| 东南极中山站陆缘固定冰2011/2012年度的时空变化 |
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| 引用本文: | 赵杰臣,杨清华,程斌,LEPP&#;RANTA Matti,谢苏锐,陈猛,于亦宁,田忠翔,李明,张林,惠凤鸣.东南极中山站陆缘固定冰2011/2012年度的时空变化[J].海洋学报(英文版),2019,38(5):51-61. |
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| 作者姓名: | 赵杰臣 杨清华 程斌 LEPP&#;RANTA Matti 谢苏锐 陈猛 于亦宁 田忠翔 李明 张林 惠凤鸣 |
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| 作者单位: | 中国海洋大学海洋与大气学院, 青岛, 266100;国家海洋环境预报中心, 北京, 100081;中山大学大气学院, 珠海, 519082,芬兰气象研究所, 赫尔辛基, 00101;芬兰赫尔辛基大学大气和地球科学研究所, 赫尔辛基, 00014,美国南佛罗里达大学地球科学学院, 坦帕, 33634,重庆市酉阳气象台, 重庆, 409800,北京师范大学全球变化与地球系统学院, 北京, 100875,School of Geosciences, University of South Florida, Tampa 33620, USA,Meteorological Service of Youyang Tujia and Miao Autonomous County, Chongqing 409800, China,北京师范大学全球变化与地球系统学院, 北京, 100875,国家海洋环境预报中心, 北京, 100081,国家海洋环境预报中心, 北京, 100081,国家海洋环境预报中心, 北京, 100081 |
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| 基金项目: | The National Natural Science Foundation of China under contract Nos 41876212, 41406218 and 41676176; the Polar Strategy Project from Chinese Arctic and Antarctic Administration under contract No. 20120317; the Opening Fund of Key Laboratory of Land Surface Process and Climate Change in Cold and Arid Regions, CAS, under contract Nos LPCC2018001 and LPCC2018005. |
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| 摘 要: | Annual observations of first-year ice(FYI) and second-year ice(SYI) near Zhongshan Station, East Antarctica,were conducted for the first time from December 2011 to December 2012. Melt ponds appeared from early December 2011. Landfast ice partly broke in late January, 2012 after a strong cyclone. Open water was refrozen to form new ice cover in mid-February, and then FYI and SYI co-existed in March with a growth rate of 0.8 cm/d for FYI and a melting rate of 2.7 cm/d for SYI. This difference was due to the oceanic heat flux and the thickness of ice,with weaker heat flux through thicker ice. From May onward, FYI and SYI showed a similar growth by 0.5 cm/d.Their maximum thickness reached 160.5 cm and 167.0 cm, respectively, in late October. Drillings showed variations of FYI thickness to be generally less than 1.0 cm, but variations were up to 33.0 cm for SYI in March,suggesting that the SYI bottom was particularly uneven. Snow distribution was strongly affected by wind and surface roughness, leading to large thickness differences in the different sites. Snow and ice thickness in Nella Fjord had a similar "east thicker, west thinner" spatial distribution. Easterly prevailing wind and local topography led to this snow pattern. Superimposed ice induced by snow cover melting in summer thickened multi-year ice,causing it to be thicker than the snow-free SYI. The estimated monthly oceanic heat flux was ~30.0 W/m2 in March–May, reducing to ~10.0 W/m2 during July–October, and increasing to ~15.0 W/m2 in November. The seasonal change and mean value of 15.6 W/m2 was similar to the findings of previous research. The results can be used to further our understanding of landfast ice for climate change study and Chinese Antarctic Expedition services.
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| 关 键 词: | 陆缘固定冰 厚度 海洋热通量 普里兹湾 东南极 |
| 收稿时间: | 2018/1/9 0:00:00 |
Spatial and temporal evolution of landfast ice near Zhongshan Station, East Antarctica, over an annual cycle in 2011/2012 |
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| ZHAO Jiechen,YANG Qinghu,CHENG Bin,LEPP&#;RANTA Matti,HUI Fengming,XIE Surui,CHEN Meng,YU Yining,TIAN Zhongxiang,LI Ming and ZHANG Lin.Spatial and temporal evolution of landfast ice near Zhongshan Station, East Antarctica, over an annual cycle in 2011/2012[J].Acta Oceanologica Sinica,2019,38(5):51-61. |
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| Authors: | ZHAO Jiechen YANG Qinghu CHENG Bin LEPP&#;RANTA Matti HUI Fengming XIE Surui CHEN Meng YU Yining TIAN Zhongxiang LI Ming and ZHANG Lin |
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| Abstract: | Annual observations of first-year ice (FYI) and second-year ice (SYI) near Zhongshan Station, East Antarctica, were conducted for the first time from December 2011 to December 2012. Melt ponds appeared from early December 2011. Landfast ice partly broke in late January, 2012 after a strong cyclone. Open water was refrozen to form new ice cover in mid-February, and then FYI and SYI co-existed in March with a growth rate of 0.8 cm/d for FYI and a melting rate of 2.7 cm/d for SYI. This difference was due to the oceanic heat flux and the thickness of ice, with weaker heat flux through thicker ice. From May onward, FYI and SYI showed a similar growth by 0.5 cm/d. Their maximum thickness reached 160.5 cm and 167.0 cm, respectively, in late October. Drillings showed variations of FYI thickness to be generally less than 1.0 cm, but variations were up to 33.0 cm for SYI in March, suggesting that the SYI bottom was particularly uneven. Snow distribution was strongly affected by wind and surface roughness, leading to large thickness differences in the different sites. Snow and ice thickness in Nella Fjord had a similar "east thicker, west thinner" spatial distribution. Easterly prevailing wind and local topography led to this snow pattern. Superimposed ice induced by snow cover melting in summer thickened multi-year ice, causing it to be thicker than the snow-free SYI. The estimated monthly oceanic heat flux was~30.0 W/m2 in March-May, reducing to~10.0 W/m2 during July-October, and increasing to~15.0 W/m2 in November. The seasonal change and mean value of 15.6 W/m2 was similar to the findings of previous research. The results can be used to further our understanding of landfast ice for climate change study and Chinese Antarctic Expedition services. |
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| Keywords: | landfast ice thickness oceanic heat flux Prydz Bay East Antarctica |
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