CLIMATE REMES MARY nepgif' fl_ 7' I. World Meteorological Organization Weather - Climate -Water WMO-N0. 1119 WMO-No. 1119 (C) World Meteorological Organization, 2013 The right of publication in print, electronic and any other form and in any language is reserved by WMO. Short extracts from WMO publications may be reproduced without authorization, provided that the complete source is clearly indicated. Editorial correspondence and requests to publish, reproduce or translate this publication in part or in whole should be addressed to: Chair, Publications Board World Meteorological Organization (WMO) 7 bis, avenue de la Paix P.O. Box 2300 CH-1211 Geneva 2, Switzerland Tel.: +41 (0) 22 730 84 03 Fax: +41 (0) 22 730 80 40 E-mail: publications@wmo.int ISBN 978-92-63-11119-7 NOTE The designations employed in WMO publications and the presentation of material in this publication do not imply the expression of any opinion whatsoever on the part of WMO concerning the legal status of any country, territory, city or area, or of its authorities, or concerning the delimitation of its frontiers or boundaries. The mention of specific companies or products does not imply that they are endorsed or recommended by WMO in preference to others of a similar nature which are not mentioned or advertised. The findings, interpretations and conclusions expressed in WMO publications with named authors are those of the authors alone and do not necessarily reflect those of WMO or its Members. THE GLOBAL CLIMATE 2001-2010 A DECADE 0F CLIMATE EXTREMES SUMMARY REPORT Foreword The first decade of the 21st century was the warmest decade recorded since modern measurements began around 1850. It saw above-average precipitation, including one year - 2010 - that broke all previous records. It was also marked by dramatic climate and weather extremes such as the European heatwave of 2003, the 2010 floods in Pakistan, hurricane Katrina in the United States of America (USA), cyclone Nargis in Myanmar and long-term droughts in the Amazon Basin, Australia and East Africa. Many of these events and trends can be explained by the natural variability of the climate system. Rising atmospheric concentrations of greenhouse gases, however, are also affecting the climate. Detecting the respective roles being played by climate variability and humaninduced climate change is one of the key challenges facing researchers today. The World Meteorological Organization (WMO) is proud to be a major contributor to international efforts to better understand our climate. We sponsor or co-sponsor leading research and observation programmes, notably the WMO Global Atmosphere Watch, the World Climate Research Programme, the Global Climate Observing System and the Intergovernmental Panel on Climate Change. We also produce an annual statement - Status of the Global Climate - based on the WMO Climate System Monitoring network. This international collaboration facilitates the gathering of data from the world's leading climate data, monitoring and research centres. These data, together with climate information collected through a unique survey among the world's National Meteorological and Hydrological Services, were also used to produce the decadal report The Global Climate 2001-2010. A decadal perspective makes it possible to assess trends and anticipate the future. It can also inform efforts to develop operational climate services that provide information and forecasts for decision-making in agriculture, health, disaster risk, water resources and other sectors. These efforts are being coordinated through the WMO-led Global Framework for Climate Services. To learn more about the 2001-2010 decade of extremes, including the detailed results of the WMO survey of countries, you are strongly encouraged to read the complete technical report (WMO-No. 1103), which is available online on the WMO website. (M. Jarraud) Secretary-General 1. Climate variability and climate change The Earth's climate fluctuates over seasons, decades and centuries in response to both natural and human variables. Natural climate variability on different timescales is caused by cycles and trends in the Earth's orbit, incoming solar radiation, the atmosphere's chemical composition, ocean circulation, the biosphere and much more. Climate change refers to long-term changes in the average state of the climate and can also be due to natural factors. The rapid changes that have occurred since the middle of the past century, however, have been caused largely by humanity's emissions of greenhouse gases into the atmosphere. Other human activities also affect the climate system, including emissions of pollutants and other aerosols, and changes to the land surface, such as urbanization and deforestation. Short-term natural climate variability can often be linked to recurring patterns of atmospheric pressure and ocean circulation. El Ni?o and La Ni?a episodes, for example, result from rapid changes in the sea-surface temperature in the equatorial Pacific Ocean. They influence weather patterns around the world through the subsequent large-scale interactions and transfers of heat in the coupled oceanatmosphere system. Other patterns affect the climate by strengthening or weakening high-altitude air currents known as jet streams. The decade 2001-2010 did not experience a major El Ni?o event, which is normally associated with a warming of the global climate (as occurred for example in the then-record warm year of 1998). La Ni?a and neutral conditions prevailed until mid-2006, followed by a brief El Ni?o. Cool La Ni?a Table 1. Mixing ratio of carbon dioxide, methane and nitrous oxide in 2010 and the decadal values for 1991-2000 and 2001-2010 2 2010 conditions returned from late 2007, a brief El Ni?o appeared from June 2009 and then a strong La Ni?a episode started in mid-2010. This short-term natural variability may have masked some of the effects of long-term climate change. The closely related Arctic Oscillation and North Atlantic Oscillation often affect the northern hemisphere winter. Since the 1990s, these two oscillations have remained mostly in a positive phase, which is associated with warmer and wetter winters in northern and central Europe and the eastern USA, drier winters in the Mediterranean and cold, dry conditions over northern Canada and Greenland. The winter of 2009/2010, however, saw extremely negative phases with low winter temperatures in northern and central Europe. Unli ke t h e s e n a t ur al b a c k- a n d - f o r t h oscillations, human-caused climate change is trending in just one direction. This is because atmospheric concentrations of carbon dioxide, methane, nitrous oxide and other greenhouse gases are increasing steadily, due to human activities. According to the WMO Greenhouse Gas Bulletin, global-average atmospheric concentrations of carbon dioxide rose to 389 ppm1 in 2010 (an increase of 39 per cent compared to pre-industrial times), methane to 1 808.0 ppb1 (158 per cent) and nitrous oxide to 323.2 ppb (20 per cent). This changing composition of the atmosphere is causing the global average temperature to rise, which, in turn, exerts a significant influence on the hydrological cycle and leads to other changes in climate and weather patterns. Humanity's emissions of chlorofluorocarbons and other chemicals have also changed the ______ 1 ppm = parts per million; ppb = parts per billion Increase since preindustrial times 1991-2000 2001-2010 Carbon dioxide 389 ppm 39% 361.5 ppm 380 ppm Methane 1 808 ppb 158% 1 758 ppb 1 790 ppb Nitrous oxide 323.2 ppb 20% 312.2 ppb 319.7 ppb atmosphere by damaging the stratospheric ozone layer that filters out harmful ultraviolet radiation. Fortunately, the phase-out of ozonedepleting substances under the Montreal Protocol should allow the ozone layer to recover in a few decades. The Antarctic ozone hole is believed to influence the Southern Annular Mode oscillation and thus the regional climate. Meanwhile, emissions of reactive gases (such as nitrogen oxides and sulphur dioxide) and aerosols (such as dust and black carbon) also interact with the climate, for example by increasing the health impacts of heatwaves. 2. The warmest decade The period 2001-2010 was the warmest decade on record since modern meteorological records began around the year 1850. The global average temperature of the air above the Earth's surface over the 10-year period is estimated to have been 14.47?C ? 0.1?C. This is 0.47?C ? 0.1?C above the 1961-1990 global average of +14.0?C and +0.21 ? 0.1?C above the 1991-2000 global average. It is 0.88?C higher than the average temperature of the first decade of the 20th century (1901-1910). A pronounc ed increase in the global temperature occurred over the four decades 1971-2010. The global temperature increased at an average estimated rate of 0.17?C per decade during that period, while the trend over the whole period 1880-2010 was only 0.0 62?C per decade. Fur thermore, the increase of 0.21?C in the average decadal temperature from 1991-2000 to 2001-2010 is larger than the increase from 1981-1990 to 1991-2000 (+0.14?C) and larger than for any other two successive decades since the beginning of instrumental records. Nine of the decade's years were among the 10 warmest on record. The warmest year ever recorded was 2010, with a mean Temperature anomaly (?C) Warmest/least Domain 2001-2010 (A) warm year during 2001-2010 (B) Land hemisphere +0.90?C Ocean +0.41?C +0.60?C Land Southern +0.47?C Land-ocean hemisphere +0.35?C Land Northern Ocean Land-ocean Global +0.79?C +0.48?C Ocean +0.29?C Land-ocean +0.33?C Warmest/coldest decade on record (C) 2007 (+0.95?C) 2001-2010 (+0.79?C) 2001 and 2004 (+0.68?C) 1881-1890 (-0.51?C) 2003 (+0.40?C) 2001-2010 (+0.35?C) 2008 (+0.26?C) 1901-1910 (-0.45?C) 2010 (+0.54?C) 2001-2010 (+0.47?C) 2008 (+0.35?C) 1901-1910 (-0.45?C) 2007 (+1.13?C) 2001-2010 (+0.90?C) 2004 (+0.76?C) 1881-1890 (-0.52?C) 2005 (+0.47?C) 2001-2010 (+0.41?C) 2008 (+0.33?C) 1901-1910 (-0.39?C) 2010 (+0.69?C) 2001-2010 (+0.60?C) 2008 (+0.53?C) 1901-1910 (-0.38?C) 2005 (+0.67?C) 2001-2010 (+0.48?C) 2001 (+0.34?C) 1901-1910 (-0.53?C) 2002 (+0.34?C) 2001-2010 (+0.29?C) 2008 (+0.20?C) 1901-1910 (-0.51?C) 2009 (+0.38?C) 2001-2010 (+0.33?C) 2008 (+0.24?C) 1901-1910 (-0.51?C) Table 2. Surface temperature anomalies with respect to 1961- 1990: over the globe, northern hemisphere and southern hemisphere for 2001-2010 (A), annual extreme values for 2001-2010 (B) and decadal extreme values for 1881-2010 (C) (source: UK Met Office and US National Oceanic and Atmospheric Administration (NOAA) for global analyses combined; NOAA-National Climate Date Center (NCDC) for the northern and southern hemispheres) 3 temperature anomaly estimated at 0.54?C above the 14.0?C baseline, followed closely by 2005. The least warm year was 2008, with an estimated anomaly of +0.38?C, but this was enough to make 2008 the warmest La Ni?a year on record. T he 2 0 01 - 2 010 d e c a d e wa s al s o the warmest on record for both land-only and ocean- only sur face temperatures. The warmest worldwide land-only surface-air temperature was recorded in 2007, with a temperature anomaly of + 0.95?C. The warmest worldwide ocean-only surface temperature was measured in 2003, with an anomaly of +0.4?C above the 1961-1990 average. This is consistent with climatechange science, which projects that the ocean surface will warm more slowly than the land because much of the additional heat will be transported down into the ocean depths or lost through evaporation. 4 Europ e ex p erien c e d above - normal temperatures bet ween 2001 and 2009, with 2007 the warmest year on record for large parts of the region. Europe, including Greenland, saw a median temperature anomaly of +1.0?C for the decade. Greenland recorded the world's largest decadal mean temperature anomaly of +1.71?C. Much of Asia also saw anomalies exceeding +1?C over the course of the decade, including China, the Islamic Republic of Iran, Mongolia and the Russian Federation. For the whole continent the median temperature anomaly of the decade was +0.84?C. 14.500 14.47 14.26 14.225 Global temperature (?C) Figure 1. Decadal global combined surface-air temperature over land and sea-surface temperature (?C) obtained from the average over the three independent datasets maintained by the UK Met Office Hadley Centre and the Climatic Research Unit, University of East Anglia, in the United Kingdom (HadCRU), NOAA-National Climatic Data Center (NCDC) and the US National Aeronautics and Space Administration-Goddard Institute for Space Studies (NASA-GISS). The horizontal grey line indicates the longterm average value for 1961-1990 (14?C). When considered region by region, most areas of the world also experienced aboveaverage temperatures during the decade, particularly in 2010, when records were broken by over +1?C in some areas. At the national level, a large majority of countries responding to the WMO survey reported tha t they ex p erien c e d their warme s t decade on record. Many geographically large countries and regions saw decadal temperature anomalies over 2001-2010 that exceeded +1?C relative to the long-term average of 1961-1990. 14.12 13.95 13.950 13.89 13.92 13.93 13.95 1951 1960 1961 1970 1971 1980 13.76 13.675 13.68 13.67 13.64 13.59 13.400 1881 1891 1901 1911 1890 1900 1910 1920 1921 1931 1930 1940 1941 1950 1981 1990 1991 2000 2001 2010 Figure 2. Annual global surface temperature anomaly for 1950-2010 with reference to the 1961-1990 base period, indicating the years with La Ni?a events (blue) and those with El Ni?o events (red) (source: HadCRU, NOAA-NCDC and NASA-GISS ) 0.6 0.5 0.4 0.3 0.2 0.1 0 -0.1 -0.2 -0.3 1950 1956 1962 1968 1974 Africa experienced warmer-than-normal conditions in every year of the decade. The highest temperature anomalies occurred in countries north of the Equator. South of the Equator, Angola, Botswana, Madagascar, Namibia, South Africa and Zimbabwe confirmed temperature anomalies in the range of + 0.5?C to +1?C. The median temperature anomaly of the decade in Africa was +0.7?C The largest country in South America, Brazil, recorded the continent's highest temperature anomaly value of + 0.74 ?C, making the decade the warmest on record there. The median value of the decadal temperature anomalies started to turn positive in 1981-1990 and reached +0.60?C in 2001-2010. 1980 1986 1992 1998 2004 2010 highest anomaly of +1.3?C, making 2001-2010 the country's warmest decade. In Oceania, Australia, French Polynesia, New Caledonia, New Zealand and Tonga reported positive temperature anomalies in the last two decades, with a median value of +0.34?C for the 2001-2010 decade. In Australia, the largest country of the region, 2001-2010 was the warmest decade ever, with an anomaly value of +0.48?C. As shown in Figures 1 and 2, the decade 2001- 2010 continued the upward trend in global temperatures, despite the cooling effects of multiple La Ni?a episodes and other natural year-to-year variability. 3. Hot and cold extremes In North and Central America, Canada and the contiguous USA and Alaska, which together constitute by far the region's largest land area, recorded a combined average temperature anomaly greater than +0.5?C. On its own, Canada recorded the region's While the average annual temperature is an important climate indicator, the temperatures that people experience can differ greatly from day to day and over the course of a year because of natural climate variability. At the 5 Extreme events, vulnerability, exposure and disasters Monitoring and understanding extreme events is important because these events often destroy lives and property. Extreme events can, however, be prevented from becoming major disasters by reducing people's vulnerability and exposure. were fewer deaths due to storms and floods in 2001-2010 compared to 1991-2000, with decreases of 16 per cent and 43 per cent, respectively, thanks, in good part, to better early warning systems and increased preparedness. While databases on disasters are useful for mapping the behaviour and impact of extremes in various regions, the data do not demonstrate that the increase in observed losses is caused by an increase in the frequency and intensity of extreme events. Other factors come into play, notably the increased exposure of people and property to climate extremes and the improved and increased reporting of disasters. There were fewer deaths, even while exposure to extreme events increased as populations grew and more people were living in disaster-prone areas. According to the 2011 Global Assessment Report, the average population exposed to flooding every year increased by 114 per cent globally between 1970 and 2010, a period in which the world's population increased by 87 per cent from 3.7 billion to 6.9 billion. The number of people exposed to severe storms almost tripled in cyclone-prone areas, increasing by 192 per cent, in the same period. Nevertheless, it is worth noting the very large increase (more than 2 000 per cent) in the loss of life from heatwaves, particularly during the unprecedented extreme heat events that affected Europe in the summer of 2003 and the Russian Federation in the summer of 2010. On the other hand, there While the risk of death and injury from storms and floods declined, the vulnerability of property increased. This is because the expansion of socio-economic and infrastructural assets led to an increase in the amount and value of property exposed to weather and climate extremes. 400 000 Casualties 2001-2010 300 000 Figure 3. Impact of extreme events during 2001-2010 compared with 1991-2000: total number of lives lost. The change in per cent from 1991-2000 to 2001-2010 is shown above the bars. (data source: EM-DAT/CRED) 6 +20% Casualties 1991-2000 350 000 250 000 -16% 200 000 150 000 2 300% -43% 100 000 50 000 189% 0 Heat -66% Cold Drought Storms (all) Floods Total same time, human influence has probably increased the maximum temperatures of the most extreme hot nights and days and the minimum temperatures of cold nights and cold days. It is also more likely than not that human-induced climate change has increased the risk of heatwaves. According to the WMO survey, a total of 56 countries (44 per cent) reported their highest absolute daily maximum temperature record over the period 1961-2010 being observed in 2001-2010 compared to 24 per cent in 1991- 2000, with the remaining 32 per cent spread over the earlier three decades. Conversely, 11 per 50% cent (14 out of 127) of the countries reported their absolute daily minimum temperature record being observed in 2001-2010, compared to 32 per cent in 1961-1970 and around 20 per cent in each of the intermediate decades (Figure 4). Over the course of the 2001-2010 decade, many countries and regions suffered heatwaves at one time or another (Figure 5). Some of the most dramatic included two severe heatwaves in India in 2002 and 2003, which each killed over 1 000 people; the 2003 summer heatwave over much of Europe, which caused more than 66 000 deaths; and the exceptionally Highest maximum temperature 40% 30% 20% 10% 0% 50% 1961-1970 1971-1980 1981-1990 1991-2000 2001-2010 Lowest minimum temperature 40% 30% 20% 10% 0% 50% 1961-1970 1971-1980 1981-1990 1991-2000 2001-2010 Highest 24-h precipitation 40% 30% 20% 10% 0% 1961-1970 1971-1980 1981-1990 1991-2000 2001-2010 Figure 4. Absolute country records of the daily maximum and minimum temperature and 24-hour total precipitation in the last five decades (source: WMO survey) 7 Europe Much of Europe was affected by Canada several extreme heatwaves Central Canada experienced its warmest and most humid summer on record in 2005. 2010 was the warmest year on record for the nation as a whole since records began in 1948. during summer 2003. Northern Africa During July and August 2003, within the same atmospheric pattern that affected Europe, northern Africa experienced record warmth. In Morocco new monthly records were set in several areas. USA The heat was most severe in August when A severe heatwave gripped the south-western USA during July 2005, setting numerous temperature records. Another severe heatwave persisted throughout August 2007 across the southern and central part of the USA, several cities recorded the highest daily maximum temperature ever measured. Some of these records were set in Rabat (44.6?C), Kenitra (47.7?C) and Tangier (43.5?C). with several new all-time high temperature records established. Western Africa Extreme heat was reported in western Africa during the boreal summer 2002. Brazil Heatwaves in Brazil from January to March 2006 were recorded and one of the highest temperatures ever Abnormally high temperatures were observed in the Sahara, as high as 50.6?C, during June and July 2002. measured (44.6?C) was registered in Bom Jesus on 31 January 2006. Argentina An extreme climate anomaly hit the region in late October/early South America November 2009 when an exceptional heatwave affected northern and As part of a persistent atmospheric blocking pattern, central Argentina. Unusually high temperatures of above an exceptionally hot February affected southern 40?C were recorded in many places and for several consecutive Argentina and Chile in 2008. Daily maximum days. Some annual absolute maximum temperature records were temperatures reached between 35?C and 40?C, broken during this period. well above the average, which ranges between 20?C and 28?C. intense and long-lasting heatwave that struck the Russian Federation in July/ August 2010, causing over 55 000 deaths. The WMO survey identifies many other abnormally high-temperature conditions, heatwaves and temperature records around the world. Despite the record average warmth of the decade, cold waves continued to cause intense suffering in many countries. Coinciding with the extreme negative phase of the Arctic Oscillation and North Atlantic Oscillation, the northern hemisphere endured extreme winter conditions from December 2009 to February 2010. Prolonged cold and snow 8 conditions across Europe resulted in over 450 deaths. The winter of 2009/2010 was also extremely cold in the Russian Federation, North America (particularly the USA) and parts of Asia. Other cold waves were experienced in the Plurinational State of Bolivia in 2002, southern Africa in 2002 and 2007, Peru in 2003, Morocco and Algeria in 2005, Australia in 2005, Asia in 2007/2008, and southern China in 2008. 4. Precipitation, floods and droughts In all parts of the world, precipitation, floods and droughts vary naturally from year to year and from decade to decade. In addition, Russian Federation As part of a blocking situation, extreme hot weather conditions affected the European part of the Russian Federation during July and August 2010. This led to disastrous bush fires in the Moscow region. In Moscow, July mean temperatures were 7.6?C above normal, making it the city's hottest month on record by more than 2?C. A new record high temperature for the city of 38.2?C was set on 29 July, and it reached 30?C or above on 33 consecutive days. China and Japan The months of August and September 2007 were extremely warm in Japan, setting a new national record of absolute maximum temperature of 40.9?C. In 2010, Japan and China had their hottest summer on record. Southern Asia Pakistan Extremely severe heatwaves hit India in 2002, 2003 and 2005. Pakistan and Bangladesh were affected In 2010, a pre-monsoon heatwave in May and June 2005 with maximum temperatures brought a record temperature of 53.5?C between 45?C and 50?C and hundreds of related deaths. to Mohenjo Daro on 26 May making a national record for Pakistan and the highest temperature in Asia since at least 1942. Australia Several heatwaves affected Australia during this decade, with disastrous bush fires as well as record temperatures. During summer 2009, Victoria reached its highest temperature with 48.8?C at Hopetown, the highest temperature ever recorded so far south anywhere in the world. because warm air can hold more moisture, it is likely that climate change has influenced the occurrence and intensity of extreme precipitation events. Greater warmth also speeds up the hydrological cycle, which should contribute to both heavier rainfall and increased evaporation. The largest number of national records for 24-hour extreme precipitation events, as reported in the WMO survey, occurred over the past two decades,1991-2010 (Figure 4). Global land-surface precipitation averaged over 2001-2010 was above the 1961-1990 average. It was the wettest decade since 1901, except for the 1950s (Figure 6). In addition, 2010 was the wettest year ever recorded at global level. The previous wettest years were 1956 and 2000, which, like the second half of 2010, coincided with strong La Ni?a events. Figure 5. Most significant heatwaves and abnormally high temperature conditions reported during 2001-2010 (source: NOAA-NCDC ) Most parts of the globe had above-normal precipitation (Figure 7). The eastern USA, northern and eastern Canada, and many parts of Europe and central Asia were particularly wet. Other wetter-than-average regions were northern and southern Brazil, Uruguay and northern and eastern Argentina, southern Africa, Indonesia and northern Australia. 9 Figure 6. Decadal global precipitation anomaly (in mm) relative to the 1961-1990 WMO standard normal (source: NOAA-NCDC ) 20 15 Precipitation anomaly (mm) 10 5 0 -5 -10 -15 -20 1901 1910 1911 1920 1921 1930 1931 1940 1941 1950 1951 1960 1961 1970 1971 1980 1981 1990 1991 2000 2001 2010 90N 60N 30N EQ Figure 7. Decadal precipitation anomalies for global land areas for 2001-2010; gridded 1? raingauge-based analysis as normalized departures in mm/year focusing on 1951-2000 base period (source: Global Precipitation Climatology Centre (GPCC), Deutscher Wetterdienst, Germany) 10 30S 60S 90S 180 120W 60W -350 -250 0 -150 -50 60E 50 150 120E 250 350 180 Regions that experienced below-normal precipitation included the western USA and Alaska, south-western Canada, central South America, most parts of southern and western Europe, central Africa, most parts of southern Asia and eastern and southeastern Australia. According to the WMO survey, floods were the most frequently experienced extreme event over the course of the decade. Eastern Europe was particularly affected in 2001 and 2005, India in 2005, Africa in 2008, Asia (notably Pakistan, where 2 000 people died and 20 million were affected) in 2010, and Australia, also in 2010. In addition, many flash floods with landslides were reported by other countries. Droughts affect more people than any other kind of natural disaster owing to their large scale and long-lasting nature. The decade 2001-2010 saw droughts occur in all parts of the world. Some of the highest-impact and long-term droughts struck Australia (in 2002 but also in other years), East Africa (2004 and 2005, resulting in widespread loss of life and food shortages) and the Amazon Basin (2010). 5. Severe storms According to NOAA-NCDC, 2001-2010 was the most active decade since 1855 for tropical cyclones in the North Atlantic Basin. An average of 15 named storms per year was recorded, well above the 1981-2010 long-term average of 12 named storms per year. In other regions, cyclone ac tivit y was generally at average or below-average levels. The eastern North Pacific basin saw 139 named storms during the decade, of which 65 were classified as hurricanes, slightly below the average. The majority of these tropical cyclones did not make landfall and did not cause substantial damage. The 230 tropical cyclones in the North-West Pacific were also slightly below average. The most destructive of these storms was Durian, which struck the Philippines in 2006, killing more than 1 000 people and affecting 1.5 million. The North Indian Ocean saw the deadliest tropical cyclone recorded during the decade, when Nargis s truck Myanmar in early May 2008. More than 138 000 people were reported killed or missing, eight million people were af fected and thousands of homes were destroyed. Extra-tropical storms can also turn into devastating natural disasters, mainly in midlatitude regions. Three major extra-tropical windstorms severely affected Europe: Kyrill struck several parts of central Europe in 2007; Klaus affected southern Europe in 2009 and Xynthia struck nor th-western Europe in 2010. These storms caused several billions of US dollars in damage and took nearly 100 lives. According to analyses by the insurance company Munich Re, winter storms in the USA and Canada in 2007 and 2008 rank among the 10 costliest storms since 1980 in terms of insured losses. 6. Shrinking ice and rising seas The most active season ever recorded was 2005, with a total of 27 named storms, of which 15 reached hurricane intensity and seven were classified as major hurricanes (Category 3 or higher). Katrina, a Category-5 hurricane, was the most devastating hurricane of the decade, making landfall in the southern USA in August. The record warmth of the decade 2001-2010 was accompanied by the melting of ice caps, sea ice and glaciers and the thawing of permafrost. In addition to being a sign of a warming climate, melting ice and snow also af fected water supplies, transpor t 11 Hurricane Bertha Hurricane Katrina (July 2008) (August 2005) Tropical storm Allison Maximum winds - 205 km/h. Longest-lived Atlantic July tropical cyclone on record. Maximum winds - 280 km/h Deadliest hurricane to strike the USA since 1928. (June 2001) Maximum winds - 95 km/h. Deadliest and costliest tropical storm on record in the USA. Hurricane Juan (September 2003) Maximum winds - 170 km/h. Worst hurricane to hit Halifax, Nova Scotia, in modern history. Tropical storm Fay Hurricane Rick (August 2008) (October 2009) Maximum winds - 110 km/h. First storm in recorded history to strike Florida (or any state) four times. Maximum winds - 270 km/h The second most intense hurricaneon record for the basin, behind Linda of 1997. Hurricane Kenna (October 2002) Maximum winds - 270 km/h. The strongest hurricane to strike Mexico from the Pacific since hurricane Madeline in 1976 and third strongest on record. Hurricane Lili Hurricane Wilma Hurricane Sergio (October 2005) Maximum winds - 295 km/h. The most intense Atlantic hurricane ever recorded. (November 2006) Maximum winds - 175 km/h. The longest-lived November tropical cyclone on record for the basin. Hurricane Michelle (October/November 2001) Tropical storm Alma (May 2008) Maximum winds - 100 km/h. The first eastern North Pacific basin tropical storm or hurricane to make landfall along the Pacific Coast of Central America since records began. Maximum winds - 220 km/h. Strongest hurricane to hit Cuba since hurricane Fox in October 1952. (September/October 2002) Maximum winds - 230 km/h. First hurricane to make landfall in the USA since hurricane Irene in 1999. Hurricane Ivan (September 2004) Maximum winds - 270 km/h. The most powerful storm to affect the Caribbean in 10 years. Hurricane Catarina (March 2004) Maximum winds - 155 km/h. The first documented South Atlantic Ocean hurricane since geostationary satellite records began in 1966. Cyclones maximum wind legend 63-118 km/h 119-153 km/h 154-177 km/h 178-209 km/h 210-249 km/h > 249 km/h routes, infrastructure, marine ecosystems and much more. The state of Arctic sea-ice cover in the 20th century is relatively well documented. Until the 1960s, sea ice covered 14-16 million km2 of the Arctic in late winter and 7-9 million km2 at the end of the northern summer. Since then it has declined rapidly. The five years with the lowest ever recorded sea-ice extent in September were 2005, 2007, 2008, 2009 and 2010. The record minimum extent of 4.28 12 million km2 - 39 per cent below the long-term average - occurred in 2007 (Figure 9). This record was broken in 2012. The estimated volume of Arctic sea ice has also been declining markedly since 2005, with a new record set in 2010. Meanwhile, Antarctic sea ice has expanded slightly overall, for reasons that continue to be investigated. The world's two major ice sheets (long-lived ice accumulated over landmass) are in the Antarctic and Greenland. The loss of net Typhoon Rananim (August 2004) Cyclone Gonu (June 2007) Maximum winds - 270 km/h. The worst tropical cyclone to hit Oman since 1945. Maximum winds - 165 km/h. Strongest typhoon to affect Zhejiang Province in China since 1956. Typhoon Kompasu (August/September 2010) Maximum winds - 195 km/h. Strongest typhoon to strike Seoul Republic of Korea in 15 years. Hurricane/typhoon Loke Typhoon Lekima (August/September 2006) (September/October 2007) Maximum winds - 260 km/h. The strongest hurricane ever recorded in the Central Pacific Ocean. Maximum winds - 130 km/h. Produced heavy rains across Viet Nam, resulting in its worst flooding in 45 years. Typhoon Tokage (October 2004) Maximum winds - 230 km/h Deadliest typhoon to strike Japan since 1979. Typhoon Durian (November 2006) Cyclone Laila Maximum sustained wind - 230 km/h. Near 1 200 deaths in the Philippines. (May 2010) Maximum winds - 120 km/h First may storm to affect south-eastern India in two decades. Cyclone Nargis (April/May 2008) Maximum winds - 215 km/h. The most devastating cyclone to hit Asia since 1991 and the worst natural disaster on record for Myanmar. Typhoon Megi (October 2010) Maximum winds - 295 km/h. The strongest tropical cyclone in the world since 2005 and the strongest in the North-West Pacific since 1983. Cyclone Ului (March 2010) Maximum winds - 260 km/h. One of the fastest intensifying tropical cyclones on record. Cyclone Dina (January 2002) Maximum winds - 240 km/h Responsible for setting a new 24-h precipitation record in Mauritius (745 mm). more details on Australia Maximum winds - 195 km/h. A new worldwide rainfall record was set in La R?union with 3929 mm measured in 3 days. (March 2006) Maximum winds - 215 km/h. The most intense cyclone to strike the Queensland coast since 1918. Cyclone Gam?de (February/March 2007) Cyclone Larry Cyclone Ingrid (March 2005) Maximum winds - 250 km/h. The first cyclone recorded to reach category 5 intensity off the coast of three different Australian states: Queensland, Northern Territory, and Western Australia. mass from both of these sheets has been accelerating, with the largest losses of the decade seen in 2007 and 2008. If this trend continues, ice sheets will contribute more to sea-level rise in the 21st century than any other factor. The world's glaciers lost more mass in 2001-2010 than in any decade since records began. Snow cover declined significantly in the northern hemisphere (Figures 10 and 11). The temperatures of permafrost (frozen land) areas have been rising, with the 2001-2010 decade marked by an increase in the thickness of the seasonal thaw layer in many northern areas. As a result of this widespread melting (and the thermal expansion of sea water), global mean sea levels continued to rise over the decade 2001-2010. The observed rate of increase was some 3 mm per year, about double the observed 20th century trend of 1.6 mm/yr. Global sea levels averaged over the decade were about 20 cm higher than those of 1880. Figure 8. Most significant tropical cyclones recorded during 2001-2010 (source: NOAA-NCDC ) 13 Figure 9. Sea-ice extent for September 2007; the magenta line indicates the long-term median from the 1979-2000 base period (left) and Arctic sea-ice extent at the end of the summer melt season from 2007 to 2010 (right) (source: National Snow and Ice Data Center, USA ) Extent (millions of square kilometres) 12 10 8 6 2010 2009 2008 2007 1979-2000 Average ?2 Standard deviations 4 2 August July September October November Figure 10. Mean cumulative specific glacier mass balance since 1945/1946 (source: World Glacier Monitoring Service) Mean cumulative specific mass balance (mm water equivalent) 15 000 10 000 5 000 0 -5 000 mean of 10 mountain ranges mean of 37 glaciers mean of all glaciers -10 000 -15 000 1945 1950 1955 1960 1965 1970 1975 1980 1985 1990 1995 2000 2005 2010 6 Figure 11. Northern hemisphere snowcover anomaly for June (1970-2010) (data source: Rutgers University Global Snow Laboratory, USA ). Note: No similar data exist for the southern hemisphere as the land area subject to seasonal snow cover (outside the Antarctic) is very small. 14 Snow-cover extent anomaly (millions square kilometres) 4 2 0 -2 -4 -6 1970 1974 1978 1982 1986 1990 1994 1998 2002 2006 2010 7. Conclusion Understanding the Earth's climate and trends in temperature, precipitation and extreme events is of vital importance to human wellbeing and sustainable development. As the report The Global Climate 2001-2010 confirms, climate scientists can now link some natural oscillations to seasonal climate trends. They also understand the mechanisms by which humanity's greenhouse-gas emissions are raising global average temperatures. While climate scientists believe that it is not yet possible to attribute individual extremes to climate change, they increasingly conclude that many recent events would have occurred in a different way - or would not have occurred at all - in the absence of climate change. For example, the likelihood of the 2003 European heatwave occurring was probably substantially increased by rising global temperatures. No clear trend has been found in tropical cyclones and extra-tropical storms at the global level. More complete datasets will be needed in order to perform robust analyses of trends in the frequency and intensity of these hazards. Distinguishing between natural climate variabilit y and human-induced climate change will also require datasets that are more complete and long-term. A decade is the minimum possible timeframe for detecting temperature changes. Assessing trends in extreme weather and climate events requires an even longer timeframe because, by definition, these events do not occur frequently. WMO's Commission for Climatology is currently addressing new approaches for the improved characterization, assessment and monitoring of these events. In addition, promising new research into the attribution of individual extreme events based on observational and model data is starting to emerge. Long-term cr yosphere monitoring has emerged as an urgent priority, both for climate research and for understanding the practical implications of the widespread melting. There are still uncertainties with respect to the future evolution of ice sheet melting. Understanding cryosphere variability will also help to improve sealevel rise projections, which, in turn, will contribute to more effective coastal planning and management. As observation, modelling and scientific understanding of the climate system advance, scientists will be able to provide increasingly useful information for decision-making. This will greatly benefit international cooperation through the United Nations Framework Convention on Climate Change and the Global Framework for Climate Services. WMO remains committed to supporting these efforts through its Members, its programmes and the regular reports made possible by the WMO Climate System Monitoring network. 15 For more information, please contact: World Meteorological Organization 7 bis, avenue de la Paix - P.O. Box 2300 - CH 1211 Geneva 2 - Switzerland Communications and Public Affairs Office E-mail: cpa@wmo.int www.wmo.int JN 13658 Tel.: +41 (0) 22 730 83 14 - Fax: +41 (0) 22 730 80 27