Global dimming

Dozens of fires burning on the surface (red dots) and a thick pall of smoke and haze (greyish pixels) filling the skies overhead in Eastern China. Smoke, pollution and other air particles are linked to global dimming. Photo taken by MODIS aboard NASA's Aqua satellite.

Global dimming is the gradual reduction in the amount of global direct irradiance at the Earth's surface that was observed for several decades after the start of systematic measurements in the 1950s. The effect varies by location, but worldwide it has been estimated to be of the order of a 4% reduction over the three decades from 1960–1990. However, after discounting an anomaly caused by the eruption of Mount Pinatubo in 1991, a very slight reversal in the overall trend has been observed.[1]

Global dimming is thought to have been caused by an increase in particulates such as sulfate aerosols in the atmosphere due to human action.

It has interfered with the hydrological cycle by reducing evaporation and may have reduced rainfall in some areas. Global dimming also creates a cooling effect that may have partially counteracted the effect of greenhouse gases on global warming.

In basic terms, less sunlight is reaching the Earth because of visible air pollution, which is reflecting the light back into space.

Causes and effects

Further information: Albedo, irradiance and insolation

It is thought that global dimming is probably due to the increased presence of aerosol particles in the atmosphere caused by human action.[2] Aerosols and other particulates absorb solar energy and reflect sunlight back into space. The pollutants can also become nuclei for cloud droplets. Water droplets in clouds coalesce around the particles.[3] Increased pollution causes more particulates and thereby creates clouds consisting of a greater number of smaller droplets (that is, the same amount of water is spread over more droplets). The smaller droplets make clouds more reflective, so that more incoming sunlight is reflected back into space and less reaches the Earth's surface. This same effect also reflects radiation from below, trapping it in the lower atmosphere. In models, these smaller droplets also decrease rainfall.[4]

Clouds intercept both heat from the sun and heat radiated from the Earth. Their effects are complex and vary in time, location, and altitude. Usually during the daytime the interception of sunlight predominates, giving a cooling effect; however, at night the re-radiation of heat to the Earth slows the Earth's heat loss.

Research

Further information: Climate model and pyranometer

In the late-1960s, Mikhail Ivanovich Budyko worked with simple two-dimensional energy-balance climate models to investigate the reflectivity of ice.[5] He found that the ice-albedo feedback created a positive feedback loop in the Earth's climate system. The more snow and ice, the more solar radiation is reflected back into space and hence the colder Earth grows and the more it snows. Other studies found that pollution or a volcano eruption could provoke the onset of an ice age.[6][7]

In the mid-1980s, Atsumu Ohmura, a geography researcher at the Swiss Federal Institute of Technology, found that solar radiation striking the Earth's surface had declined by more than 10% over the three previous decades. His findings appeared to contradict global warming—the global temperature had been generally rising since the 70s. Less light reaching the earth seemed to mean that it should cool. Ohmura published his findings "Secular variation of global radiation in Europe" in 1989.[8] This was soon followed by others: Viivi Russak in 1990 "Trends of solar radiation, cloudiness and atmospheric transparency during recent decades in Estonia",[9] and Beate Liepert in 1994 "Solar radiation in Germany — Observed trends and an assessment of their causes".[10] Dimming has also been observed in sites all over the former Soviet Union.[11] Gerry Stanhill who studied these declines worldwide in many papers (see references) coined the term "global dimming".[12]

Independent research in Israel and the Netherlands in the late 1980s showed an apparent reduction in the amount of sunlight,[13] despite widespread evidence that the climate was becoming hotter. The rate of dimming varies around the world but is on average estimated at around 2–3% per decade. The trend reversed in the early 1990s. [1] It is difficult to make a precise measurement, due to the difficulty in accurately calibrating the instruments used, and the problem of spatial coverage. Nonetheless, the effect is almost certainly present.

The effect (2–3%, as above) is due to changes within the Earth's atmosphere; the value of the solar radiation at the top of the atmosphere has not changed by more than a fraction of this amount.[14]

Smog, seen here at the Golden Gate Bridge, is a likely contributor to global dimming.

The effect varies greatly over the planet, but estimates of the terrestrial surface average value are:

Note that these numbers are for the terrestrial surface and not really a global average. Whether dimming (or brightening) occurred over the ocean has been a bit of an unknown though a specific measurement (see below, Causes) measured effects some 400 miles (643.7 km) from India over the Indian Ocean towards the Maldives Islands. Regional effects probably dominate but are not strictly confined to the land area, and the effects will be driven by regional air circulation. A 2009 review by Wild et al.[18] found that widespread variation in regional and time effects. There was solar brightening beyond 2000 at numerous stations in Europe, the United States, and Korea. The brightening seen at sites in Antarctica during the 1990s, influenced by recovering from the Mount Pinatubo volcanic eruption in 1991, fades after 2000. The brightening tendency also seems to level off at sites in Japan. In China there is some indication for a renewed dimming, after the stabilization in the 1990s. A continuation of the long-lasting dimming is also noted at the sites in India. Overall, the available data suggest continuation of the brightening beyond the year 2000 at numerous locations, yet less pronounced and coherent than during the 1990s, with more regions with no clear changes or declines. Therefore, globally, greenhouse warming after 2000 may be less modulated by surface solar variations than in prior decades. The largest reductions are found in the northern hemisphere mid-latitudes.[19] Visible light and infrared radiation seem to be most affected rather than the ultraviolet part of the spectrum.[20]

Pan evaporation data

Further information: Pan evaporation

Over the last 50 or so years, pan evaporation has been carefully monitored. For decades, nobody took much notice of the pan evaporation measurements. But in the 1990s in Europe, Israel, and North America, scientists spotted something that at the time was considered very strange: the rate of evaporation was falling although they had expected it to increase due to global warming.[21] The same trend has been observed in China over a similar period. A decrease in solar irradiance is cited as the driving force. However, unlike in other areas of the world, in China the decrease in solar irradiance was not always accompanied by an increase in cloud cover and precipitation. It is believed that aerosols may play a critical role in the decrease of solar irradiance in China.[22]

BBC Horizon producer David Sington believes that many climate scientists regard the pan-evaporation data as the most convincing evidence of solar dimming.[23] Pan evaporation experiments are easy to reproduce with low-cost equipment. There are many pans used for agriculture all over the world and in many instances the data have been collected for nearly a half century. However, pan evaporation depends on factors besides net radiation from the sun. The other two major factors are vapor pressure deficit and wind speed.[24] The ambient temperature turns out to be a negligible factor. The pan evaporation data corroborates the data gathered by radiometer[16][21] and fills in the gaps in the data obtained using pyranometers. With adjustments to these factors, pan evaporation data has been compared to results of climate simulations.[25]

Probable causes

Further information: Particulate, Black carbon, Contrail and Volcanic ash
NASA photograph showing aircraft contrails and natural clouds. The temporary disappearance of contrails over North America due to plane groundings after the September 11, 2001 attacks, and the resulting increase in diurnal temperature range gave empirical evidence of the effect of thin ice clouds at the Earth's surface.[26]

The incomplete combustion of fossil fuels (such as diesel) and wood releases black carbon into the air. Though black carbon, most of which is soot, is an extremely small component of air pollution at land surface levels, the phenomenon has a significant heating effect on the atmosphere at altitudes above two kilometers (6,562 ft). Also, it dims the surface of the ocean by absorbing solar radiation.[27]

Experiments in the Maldives (comparing the atmosphere over the northern and southern islands) in the 1990s showed that the effect of macroscopic pollutants in the atmosphere at that time (blown south from India) caused about a 10% reduction in sunlight reaching the surface in the area under the pollution cloud a much greater reduction than expected from the presence of the particles themselves.[28] Prior to the research being undertaken, predictions were of a 0.5–1% effect from particulate matter; the variation from prediction may be explained by cloud formation with the particles acting as the focus for droplet creation. Clouds are very effective at reflecting light back out into space.

The phenomenon underlying global dimming may also have regional effects. While most of the earth has warmed, the regions that are downwind from major sources of air pollution (specifically sulfur dioxide emissions) have generally cooled. This may explain the cooling of the eastern United States relative to the warming western part.[29]

However some research shows that black carbon will increase global warming, being second only to CO2. They believe that soot will absorb solar energy and transport it to other areas such as the Himalayas where glacial melting occurs. It can also darken Arctic ice reducing reflectivity and increasing absorption of solar radiation.[30]

Some climate scientists have theorized that aircraft contrails (also called vapor trails) are implicated in global dimming, but the constant flow of air traffic previously meant that this could not be tested. The near-total shutdown of civil air traffic during the three days following the September 11, 2001 attacks afforded a unique opportunity in which to observe the climate of the United States absent from the effect of contrails. During this period, an increase in diurnal temperature variation of over 1 °C (1.8 °F) was observed in some parts of the U.S., i.e. aircraft contrails may have been raising nighttime temperatures and/or lowering daytime temperatures by much more than previously thought.[26]

Airborne volcanic ash can reflect the Sun's rays back into space and thereby contribute to cooling the planet. Dips in earth temperatures have been observed after large volcano eruptions such as Mount Agung in Bali that erupted in 1963, El Chichon (Mexico) 1983, Ruiz (Colombia) 1985, and Pinatubo (Philippines) 1991. But even for major eruptions, the ash clouds remain only for relatively short periods.[31]

Recent reversal of the trend

Further information: Clean Air Act (United States)
Sun-blocking aerosols around the world steadily declined (red line) since the 1991 eruption of Mount Pinatubo, according to satellite estimates. Credit: Michael Mishchenko, NASA

Wild et al., using measurements over land, report brightening since 1990,[13][32][33] and Pinker et al.[34] found that slight dimming continued over land while brightening occurred over the ocean.[35] Hence, over the land surface, Wild et al. and Pinker et al. disagree. A 2007 NASA sponsored satellite-based study sheds light on the puzzling observations by other scientists that the amount of sunlight reaching Earth's surface had been steadily declining in recent decades, began to reverse around 1990. This switch from a "global dimming" trend to a "brightening" trend happened just as global aerosol levels started to decline.[31][36]

It is likely that at least some of this change, particularly over Europe, is due to decreases in airborne pollution. Most governments of developed nations have taken steps to reduce aerosols released into the atmosphere, which helps reduce global dimming.

Sulfate aerosols have declined significantly since 1970 with the Clean Air Act in the United States and similar policies in Europe. The Clean Air Act was strengthened in 1977 and 1990. According to the EPA, from 1970 to 2005, total emissions of the six principal air pollutants, including PM’s, dropped by 53% in the US. In 1975, the masked effects of trapped greenhouse gases finally started to emerge and have dominated ever since.[37]

The Baseline Surface Radiation Network (BSRN) has been collecting surface measurements. BSRN was started in the early 1990s and updated the archives in this time. Analysis of recent data reveals that the surface of the planet has brightened by about 4% in the past decade. The brightening trend is corroborated by other data, including satellite analyses.

Relationship to hydrological cycle

This figure shows the level of agreement between a climate model driven by five factors and the historical temperature record. The negative component identified as "sulfate" is associated with the aerosol emissions blamed for global dimming.

Pollution produced by humans may be seriously weakening the Earth's water cycle reducing rainfall and threatening fresh water supplies. A 2001 study by researchers at the Scripps Institution of Oceanography suggests that tiny particles of soot and other pollutants have a significant effect on the hydrological cycle. According to Veerabhadran Ramanathan, "the energy for the hydrological cycle comes from sunlight. As sunlight heats the ocean, water escapes into the atmosphere and falls out as rain. So as aerosols cut down sunlight by large amounts, they may be spinning down the hydrological cycle of the planet."[38]

Large scale changes in weather patterns may also have been caused by global dimming. Climate modelers speculatively suggest that this reduction in solar radiation at the surface may have led to the failure of the monsoon in sub-Saharan Africa during the 1970s and 1980s, together with the associated famines such as the Sahel drought, caused by Northern hemisphere pollution cooling the Atlantic.[39] Because of this, the Tropical rain belt may not have risen to its northern latitudes, thus causing an absence of seasonal rains. This claim is not universally accepted and is very difficult to test. However a 2009 Chinese study of 50 years of continuous data found that though most parts of eastern China saw no significant change in the amount of water held by the atmosphere light rains had decreased.[4] The researchers then modeled the effect of aerosols and also concluded the overall effect was that water drops in polluted cases are up to 50 percent smaller than in pristine skies. They concluded smaller size impedes the formation of rain clouds, and the falling of light rain is beneficial for agriculture. This was a different effect than reducing solar irradiance, but still a direct result from the presence of aerosols.

The 2001 study by researchers at the Scripps Institution of Oceanography concluded that the imbalance between global dimming and global warming at the surface leads to weaker turbulent heat fluxes to the atmosphere. This means globally reduced evaporation and hence precipitation occur in a dimmer and warmer world, which could ultimately lead to a more humid atmosphere in which it rains less.[40]

A natural form of large scale environmental shading/dimming has been identified that affected the 2006 northern hemisphere hurricane season. The NASA study found that several major dust storms in June and July in the Sahara desert sent dust drifting over the Atlantic Ocean and through several effects caused cooling of the waters, thus dampening the development of hurricanes.[41][42]

Relationship to global warming

Further information: Global warming

Some scientists now consider that the effects of global dimming have masked the effect of global warming to some extent and that resolving global dimming may therefore lead to increases in predictions of future temperature rise.[43] According to Beate Liepert, "We lived in a global warming plus a global dimming world and now we are taking out global dimming. So we end up with the global warming world, which will be much worse than we thought it will be, much hotter."[44] The magnitude of this masking effect is one of the central problems in climate change with significant implications for future climate changes and policy responses to global warming.[43]

Interactions between the two theories for climate modification have also been studied, as global warming and global dimming are neither mutually exclusive nor contradictory. In a paper published on March 8, 2005 in the American Geophysical Union's Geophysical Research Letters, a research team led by Anastasia Romanou of Columbia University's Department of Applied Physics and Mathematics, New York, also showed that the apparently opposing forces of global warming and global dimming can occur at the same time.[45] Global dimming interacts with global warming by blocking sunlight that would otherwise cause evaporation and the particulates bind to water droplets. Water vapor is the major greenhouse gas. On the other hand, global dimming is affected by evaporation and rain. Rain has the effect of clearing out polluted skies.

Brown clouds have been found to amplify global warming according to Veerabhadran Ramanathan, an atmospheric chemist at the Scripps Institution of Oceanography in La Jolla, CA. "The conventional thinking is that brown clouds have masked as much as 50 percent of global warming by greenhouse gases through so-called global dimming... While this is true globally, this study reveals that over southern and eastern Asia, the soot particles in the brown clouds are in fact amplifying the atmospheric warming trend caused by greenhouse gases by as much as 50 percent."[46]

Possible use to mitigate global warming

Further information: Solar radiation management, Mitigation of global warming and Albedo

Some scientists have suggested using aerosols to stave off the effects of global warming as an emergency geoengineering measure.[47] In 1974, Mikhail Budyko suggested that if global warming became a problem, the planet could be cooled by burning sulfur in the stratosphere, which would create a haze.[48][49] An increase in planetary albedo of just 0.5 percent is sufficient to halve the effect of a CO2 doubling.[50]

The simplest solution would be to simply emit more sulfates, which would end up in troposphere - the lowest part of the atmosphere. If this were done, Earth would still face many problems, such as:

The solution advocated is transporting sulfates into the next higher layer of the atmosphere - stratosphere. Aerosols in the stratosphere last years instead of weeks - so only a relatively smaller (though still large) amount of sulfate emissions would be necessary, and side effects would be less. This would require developing an efficient way to transport large amounts of gases into stratosphere, many of which have been proposed though none are known to be effective or economically viable.[52]

In a blog post, Gavin Schmidt stated that "Ideas that we should increase aerosol emissions to counteract global warming have been described as a 'Faustian bargain' because that would imply an ever increasing amount of emissions in order to match the accumulated greenhouse gas in the atmosphere, with ever increasing monetary and health costs."[53]

See also

References

  1. 1.0 1.1 Hegerl, G. C.; Zwiers, F. W.; Braconnot, P. et al. (2007). "Chapter 9, Understanding and Attributing Climate Change Section 9.2.2 Spatial and Temporal Patterns of the Response to Different Forcings and their Uncertainties". In Solomon, S.; Qin, D.; Manning, M.; Chen, Z.; Marquis, M.; Averyt, K.B.; Tignor, M.; Miller, H.L. Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Intergovernmental Panel on Climate Change. Cambridge, United Kingdom and New York, NY, USA.: Cambridge University Press. Retrieved 2008-04-13. See 9.2.2.2
  2. Keneth L. Denman and Guy Brasseur et al. (2007). "Couplings between changes in Climate System and the Biogeochemistry, 7.5.3" (PDF). IPCC. Retrieved 2008-04-09.
  3. "The Physical Basis for Seeding Clouds". Atmospherics Inc. 1996. Retrieved 2008-04-03.
  4. 4.0 4.1 Yun Qian, Daoyi Gong et al. (2009). "The Sky Is Not Falling: Pollution in eastern China cuts light, useful rainfall". Pacific Northwest National Laboratory. Retrieved 2009-08-16.
  5. Budyko, M.I. (1969). "The effect of solar radiation variations on the climate of the Earth". Tellus 21 (5): 611–619. doi:10.1111/j.2153-3490.1969.tb00466.x.
  6. Rasool, Ichtiaque, S. and Schneider, Stephen H. (July 1971). "Atmospheric Carbon Dioxide and Aerosols: Effects of Large Increases on Global Climate". Science 173 (3992): 138–141. Bibcode:1971Sci...173..138R. doi:10.1126/science.173.3992.138. PMID 17739641.
  7. Lockwood, John G. (1979). Causes of Climate. Lecture notes in mathematics 1358. New York: John Wiley & Sons. p. 162. ISBN 0-470-26657-0.
  8. Ohmura, A. and Lang, H. (June 1989). Lenoble, J. and Geleyn, J.-F. (Eds), ed. Secular variation of global radiation in Europe. In IRS '88: Current Problems in Atmospheric Radiation, A. Deepak Publ., Hampton, VA. , Hampton, VA: Deepak Publ. pp. (635) pp. 298–301. ISBN 978-0-937194-16-4.
  9. Russak, V. (1990). "Trends of solar radiation, cloudiness and atmospheric transparency during recent decades in Estonia". Tellus B 42 (2): 206–210. Bibcode:1990TellB..42..206R. doi:10.1034/j.1600-0889.1990.t01-1-00006.x. 1990TellB..42..206R.
  10. Liepert, B. G., P. Fabian et al. (1994). "Solar radiation in Germany - Observed trends and an assessment of their causes. Part 1. Regional approach". Contr. Atm. Physics 67: 15–29.
  11. Abakumova, G.M. et al. (1996). "Evaluation of long-term changes in radiation, cloudiness and surface temperature on the territory of the former Soviet Union" (PDF). Journal of Climate 9 (6): 1319–1327. Bibcode:1996JCli....9.1319A. doi:10.1175/1520-0442(1996)009<1319:EOLTCI>2.0.CO;2.
  12. 12.0 12.1 Stanhill, G. and Moreshet, S. (2004-11-06). "Global radiation climate changes in Israel". Climatic Change 22 (2): 121–138. doi:10.1007/BF00142962.
  13. 13.0 13.1 "Earth lightens up". Pacific Northwest National Laboratory. Retrieved May 8, 2005.
  14. Eddy, John A. Gilliland, Ronald L. & Hoyt, Douglas V. (1982-12-23). "Changes in the solar constant and climatic effects". Nature 300 (5894): 689–693. Bibcode:1982Natur.300..689E. doi:10.1038/300689a0. Spacecraft measurements have established that the total radiative output of the Sun varies at the 0.1−0.3% level
  15. H. Gilgen, M. Wild, and A. Ohmura (1998). "Means and trends of shortwave irradiance at the surface estimated from global energy balance archive data" (PDF). Journal of Climate 11 (8): 2042–2061. Bibcode:1998JCli...11.2042G. doi:10.1175/1520-0442-11.8.2042.
  16. 16.0 16.1 Stanhill, G. and S. Cohen (2001). "Global dimming: a review of the evidence for a widespread and significant reduction in global radiation with discussion of its probable causes and possible agricultural consequences". Agricultural and Forest Meteorology 107 (4): 255–278. doi:10.1016/S0168-1923(00)00241-0.
  17. Liepert, B. G. (2002-05-02). "Observed Reductions in Surface Solar Radiation in the United States and Worldwide from 1961 to 1990" (PDF). Geophysical Research Letters 29 (12): 1421. Bibcode:2002GeoRL..29j..61L. doi:10.1029/2002GL014910.
  18. Wild, Martin; Trüssel, Barbara; Ohmura, Atsumu; Long, Charles N.; König-Langlo, Gert; Dutton, Ellsworth G.; Tsvetkov, Anatoly (2009-05-16). "Global dimming and brightening: An update beyond 2000". Journal of Geophysical Research Atmospheres 114: D00D13. Bibcode:2009JGRD..11400D13W. doi:10.1029/2008JD011382.
  19. R. E. Carnell, C. A. Senior (April 1998). "Changes in mid-latitude variability due to increasing greenhouse gases and sulphate aerosols". Climate Dynamics Springer Berlin / Heidelberg 14 (5): 369–383. Bibcode:1998ClDy...14..369C. doi:10.1007/s003820050229.
  20. Adam, David (2003-12-18). "Goodbye sunshine". Guardian News and Media Limited. Retrieved 2009-08-26.
  21. 21.0 21.1 Roderick, Michael L. and Farquhar, Graham D. (2002). "The Cause of Decreased Pan Evaporation over the Past 50 Years". Science 298 (5597): 1410–1411. Bibcode:2002Sci...298.1407D. doi:10.1126/science.1075390. PMID 12434057.
  22. Liu B., Xu M., Henderson M. & Gong W. (2004). "A spatial analysis of pan evaporation trends in China, 1955-2000". Journal of Geophysical Research 109 (D15): D15102. Bibcode:2004JGRD..10915102L. doi:10.1029/2004JD004511.
  23. Sington, David (January 15, 2005). "TV&Radio follow-up". BBC - Science & Nature - Horizon.
  24. Roderick, Michael L.; Leon D. Rotstayn; Graham D. Farquhar; Michael T. Hobbins (2007-09-13). "On the attribution of changing pan evaporation". Geophysical Research Letters 34 (17): L17403. Bibcode:2007GeoRL..3417403R. doi:10.1029/2007GL031166.
  25. Rotstayn L.D., Roderick M.L. & Farquhar G.D. (2006). "A simple pan-evaporation model for analysis of climate simulations: Evaluation over Australia" (PDF). Geophysical Research Letters 33 (17): L17403. Bibcode:2006GeoRL..3317715R. doi:10.1029/2006GL027114.
  26. 26.0 26.1 Travis, David J.; Carleton, Andrew M. & Lauritsen, Ryan G (2002). "Contrails reduce daily temperature range" (PDF). Nature 418 (6898): 601. Bibcode:2002Natur.418..601T. doi:10.1038/418601a. PMID 12167846.
  27. "Transported Black Carbon A Significant Player In Pacific Ocean Climate". Science Daily. 2007-03-15.
  28. J. Srinivasan et al. (2002). "Asian Brown Cloud – fact and fantasy" (PDF). Current Science 83 (5): 586–592.
  29. "Crichton's Thriller State of Fear: Separating Fact from Fiction". Retrieved 2006-06-12.
  30. "Nature Geoscience: Global and regional climate changes due to black carbon". Retrieved 2008-03-26.
  31. 31.0 31.1 "Global 'Sunscreen' Has Likely Thinned, Report NASA Scientists". NASA. 2007-03-15.
  32. Wild, M et al. (2005). "From Dimming to Brightening: Decadal Changes in Solar Radiation at Earth's Surface". Science 308 (2005–05–06): 847–850. Bibcode:2005Sci...308..847W. doi:10.1126/science.1103215. PMID 15879214.
  33. Wild, M., A. Ohmura, and K. Makowski (2007). "Impact of global dimming and brightening on global warming". Geophysical Research Letters 34 (4): L04702. Bibcode:2007GeoRL..3404702W. doi:10.1029/2006GL028031.
  34. Pinker; Zhang, B; Dutton, EG et al. (2005). "Do Satellites Detect Trends in Surface Solar Radiation?". Science 308 (6 May 2005): 850–854. Bibcode:2005Sci...308..850P. doi:10.1126/science.1103159. PMID 15879215.
  35. "Global Dimming may have a brighter future". Retrieved 2006-06-12.
  36. Richard A. Kerr (2007-03-16). "Climate change: Is a Thinning Haze Unveiling the Real Global Warming?". Science 315 (5818): 1480. doi:10.1126/science.315.5818.1480. PMID 17363636.
  37. "Air Emissions Trends - Continued Progress Through 2005".
  38. Cat Lazaroff (2007-12-07). "Aerosol Pollution Could Drain Earth's Water Cycle". Environment News Service.
  39. Rotstayn and Lohmann; Lohmann, Ulrike (2002). "Tropical Rainfall Trends and the Indirect Aerosol Effect". Journal of Climate 15 (15): 2103–2116. Bibcode:2002JCli...15.2103R. doi:10.1175/1520-0442(2002)015<2103:TRTATI>2.0.CO;2.
  40. Kostel, Ken and Oh, Clare (2006-04-14). "Could Reducing Global Dimming Mean a Hotter, Dryer World?". Lamont–Doherty Earth Observatory News. Retrieved 2006-06-12.
  41. "Study ties hurricanes to Sahara". United Press International. 2007-04-03.
  42. "Did Dust Bust the 2006 Hurricane Season Forecasts?". NASA. 2007-03-28.
  43. 43.0 43.1 Andreae O. M., Jones C. D., Cox P. M. (2005). "Strong present-day aerosol cooling implies a hot future". Nature 435 (7046): 1187–1190. Bibcode:2005Natur.435.1187A. doi:10.1038/nature03671. PMID 15988515.
  44. "Global Dimming". BBC. Retrieved 6 April 2009.
  45. Alpert, P., P. Kishcha, Y. J. Kaufman, and R. Schwarzbard (2005). "Global dimming or local dimming?: Effect of urbanization on sunlight availability". Geophys. Res. Lett. 32 (17): L17802. Bibcode:2005GeoRL..3217802A. doi:10.1029/2005GL023320.
  46. National Science Foundation (2007-08-01). ""Brown Cloud" Particulate Pollution Amplifies Global Warming". Retrieved 2008-04-03.
  47. William J. Broad (27 June 2006). "How to Cool a Planet (Maybe)". The New York Times. Retrieved 6 April 2009.
  48. Spencer Weart (July 2006). "Aerosols: Effects of Haze and Cloud". The Discovery of Global Warming. American Institute of Physics. Retrieved 6 April 2009.
  49. Crutzen, P. (August 2006). "Albedo enhancement by stratospheric sulfur injections: a contribution to resolve a policy dilemma?" (PDF). Climatic Change 77 (3–4): 211–220. doi:10.1007/s10584-006-9101-y.
  50. Ramanathan, V. (1988-04-15). "The greenhouse theory of climate change: a test by an inadvertent global experiment". Science 240 (4850): 293–299. Bibcode:1988Sci...240..293R. doi:10.1126/science.240.4850.293. PMID 17796737.
  51. 51.0 51.1 51.2 51.3 Ramanathan, V. (2006). "Atmospheric Brown Clouds: Health, Climate and Agriculture Impacts" (PDF). Pontifical Academy of Sciences Scripta Varia (Pontifica Academia Scientiarvm) 106 (Interactions Between Global Change and Human Health): 47–60.
  52. "RealClimate: Global Dimming?". 2005-01-18. Retrieved 2007-04-05.

External links

Wikinews has related news: PBS show asserts greenhouse gases, atmospheric pollutants dimming future
Wikibooks has a book on the topic of: Climate Change