29 research outputs found

    The state of the Martian climate

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    60°N was +2.0°C, relative to the 1981–2010 average value (Fig. 5.1). This marks a new high for the record. The average annual surface air temperature (SAT) anomaly for 2016 for land stations north of starting in 1900, and is a significant increase over the previous highest value of +1.2°C, which was observed in 2007, 2011, and 2015. Average global annual temperatures also showed record values in 2015 and 2016. Currently, the Arctic is warming at more than twice the rate of lower latitudes

    State of the climate in 2018

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    In 2018, the dominant greenhouse gases released into Earth’s atmosphere—carbon dioxide, methane, and nitrous oxide—continued their increase. The annual global average carbon dioxide concentration at Earth’s surface was 407.4 ± 0.1 ppm, the highest in the modern instrumental record and in ice core records dating back 800 000 years. Combined, greenhouse gases and several halogenated gases contribute just over 3 W m−2 to radiative forcing and represent a nearly 43% increase since 1990. Carbon dioxide is responsible for about 65% of this radiative forcing. With a weak La Niña in early 2018 transitioning to a weak El Niño by the year’s end, the global surface (land and ocean) temperature was the fourth highest on record, with only 2015 through 2017 being warmer. Several European countries reported record high annual temperatures. There were also more high, and fewer low, temperature extremes than in nearly all of the 68-year extremes record. Madagascar recorded a record daily temperature of 40.5°C in Morondava in March, while South Korea set its record high of 41.0°C in August in Hongcheon. Nawabshah, Pakistan, recorded its highest temperature of 50.2°C, which may be a new daily world record for April. Globally, the annual lower troposphere temperature was third to seventh highest, depending on the dataset analyzed. The lower stratospheric temperature was approximately fifth lowest. The 2018 Arctic land surface temperature was 1.2°C above the 1981–2010 average, tying for third highest in the 118-year record, following 2016 and 2017. June’s Arctic snow cover extent was almost half of what it was 35 years ago. Across Greenland, however, regional summer temperatures were generally below or near average. Additionally, a satellite survey of 47 glaciers in Greenland indicated a net increase in area for the first time since records began in 1999. Increasing permafrost temperatures were reported at most observation sites in the Arctic, with the overall increase of 0.1°–0.2°C between 2017 and 2018 being comparable to the highest rate of warming ever observed in the region. On 17 March, Arctic sea ice extent marked the second smallest annual maximum in the 38-year record, larger than only 2017. The minimum extent in 2018 was reached on 19 September and again on 23 September, tying 2008 and 2010 for the sixth lowest extent on record. The 23 September date tied 1997 as the latest sea ice minimum date on record. First-year ice now dominates the ice cover, comprising 77% of the March 2018 ice pack compared to 55% during the 1980s. Because thinner, younger ice is more vulnerable to melting out in summer, this shift in sea ice age has contributed to the decreasing trend in minimum ice extent. Regionally, Bering Sea ice extent was at record lows for almost the entire 2017/18 ice season. For the Antarctic continent as a whole, 2018 was warmer than average. On the highest points of the Antarctic Plateau, the automatic weather station Relay (74°S) broke or tied six monthly temperature records throughout the year, with August breaking its record by nearly 8°C. However, cool conditions in the western Bellingshausen Sea and Amundsen Sea sector contributed to a low melt season overall for 2017/18. High SSTs contributed to low summer sea ice extent in the Ross and Weddell Seas in 2018, underpinning the second lowest Antarctic summer minimum sea ice extent on record. Despite conducive conditions for its formation, the ozone hole at its maximum extent in September was near the 2000–18 mean, likely due to an ongoing slow decline in stratospheric chlorine monoxide concentration. Across the oceans, globally averaged SST decreased slightly since the record El Niño year of 2016 but was still far above the climatological mean. On average, SST is increasing at a rate of 0.10° ± 0.01°C decade−1 since 1950. The warming appeared largest in the tropical Indian Ocean and smallest in the North Pacific. The deeper ocean continues to warm year after year. For the seventh consecutive year, global annual mean sea level became the highest in the 26-year record, rising to 81 mm above the 1993 average. As anticipated in a warming climate, the hydrological cycle over the ocean is accelerating: dry regions are becoming drier and wet regions rainier. Closer to the equator, 95 named tropical storms were observed during 2018, well above the 1981–2010 average of 82. Eleven tropical cyclones reached Saffir–Simpson scale Category 5 intensity. North Atlantic Major Hurricane Michael’s landfall intensity of 140 kt was the fourth strongest for any continental U.S. hurricane landfall in the 168-year record. Michael caused more than 30 fatalities and 25billion(U.S.dollars)indamages.InthewesternNorthPacific,SuperTyphoonMangkhutledto160fatalitiesand25 billion (U.S. dollars) in damages. In the western North Pacific, Super Typhoon Mangkhut led to 160 fatalities and 6 billion (U.S. dollars) in damages across the Philippines, Hong Kong, Macau, mainland China, Guam, and the Northern Mariana Islands. Tropical Storm Son-Tinh was responsible for 170 fatalities in Vietnam and Laos. Nearly all the islands of Micronesia experienced at least moderate impacts from various tropical cyclones. Across land, many areas around the globe received copious precipitation, notable at different time scales. Rodrigues and RĂ©union Island near southern Africa each reported their third wettest year on record. In Hawaii, 1262 mm precipitation at Waipā Gardens (Kauai) on 14–15 April set a new U.S. record for 24-h precipitation. In Brazil, the city of Belo Horizonte received nearly 75 mm of rain in just 20 minutes, nearly half its monthly average. Globally, fire activity during 2018 was the lowest since the start of the record in 1997, with a combined burned area of about 500 million hectares. This reinforced the long-term downward trend in fire emissions driven by changes in land use in frequently burning savannas. However, wildfires burned 3.5 million hectares across the United States, well above the 2000–10 average of 2.7 million hectares. Combined, U.S. wildfire damages for the 2017 and 2018 wildfire seasons exceeded $40 billion (U.S. dollars)

    IMPACT OF CLIMATE CHANGE ON IRRIGATED AGRICULTURE

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    WOS: 000289041100019The changes and the problems which will happen in relation to climate change, and the measures to be taken to reduce these problems constitute the most important global environmental problem of the century we are living in. In Turkey, water is the most critical resource for agricultural ecosystems. Variations in water resources and the advent of drought or increased runoff have significant implications for the water supply and for agriculture. Changes in water resources associated with climate change and their implications for agricultural production are also important for future water resources planning and agricultural sustainable development strategy. Drought has been a recurrent phenomenon in Turkey for the last several decades. The drought occurrences have been generally closely related to a lack of precipitation combined with high temperatures. A warming trend beginning in the early 1990s has dominated almost a decade and the annual mean temperatures have remained above average since 1995. These droughts have greatly affected water resources and thereby the agricultural sector. This sector, upon which the country's economy depends, is the biggest user of water resources, with a 74% share. Thus, when it comes to sharing and efficient use of water resources, the greatest pressure is on the agricultural sector. The effects of drought on agriculture can be seen as changes in crop patters, irrigation ratios, water quality and water management

    ОДНОС ИЗМЕЂУ NAO ИНДЕКСА, ĐœĐ ĐĐ—ĐĐ˜Đ„ ДАНА И Đ•ĐšĐĄĐąĐ Đ•ĐœĐĐ˜Đ„ И ĐĄĐ Đ•Đ”ĐŠĐ˜Đ„ ĐœĐĐšĐĄĐ˜ĐœĐĐ›ĐĐ˜Đ„ ВРИЈЕДНОСбИ бЕМПЕРАбУРЕ ĐŁ бУРСКОЈ

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    О ĐŸĐŽĐœĐŸŃŃƒ NAO ĐžĐœĐŽĐ”Đșса Đž паЎаĐČĐžĐœĐ° Đž срДЎњД Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ” у бурсĐșĐŸŃ˜ су ĐżŃ€ĐŸĐČĐ”ĐŽĐ”ĐœĐ” Đ±Ń€ĐŸŃ˜ĐœĐ” ŃŃ‚ŃƒĐŽĐžŃ˜Đ”(TĂŒrkoğlu et. al, 2006, TĂŒrkeƟ and Erlat, 2003). ĐŁ раЮу Ń›Đ”ĐŒĐŸ Đ°ĐœĐ°Đ»ĐžĐ·ĐžŃ€Đ°Ń‚Đž упраĐČĐŸ ĐŸĐČај ĐŸĐŽĐœĐŸŃ ŃƒŃŃ™Đ”ĐŽ ĐœĐ”ĐŽĐŸĐČĐŸŃ™ĐœĐžŃ…ĐżĐŸĐŽĐ°Ń‚Đ°ĐșĐ° ĐŸ утоцају NAO ĐžĐœĐŽĐ”Đșса ĐœĐ° Đ±Ń€ĐŸŃ˜ ĐŒŃ€Đ°Đ·ĐœĐžŃ… ĐŽĐ°ĐœĐ° Ń‚Đ” ĐœĐ° ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœŃƒ Đž ŃŃ€Đ”ĐŽŃšŃƒ ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœŃƒ Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Ńƒ.ĐŸĐ°Ń€Đ°ĐŒĐ”Ń‚Ń€Đž тДлДĐșĐŸĐœĐ”ĐșŃ†ĐžŃ˜Đ” у ĐŒĐ°ŃšĐŸŃ˜ ОлО ĐČĐ”Ń›ĐŸŃ˜ ĐŒŃ˜Đ”Ń€Đž уточу ĐœĐ° ĐłĐ»ĐŸĐ±Đ°Đ»ĐœŃƒ ĐșĐ»ĐžĐŒŃƒ Ń‚Đ” ĐœĐ° ŃšĐ”ĐœŃƒ ĐŽĐžŃ„Đ”Ń€Đ”ĐœŃ†ĐžŃ˜Đ°Ń†ĐžŃ˜Ńƒ ĐżŃ€Đ”ĐŒĐ°Ń€Đ”ĐłĐžĐŸĐœĐžĐŒĐ°. бурсĐșĐ° јД ŃƒĐŽĐ°Ń™Đ”ĐœĐ° ĐŸĐŽ ĐŸĐșĐ”Đ°ĐœĐ° Đ° ĐœĐ° ĐșĐ»ĐžĐŒŃƒ у ĐŸĐČĐŸŃ˜ Đ·Đ”ĐŒŃ™Đž ĐČОшД ŃƒŃ‚ĐžŃ‡Đ” NAO ĐœĐ”ĐłĐŸ ENSO (Sensoy et al,2011). Đ Đ°ĐŽ сД баĐČĐž ĐŒĐŸĐłŃƒŃ›ĐžĐŒ ŃƒŃ‚ĐžŃ†Đ°Ń˜ĐžĐŒĐ° NAO ĐžĐœĐŽĐ”Đșса (сјДĐČĐ”Ń€ĐœĐŸ-Đ°Ń‚Đ»Đ°ĐœŃ‚ŃĐșĐ” ĐŸŃŃ†ĐžĐ»Đ°Ń†ĐžŃ˜Đ”) ĐœĐ° Đ±Ń€ĐŸŃ˜ ĐŒŃ€Đ°Đ·ĐœĐžŃ… ĐŽĐ°ĐœĐ°, Ń‚Đ” ĐœĐ°ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœŃƒ Đž срДЎњД ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœŃƒ Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€ у бурсĐșĐŸŃ˜. ĐšĐŸŃ€ĐžŃˆŃ›Đ”ĐœĐž су ĐżĐŸĐŽĐ°Ń†Đž са 41 Ń…ĐžĐŽŃ€ĐŸĐŒĐ”Ń‚Đ”ĐŸŃ€ĐŸĐ»ĐŸŃˆĐșĐ” ŃŃ‚Đ°ĐœĐžŃ†Đ”Ńƒ бурсĐșĐŸŃ˜ Đž Ń‚ĐŸ ĐČŃ€ĐžŃ˜Đ”ĐŽĐœĐŸŃŃ‚Đž Đ·Đ° Đ±Ń€ĐŸŃ˜ ĐŒŃ€Đ°Đ·ĐœĐžŃ… ĐŽĐ°ĐœĐ°, Đ”ĐșŃŃ‚Ń€Đ”ĐŒĐœĐ” ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ” Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ” Đž срДЎњД ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ”Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ” Đ·Đ° ĐČŃ€Đ”ĐŒĐ”ĐœŃĐșĐž ĐżĐ”Ń€ĐžĐŸĐŽ ĐŸĐŽ 1960. ĐŽĐŸ 2015.ĐłĐŸĐŽĐžĐœĐ”. ĐĐ°Ń˜ĐœĐŸĐČОјО ĐżĐŸĐŽĐ°Ń†Đž NAO ĐžĐœĐŽĐ”Đșса су ĐżŃ€Đ”ŃƒĐ·Đ”Ń‚Đž саNCAR/UCAR ĐĐ°Ń†ĐžĐŸĐœĐ°Đ»ĐœĐŸĐł Ń†Đ”ĐœŃ‚Ń€Đ° Đ·Đ° Đ°Ń‚ĐŒĐŸŃŃ„Đ”Ń€ŃĐșĐ° ОстражОĐČања. ĐŸŃ€Đ”ŃƒĐ·Đ”Ń‚Đ” су ŃĐ°ĐŒĐŸ ĐČŃ€ĐžŃ˜Đ”ĐŽĐœĐŸŃŃ‚Đž ĐžĐœĐŽĐ”Đșса ĐČДћД ĐŸĐŽÂ±0.5ĐșĐ°ĐșĐŸ Đ±ĐžŃĐŒĐŸ Đ”Đ»ĐžĐŒĐžĐœĐžŃĐ°Đ»Đž ĐœĐ”ŃƒŃ‚Ń€Đ°Đ»ĐœŃƒ Ń„Đ°Đ·Ńƒ NAO ĐžĐœĐŽĐ”Đșса. ĐœŃ€Đ°Đ·ĐœĐžĐŒ ĐŽĐ°ĐœĐŸĐŒ сД ŃĐŒĐ°Ń‚Ń€Đ° ĐŸĐœĐ°Ń˜ ĐŽĐ°Đœ ĐșĐ°ĐŽĐ° јД ĐŒĐžĐœĐžĐŒĐ°Đ»ĐœĐ°ĐŽĐœĐ”ĐČĐœĐ° Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ° ĐČĐ°Đ·ĐŽŃƒŃ…Đ° ĐžŃĐżĐŸĐŽ 0°C. ĐŸĐŸŃ€Đ”ĐŽ Ń‚ĐŸĐłĐ°, ĐșĐŸĐ”Ń„ĐžŃ†ĐžŃ˜Đ”ĐœŃ‚Đž ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ” су ĐžĐ·Ń€Đ°Ń‡ŃƒĐœĐ°Ń‚Đž ĐșĐŸŃ€ĐžŃˆŃ›Đ”ŃšĐ”ĐŒ PearsonŃ„ĐŸŃ€ĐŒŃƒĐ»Đ” Đž Đ·Đ° срДЎњД ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ” Đž Đ·Đ° Đ”ĐșŃŃ‚Ń€Đ”ĐŒĐœĐ” ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ” Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ”, ĐșĐ°ĐŸ Đž ĐżĐ°Ń€Đ°ĐŒĐ”Ń‚Ń€Đž Đ±Ń€ĐŸŃ˜Đ° ĐŒŃ€Đ°Đ·ĐœĐžŃ… ĐŽĐ°ĐœĐ°ŃƒĐșључујућо ĐŒŃ˜Đ”ŃĐ”Ń‡ĐœĐž ĐœĐžĐČĐŸ Đž DJFM. ĐĄĐŒĐ°Ń‚Ń€Đ° сД ĐŽĐ° јД ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ° слаба Đ°ĐșĐŸ су ĐČŃ€ĐžŃ˜Đ”ĐŽĐœĐŸŃŃ‚Đž r ĐžĐ·ĐŒĐ”Ń’Ńƒ ± 0.10-0.29,Đ·Đ° ĐČŃ€ĐžŃ˜Đ”ĐŽĐœĐŸŃŃ‚Đž ± 0.30-0.49 ĐŸĐœĐ° јД ŃƒĐŒŃ˜Đ”Ń€Đ”ĐœĐ°, Đ° Đ·Đ° ĐČŃ€ĐžŃ˜Đ”ĐŽĐœĐŸŃŃ‚Đž 0.50-1.00 јД ĐČĐžŃĐŸĐșĐ°. ĐŸĐŸŃ€Đ”ĐŽ Ń‚ĐŸĐłĐ°, ± проĐșазујД ŃĐŒŃ˜Đ”Ń€ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ”. ĐŁĐșĐŸĐ»ĐžĐșĐŸ јД ĐžĐ·Ń€Đ°Ń‡ŃƒĐœĐ°Ń‚Đ° статосточĐșĐ° ĐČŃ€ĐžŃ˜Đ”ĐŽĐœĐŸŃŃ‚ (t) ĐČДћа ĐŸĐŽ Ń†ĐžŃ™Đ°ĐœĐ” Ń‚Đ°Đ±Đ”Đ»Đ°Ń€ĐœĐ” ĐČŃ€ĐžŃ˜Đ”ĐŽĐœĐŸŃŃ‚Đž (ĐżŃ€Đ”ĐŒĐ°ŃŃ‚Đ”ĐżĐ”ĐœŃƒ ŃĐ»ĐŸĐ±ĐŸĐŽĐ” Đž ĐœĐžĐČĐŸŃƒ Đ·ĐœĐ°Ń‡Đ°Ń˜Đ°), Ń…ĐžĐżĐŸŃ‚Đ”Đ·Đ° сД ĐœĐ” ĐŒĐŸĐ¶Đ” ĐżĐŸŃ‚ĐČрЮото Ń‚Đ” ĐœĐ”Ń›Đ” бОтО Đ·ĐœĐ°Ń‡Đ°Ń˜ĐœĐ” ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ”. ĐŁ ĐœĐ°ŃˆĐ”ĐŒ раЮу,ŃŃ‚Đ”ĐżĐ”Đœ ŃĐ»ĐŸĐ±ĐŸĐŽĐ” ĐžĐ·ĐœĐŸŃĐž 56-2 = 54, Đ° ĐžĐ·Ń€Đ°Ń‡ŃƒĐœĐ°Ń‚Đž праг јД ± 0.27 Đ·Đ° α = 0,05 Đž ± 0.34 Đ·Đ° α = 0,01. ĐŸŃ€Đ”ĐŒĐ° ĐŽĐŸĐ±ĐžŃ˜Đ”ĐœĐžĐŒŃ€Đ”Đ·ŃƒĐ»Ń‚Đ°Ń‚ĐžĐŒĐ°, ĐŸĐŽĐœĐŸŃ ĐžĐ·ĐŒĐ”Ń’Ńƒ NAO ĐžĐœĐŽĐ”Đșса Đž ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ” Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ” јД ĐœĐ”ĐłĐ°Ń‚ĐžĐČĐ°Đœ, ŃˆŃ‚ĐŸ запраĐČĐŸ Đ·ĐœĐ°Ń‡Đž ĐŽĐ° ĐœĐ”ĐłĐ°Ń‚ĐžĐČĐ°ĐœNAO ĐžĐœĐŽĐ”Đșс ĐŽĐŸĐČĐŸĐŽĐž ĐŽĐŸ ĐżĐŸĐČДћања ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ” Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ”. ĐŁĐŒŃ˜Đ”Ń€Đ”ĐœĐ”/ĐżĐŸĐČĐžŃˆĐ”ĐœĐ” Đž Đ·ĐœĐ°Ń‡Đ°Ń˜ĐœĐ” ĐœĐ”ĐłĐ°Ń‚ĐžĐČĐœĐ” ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ”ŃŃƒ ĐžĐ·ĐŒŃ˜Đ”Ń€Đ”ĐœĐ” у ĐŒĐ°Ń˜Ńƒ, ĐŽĐ”Ń†Đ”ĐŒĐ±Ń€Ńƒ, Ń‚Đ” DJFM у ĐČĐ”Ń›ĐžĐœĐž ŃŃ‚Đ°ĐœĐžŃ†Đ°. ĐŸĐŸŃŃ‚ĐŸŃ˜Đž слаба ĐżĐŸĐ·ĐžŃ‚ĐžĐČĐœĐ° ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ° ĐżĐŸŃ‡Đ”Ń‚ĐșĐŸĐŒ Đž ĐșŃ€Đ°Ń˜Đ”ĐŒŃ˜Đ”ŃĐ”ĐœĐž (ŃĐ”ĐżŃ‚Đ”ĐŒĐ±Đ°Ń€ Đž ĐœĐŸĐČĐ”ĐŒĐ±Đ°Ń€). ĐŁĐŸĐżŃˆŃ‚Đ”ĐœĐŸ ĐłĐŸĐČĐŸŃ€Đ”Ń›Đž, ĐżĐŸŃŃ‚ĐŸŃ˜Đž слаба ĐœĐ”ĐłĐ°Ń‚ĐžĐČĐœĐ° ĐČДза ĐžĐ·ĐŒĐ”Ń’Ńƒ NAO ĐžĐœĐŽĐ”Đșса Đž ŃŃ€Đ”ĐŽŃšĐ”ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ” Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ”, ĐŒĐ°ĐŽĐ° сД у Ń˜ŃƒĐœŃƒ Đž ĐŸĐșŃ‚ĐŸĐ±Ń€Ńƒ јаĐČљају ŃƒĐŒŃ˜Đ”Ń€Đ”ĐœĐ” Đž статосточĐșĐž Đ·ĐœĐ°Ń‡Đ°Ń˜ĐœĐ” ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ” Đ±ŃƒĐŽŃƒŃ›ĐžĐŽĐ° су Ń‚ĐŸ ĐżŃ€Đ”Đ»Đ°Đ·ĐœĐž ĐŒŃ˜Đ”ŃĐ”Ń†Đž. Đ”Ń€ŃƒĐłĐžĐŒ Ń€ĐžŃ˜Đ”Ń‡ĐžĐŒĐ°, ĐœĐ”ĐłĐ°Ń‚ĐžĐČĐœĐž NAO ĐžĐœĐŽĐ”Đșс ĐŽĐŸĐČĐŸĐŽĐž ĐŽĐŸ ĐżĐŸĐČДћања срДЎњД ĐŒĐ°ĐșŃĐžĐŒĐ°Đ»ĐœĐ”Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ”, ĐŽĐŸĐș сД слаба ĐżĐŸĐ·ĐžŃ‚ĐžĐČĐœĐ° ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ° јаĐČља у Đ°ĐČгусту. ĐžĐŽĐœĐŸŃ ĐžĐ·ĐŒĐ”Ń’Ńƒ NAO ĐžĐœĐŽĐ”Đșса Đž Đ±Ń€ĐŸŃ˜Đ° ĐŒŃ€Đ°Đ·ĐœĐžŃ…ĐŽĐ°ĐœĐ° јД углаĐČĐœĐŸĐŒ ĐżĐŸĐ·ĐžŃ‚ĐžĐČĐ°Đœ, ŃˆŃ‚ĐŸ Đ·ĐœĐ°Ń‡Đž ĐŽĐ° ћД ĐżĐŸĐ·ĐžŃ‚ĐžĐČĐœĐž NAO ĐžĐœĐŽĐ”Đșс ĐżĐŸĐČДћатО Đ±Ń€ĐŸŃ˜ ĐŒŃ€Đ°Đ·ĐœĐžŃ… ĐŽĐ°ĐœĐ° ĐŽĐŸĐș ћД ĐœĐ”ĐłĐ°Ń‚ĐžĐČĐ°ĐœĐžĐœĐŽĐ”Đșс ĐŽĐŸĐČДстО ĐŽĐŸ ĐŒĐ°ŃšĐ”Đł Đ±Ń€ĐŸŃ˜Đ° остох. На ĐČĐ”Ń›ĐžĐœĐž ĐŒĐ”Ń‚Đ”ĐŸŃ€ĐŸĐ»ĐŸŃˆĐșох ŃŃ‚Đ°ĐœĐžŃ†Đ° јД Đ·Đ°Đ±ĐžŃ™Đ”Đ¶Đ”ĐœĐ° ĐČĐžŃĐŸĐșĐ° Đž статосточĐșĐžĐ·ĐœĐ°Ń‡Đ°Ń˜ĐœĐ° ĐżĐŸĐ·ĐžŃ‚ĐžĐČĐœĐ° ĐșĐŸŃ€Đ”Đ»Đ°Ń†ĐžŃ˜Đ° ĐșĐŸĐŽ DJFM ĐŸŃĐžĐŒ у Đ˜ŃŃ‚Đ°ĐŒĐ±ŃƒĐ»Ńƒ, йДĐșорЮагу, Đ§Đ°ĐœĐ°ĐșалДу Đž ĐœĐ”Ń€ŃĐžĐœŃƒ. ĐŸŃ€Đ”ĐŒĐ° Ń€Đ”Đ·ŃƒĐ»Ń‚Đ°Ń‚ĐžĐŒĐ°,DJFM NAO ĐžĐœĐŽĐ”Đșс ĐœĐ°Ń€ĐŸŃ‡ĐžŃ‚ĐŸ ŃƒŃ‚ĐžŃ‡Đ” ĐœĐ° ĐșĐ»ĐžĐŒŃƒ у бурсĐșĐŸŃ˜ ŃƒŃŃ™Đ”ĐŽ Đ°Ń‚ĐŒĐŸŃŃ„Đ”Ń€ŃĐșĐ” цорĐșŃƒĐ»Đ°Ń†ĐžŃ˜Đ”. ХрДЎња Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ° убурсĐșĐŸŃ˜ у ĐżĐŸŃ€Đ°ŃŃ‚Ńƒ јД ĐŸĐŽ 1981. ĐłĐŸĐŽĐžĐœĐ”. ПраĐČац ĐŸĐŽĐœĐŸŃĐ° Ń‚Đ”ĐŒĐżĐ”Ń€Đ°Ń‚ŃƒŃ€Đ” јД ĐœĐ”ĐłĐ°Ń‚ĐžĐČĐ°Đœ ĐŽĐŸĐș јД ĐżĐŸĐ·ĐžŃ‚ĐžĐČĐ°Đœ ĐșĐ°ĐŽĐ° јД Ń€ĐžŃ˜Đ”Ń‡ ĐŸĐ±Ń€ĐŸŃ˜Ńƒ ĐŒŃ€Đ·ĐœĐžŃ… ĐŽĐ°ĐœĐ°

    Regional Climates

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    International audienc

    Regional Climates

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    Meridional Overturning Circulation Observations in the Subtropical North Atlantic

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    Large-scale climate patterns influenced temperature and weather patterns around the globe in 2011. In particular, a moderate-to-strong La Niña at the beginning of the year dissipated during boreal spring but reemerged during fall. The phenomenon contributed to historical droughts in East Africa, the southern United States, and northern Mexico, as well the wettest two-year period (2010-11) on record for Australia, particularly remarkable as this follows a decade-long dry period. Precipitation patterns in South America were also influenced by La Niña. Heavy rain in Rio de Janeiro in January triggered the country's worst floods and landslides in Brazil's history. The 2011 combined average temperature across global land and ocean surfaces was the coolest since 2008, but was also among the 15 warmest years on record and above the 1981-2010 average. The global sea surface temperature cooled by 0.1°C from 2010 to 2011, associated with cooling influences of La Niña. Global integrals of upper ocean heat content for 2011 were higher than for all prior years, demonstrating the Earth's dominant role of the oceans in the Earth's energy budget. In the upper atmosphere, tropical stratospheric temperatures were anomalously warm, while polar temperatures were anomalously cold. This led to large springtime stratospheric ozone reductions in polar latitudes in both hemispheres. Ozone concentrations in the Arctic stratosphere during March were the lowest for that period since satellite records began in 1979. An extensive, deep, and persistent ozone hole over the Antarctic in September indicates that the recovery to pre-1980 conditions is proceeding very slowly. Atmospheric carbon dioxide concentrations increased by 2.10 ppm in 2011, and exceeded 390 ppm for the first time since instrumental records began. Other greenhouse gases also continued to rise in concentration and the combined effect now represents a 30% increase in radiative forcing over a 1990 baseline. Most ozone depleting substances continued to fall. The global net ocean carbon dioxide uptake for the 2010 transition period from El Niño to La Niña, the most recent period for which analyzed data are available, was estimated to be 1.30 Pg C yr-1, almost 12% below the 29-year long-term average. Relative to the long-term trend, global sea level dropped noticeably in mid-2010 and reached a local minimum in 2011. The drop has been linked to the La Nina conditions that prevailed throughout much of 2010-11. Global sea level increased sharply during the second half of 2011. Global tropical cyclone activity during 2011 was wellbelow average, with a total of 74 storms compared with the 1981-2010 average of 89. Similar to 2010, the North Atlantic was the only basin that experienced abovenormal activity. For the first year since the widespread introduction of the Dvorak intensity-estimation method in the 1980s, only three tropical cyclones reached Category 5 intensity level-all in the Northwest Pacific basin. The Arctic continued to warm at about twice the rate compared with lower latitudes. Below-normal summer snowfall, a decreasing trend in surface albedo, and aboveaverage surface and upper air temperatures resulted in a continued pattern of extreme surface melting, and net snow and ice loss on the Greenland ice sheet. Warmerthan- normal temperatures over the Eurasian Arctic in spring resulted in a new record-low June snow cover extent and spring snow cover duration in this region. In the Canadian Arctic, the mass loss from glaciers and ice caps was the greatest since GRACE measurements began in 2002, continuing a negative trend that began in 1987. New record high temperatures occurred at 20 m below the land surface at all permafrost observatories on the North Slope of Alaska, where measurements began in the late 1970s. Arctic sea ice extent in September 2011 was the second-lowest on record, while the extent of old ice (four and five years) reached a new record minimum that was just 19% of normal. On the opposite pole, austral winter and spring temperatures were more than 3°C above normal over much of the Antarctic continent. However, winter temperatures were below normal in the northern Antarctic Peninsula, which continued the downward trend there during the last 15 years. In summer, an all-time record high temperature of -12.3°C was set at the South Pole station on 25 December, exceeding the previous record by more than a full degree. Antarctic sea ice extent anomalies increased steadily through much of the year, from briefly setting a record low in April, to well above average in December. The latter trend reflects the dispersive effects of low pressure on sea ice and the generally cool conditions around the Antarctic perimeter. © 2012 American Meteorological Society

    State of the climate in 2010

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    Several large-scale climate patterns influenced climate conditions and weather patterns across the globe during 2010. The transition from a warm El Nino phase at the beginning of the year to a cool La Nina phase by July contributed to many notable events, ranging from record wetness across much of Australia to historically low Eastern Pacific basin and near-record high North Atlantic basin hurricane activity. The remaining five main hurricane basins experienced below-to well-below-normal tropical cyclone activity. The negative phase of the Arctic Oscillation was a major driver of Northern Hemisphere temperature patterns during 2009/10 winter and again in late 2010. It contributed to record snowfall and unusually low temperatures over much of northern Eurasia and parts of the United States, while bringing above-normal temperatures to the high northern latitudes. The February Arctic Oscillation Index value was the most negative since records began in 1950. The 2010 average global land and ocean surface temperature was among the two warmest years on record. The Arctic continued to warm at about twice the rate of lower latitudes. The eastern and tropical Pacific Ocean cooled about 1 C from 2009 to 2010, reflecting the transition from the 2009/10 El Nino to the 2010/11 La Nina. Ocean heat fluxes contributed to warm sea surface temperature anomalies in the North Atlantic and the tropical Indian and western Pacific Oceans. Global integrals of upper ocean heat content for the past several years have reached values consistently higher than for all prior times in the record, demonstrating the dominant role of the ocean in the Earth's energy budget. Deep and abyssal waters of Antarctic origin have also trended warmer on average since the early 1990s. Lower tropospheric temperatures typically lag ENSO surface fluctuations by two to four months, thus the 2010 temperature was dominated by the warm phase El Nino conditions that occurred during the latter half of 2009 and early 2010 and was second warmest on record. The stratosphere continued to be anomalously cool. Annual global precipitation over land areas was about five percent above normal. Precipitation over the ocean was drier than normal after a wet year in 2009. Overall, saltier (higher evaporation) regions of the ocean surface continue to be anomalously salty, and fresher (higher precipitation) regions continue to be anomalously fresh. This salinity pattern, which has held since at least 2004, suggests an increase in the hydrological cycle. Sea ice conditions in the Arctic were significantly different than those in the Antarctic during the year. The annual minimum ice extent in the Arctic reached in September was the third lowest on record since 1979. In the Antarctic, zonally averaged sea ice extent reached an all-time record maximum from mid-June through late August and again from mid-November through early December. Corresponding record positive Southern Hemisphere Annular Mode Indices influenced the Antarctic sea ice extents. Greenland glaciers lost more mass than any other year in the decade-long record. The Greenland Ice Sheet lost a record amount of mass, as the melt rate was the highest since at least 1958, and the area and duration of the melting was greater than any year since at least 1978. High summer air temperatures and a longer melt season also caused a continued increase in the rate of ice mass loss from small glaciers and ice caps in the Canadian Arctic. Coastal sites in Alaska show continuous permafrost warming and sites in Alaska, Canada, and Russia indicate more significant warming in relatively cold permafrost than in warm permafrost in the same geographical area. With regional differences, permafrost temperatures are now up to 2 C warmer than they were 20 to 30 years ago. Preliminary data indicate there is a high probability that 2010 will be the 20th consecutive year that alpine glaciers have lost mass. Atmospheric greenhouse gas concentrations continued to rise and ozone depleting substances continued to decrease. Carbon dioxide increased by 2.60 ppm in 2010, a rate above both the 2009 and the 1980-2010 average rates. The global ocean carbon dioxide uptake for the 2009 transition period from La Nina to El Nino conditions, the most recent period for which analyzed data are available, is estimated to be similar to the long-term average. The 2010 Antarctic ozone hole was among the lowest 20% compared with other years since 1990, a result of warmer-than-average temperatures in the Antarctic stratosphere during austral winter between mid-July and early September
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