that hurricane power dissipation is highly correlated with temperature, reflecting global warming. However, a further study by Emanuel using current model output concluded that the increase in power dissipation in recent decades cannot be completely attributed to global warming. Hurricane modeling has produced similar results, finding that hurricanes, simulated under warmer, high-CO2 conditions, are more intense, however, hurricane frequency will be reduced. Worldwide, the proportion of hurricanes reaching categories 4 or 5 – with wind speeds above 56 metres per second – has risen from 20% in the 1970s to 35% in the 1990s. Precipitation hitting the US from hurricanes has increased by 7% over the twentieth century. The extent to which this is due to global warming as opposed to the Atlantic Multidecadal Oscillation is unclear.

Some studies have found that the increase in sea surface temperature may be offset by an increase in wind shear, leading to little or no change in hurricane activity. Increases in catastrophes resulting from extreme weather are mainly caused by increasing population densities, and anticipated future increases are similarly dominated by societal change rather than climate change. The World Meteorological Organization explains that “though there is evidence both for and against the existence of a detectable anthropogenic signal in the tropical cyclone climate record to date, no firm conclusion can be made on this point.” They also clarified that “no individual tropical cyclone can be directly attributed to climate change.”However, Hoyos et al. (2006) have linked the increasing trend in number of category 4 and 5 hurricanes for the period 1970-2004 directly to the trend in sea surface temperatures.

Thomas Knutson and Robert E. Tuleya of NOAA stated in 2004 that warming induced by greenhouse gas may lead to increasing occurrence of highly destructive category-5 storms.Vecchi and Soden find that wind shear, the increase of which acts to inhibit tropical cyclones, also changes in model-projections of global warming. There are projected increases of wind shear in the tropical Atlantic and East Pacific associated with the deceleration of the Walker circulation, as well as decreases of wind shear in the western and central Pacific. The study does not make claims about the net effect on Atlantic and East Pacific hurricanes of the warming and moistening atmospheres, and the model-projected increases in Atlantic wind shear.A substantially higher risk of extreme weather does not necessarily mean a noticeably greater risk of slightly-above-average weather. However, the evidence is clear that severe weather and moderate rainfall are also increasing. Increases in temperature are expected to produce more intense convection over land and a higher frequency of the most severe storms. Stephen Mwakifwamba, national co-ordinator of the Centre for Energy, Environment, Science and Technology — which prepared the Tanzanian government's climate change report to the UN — says that change is happening in Tanzania right now. "In the past, we had a drought about every 10 years", he says. "Now we just don't know when they will come. They are more frequent, but then so are floods. The climate is far less predictable. We might have floods in May or droughts every three years. Upland areas, which were never affected by mosquitoes, now are. Water levels are decreasing every day. The rains come at the wrong time for farmers and it is leading to many problems.

Greg Holland, director of the Mesoscale and Microscale Meteorology Division at the National Center for Atmospheric Research in Boulder, Colorado, said on April 24, 2006, "The hurricanes we are seeing are indeed a direct result of climate change," and that the wind and warmer water conditions that fuel storms when they form in the Caribbean are, "increasingly due to greenhouse gases. There seems to be no other conclusion you can logically draw." Holland said, "The large bulk of the scientific community say what we are seeing now is linked directly to greenhouse gases.(See also "Global warming?" in tropical cyclone)

Temperature rise

From 1961 to 2003, the global ocean temperature has risen by 0.10°C from the surface to a depth of 700 m. There is variability both year-to-year and over longer time scales, with global ocean heat content observations showing high rates of warming for 1991 to 2003, but some cooling from 2003 to 2007. The temperature of the Antarctic Southern Ocean rose by 0.17 °C (0.31 °F) between the 1950s and the 1980s, nearly twice the rate for the world's oceans as a whole . As well as having effects on ecosystems (e.g. by melting sea ice, affecting algae that grow on its underside), warming reduces the ocean's ability to absorb CO2.[citation needed]

Acidification

The world’s oceans soak up much of the carbon dioxide produced by living organisms, either as dissolved gas, or in the skeletons of tiny marine creatures that fall to the bottom to become chalk or limestone. Oceans currently absorb about one tonne of CO2 per person per year. It is estimated that the oceans have absorbed around half of all CO2 generated by human activities since 1800 (118 ± 19 petagrams of carbon from 1800 to 1994). But in water, carbon dioxide becomes a weak carbonic acid, and the increase in the greenhouse gas since the industrial revolution has already lowered the average pH (the laboratory measure of acidity) of seawater by 0.1 units, to 8.2. Predicted emissions could lower it by a further 0.5 by 2100, to a level probably not seen for hundreds of millennia and, critically, at a rate of change probably 100 times greater than at any time over this period. There are concerns that increasing acidification could have a particularly detrimental effect on corals (16% of the world's coral reefs have died from bleaching caused by warm water in 1998, which coincidentally was the warmest year ever recorded) and other marine organisms with calcium carbonate shells.

Increased evaporation

Over the course of the 20th century, evaporation rates have reduced worldwide [26]; this is thought by many to be explained by global dimming. As the climate grows warmer and the causes of global dimming are reduced, evaporation will increase due to warmer oceans. Because the world is a closed system this will cause heavier rainfall, with more erosion. This erosion, in turn, can in vulnerable tropical areas (especially in Africa) lead to desertification. On the other hand, in other areas, increased rainfall lead to growth of forests in dry desert areas. Scientists have found evidence that increased evaporation could result in more extreme weather as global warming progresses. The IPCC Third Annual Report says: global average water vapor concentration and precipitation are projected to increase during the 21st century. By the second half of the 21st century, it is likely that precipitation will have increased over northern mid- to high latitudes and Antarctica in winter. At low latitudes there are both regional increases and decreases over land areas. Larger year to year variations in precipitation are very likely over most areas where an increase in mean precipitation is projected.

Oceans

The role of the oceans in global warming is a complex one. The oceans serve as a sink for carbon dioxide, taking up much that would otherwise remain in the atmosphere, but increased levels of CO2 have led to ocean acidification. Furthermore, as the temperature of the oceans increases, they become less able to absorb excess CO2. Global warming is projected to have a number of effects on the oceans. Ongoing effects include rising sea levels due to thermal expansion and melting of glaciers and ice sheets, and warming of the ocean surface, leading to increased temperature stratification. Other possible effects include large-scale changes in ocean circulation.

Sea level rise

Sea level rise during the Holocene

With increasing average global temperature, the water in the oceans expands in volume, and additional water enters them which had previously been locked up on land in glaciers, for example, the Greenland and the Antarctic ice sheets. For most glaciers worldwide, an average volume loss of 60% until 2050 is predicted. Meanwhile, the estimated total ice melting rate over Greenland is –239 ± 23 cubic kilometers per year, mostly from East Greenland. The Antarctic ice sheet, however, is expected to grow during the 21st century because of increased precipitation. Under the IPCC Special Report on Emission Scenarios (SRES) A1B scenario by the mid-2090s, for instance, global sea level reaches 0.22 to 0.44 m above 1990 levels, and is rising at about 4 mm per year. Since 1900, the sea level has risen at an average of 1.7 mm/yr.; since 1993, satellite altimetry from TOPEX/Poseidon indicates a rate of about 3 mm/yr. The sea level has risen more than 120 metres since the Last Glacial Maximum about 20,000 years ago. The bulk of that occurred before 7000 years ago. Global temperature declined after the Holocene Climatic Optimum, causing a sea level lowering of 0.7 ± 0.1 m between 4000 and 2500 years before present. From 3000 years ago to the start of the 19th century, sea level was almost constant, with only minor fluctuations. However, the Medieval Warm Period may have caused some sea level rise; evidence has been found in the Pacific Ocean for a rise to perhaps 0.9 m above present level in 700 BP. In a paper published in 2007, the climatologist James Hansen et al. claimed that ice at the poles does not melt in a gradual and linear fashion, but flips suddenly from one state to another according to the geological record. In this paper Hansen et al. state: Our concern that BAU GHG scenarios would cause large sealevel rise this century (Hansen 2005) differs from estimates of IPCC (2001, 2007), which foresees little or no contribution to twentyfirst century sealevel rise from Greenland and Antarctica. However, the IPCC analyses and projections do not well account for the nonlinear physics of wet ice sheet disintegration, ice streams and eroding ice shelves, nor are they consistent with the palaeoclimate evidence we have presented for the absence of discernible lag between ice sheet forcing and sea level rise.

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