浏览全部资源
扫码关注微信
纸质出版日期: 2018-5 ,
录用日期: 2017-12-21
扫 描 看 全 文
王圆圆, 李贵才, 郭徵, 郭兆迪. 2018. 1979年—2014年三峡库区月平均气温的时空变化分析. 遥感学报, 22(3): 487–496
Wang Y Y, Li G C, Guo Z and Guo Z D. 2018. Spatial-temporal analysis of monthly air temperature changes from 1979—2014 in the Three Gorges Dam region. Journal of Remote Sensing, 22(3): 487–496
三峡区域气温变化长期以来受到科研人员和公众的关注。受三峡复杂地形的影响,仅仅基于气象站点观测数据很难准确获取区域气温变化的空间格局,遥感技术则可以通过提供空间连续的地表观测数据来辅助气温变化分析。以广义加性模型GAM(General Additive Model)为插值算法,以高程和夜间地表温度(LST
night
)遥感产品为辅助变量,估算三峡库区1979年—2014年1 km空间分辨率的月气温数据,在此基础上分析了气温变化趋势的时空特征及其与高程和森林覆盖率的关系。研究表明,(1)在插值算法中引入遥感产品LST
night
作为辅助变量可以明显改善气温估算精度,冬春季的改善幅度高于夏秋季;(2)三峡库区年平均气温在1997年后明显上升,但在2003年库区蓄水后无明显变化趋势,几乎所有月(除12月以外)的气温都呈现上升趋势,增温趋势最显著是3月和9月,3月增温主要来自于库区东部山区的贡献,而9月增温主要来自于库区西部平原的贡献;(3)多数月份(除7月、8月、9月以外)的低温上升速度超过高温上升速度,导致区域气温的动态变化范围缩小;(4)三峡库区年平均气温上升速度与高程呈正相关,即海拔越高,升温越快,但在同一海拔高度处,森林覆盖率越高,年均气温上升速度越慢,暗示森林具有抑制增温的作用。
The near-surface air temperature (
T
a
) change in the Three Gorges Dam region (TGD) has long been a popular topic in public and research fields. However
fully capturing the spatial pattern of
T
a
change in TGD is challenging because of the sparse observation net and complicated topographic conditions. Thermal remote sensing technology can obtain spatially contiguous observations of Land Surface Temperature (LST) in a synoptic manner
thus providing invaluable information for spatial pattern analyses of
T
a
change given the fact that LST and
T
a
are closely related. This study aims to obtain the monthly
T
a
from 1979-2014 and determine its trend at a spatial resolution of 1 km. We used the satellite product of LST at nighttime (LST
night
) as a covariate in the general additive model (GAM)
which incorporates spline interpolation and linear regression
to ensure high quality of
T
a
data. First
monthly
T
a
estimation accuracies estimated with and without LST
night
were compared to evaluate the contribution of LST
night
. Second
the pixel-wise
T
a
trend was calculated with the Mann-Kendall method
and the spatial-temporal features of the
T
a
trend were analyzed. Finally
the effects of elevation and tree cover on the
T
a
trend were assessed. The main results were as follows. (1) When LST
night
was used as a covariate in GAM
temperature interpolation accuracy dramatically improved. The improvement in the cold season was more obvious than that in the warm season because
T
a
in the cold season is mainly influenced by LST through a strong radiative cooling effect. (2) Inter-annual variation analysis of regional mean annual
T
a
in TGD revealed that pronounced warming occurred after 1997
and no significant change in
T
a
was observed after the water level rose to 135 m in 2003. (3) Temporal-spatial analysis of monthly
T
a
showed that warming occurs in almost every month (except for December)
and the most dramatic warming occurs in March and September. In March
pixels with significant warming trends are mainly located in the eastern mountainous TGD
whereas in September
they are mainly located in the western TGD with a relatively flat terrain. (4) The
T
a
range for most months has been decreasing because the minimum temperature increased at a faster speed than the maximum temperature. Consequently
the lapse rate of
T
a
showed a decrease. (5) The enhanced warming trend over high elevations indicated a strong positive correlation between the trend of annual
T
a
and elevation (
r
= 0.76). However
when the elevations are similar
the warming trend is less pronounced in regions with dense tree cover
suggesting that forests can restrain warming. We conclude that LST
night
information is beneficial to
T
a
estimation and that the change trend of
T
a
in TGD shows various features depending on season
region
land cover properties
and temperature metric. Further in-depth analysis of the driving factors of the
T
a
trend
such as land use/cover or forest cover change
should be implemented in the future to be fully prepared to meet the challenges of climate change in TGD.
三峡库区气温变化广义加性模型地表温度
Three Gorges Dam region (TGD)warminggeneral additive modelland surface temperature
Benali A, Carvalho A C, Nunes J P, Carvalhais N and Santos A. 2012. Estimating air surface temperature in Portugal using MODIS LST data. Remote Sensing of Environment, 124: 108–121
陈鲜艳, 张强, 叶殿秀, 廖要明, 祝昌汉, 邹旭恺. 2009. 三峡库区局地气候变化. 长江流域资源与环境, 18(1): 47–51
Chen X Y, Zhang Q, Ye D X, Liao Y M, Zhu C H and Zou X K. 2009. Regional climate change over three gorges reservoir area. Resources and Environment in the Yangtze Basin, 18(1): 47–51 (
Diaz H F and Bradley R S. 1997. Temperature variations during the last century at high elevation sites. Climate Change, 36(3-4): 253–279
Hamed K H. 2008. Trend detection in hydrologic data: the Mann–Kendall trend test under the scaling hypothesis. Journal of Hydrology, 349(3-4): 350–363
Hill D J. 2013. Evaluation of the temporal relationship between daily min/max air and land surface temperature. International Journal of Remote Sensing, 34(24): 9002–9015
李新, 程国栋, 卢玲. 2003. 青藏高原气温分布的空间插值方法比较. 高原气象, 22(6): 565–573
Li X, Cheng G D and Lu L. 2003. Comparison study of spatial interpolation methods of air temperature over Qinghai-Xizang Plateau. Plateau Meteorology, 22(6): 565–573 (
Li Y, Zhao M S, Motesharrei S, Mu Q Z, Kalnay E and Li S C. 2015. Local cooling and warming effects of forests based on satellite observations. Nature Communication, 6: 6603
Liu X D, Cheng Z G, Yan L B and Yin Z Y. 2009. Elevation dependency of recent and future minimum surface air temperature trends in the Tibetan Plateau and its surroundings. Global and Planetary Change, 68(3): 164–174
马占山, 张强, 秦琰琰. 2010. 三峡水库对区域气候影响的数值模拟分析. 长江流域资源与环境, 19(9): 1044–1052
Ma Z S, Zhang Q and Qin Y Y. 2010. Numerical simulation and analysis of the effect of three gorges reservoir project on the regional climate change. Resources and Environment in the Yangtze Basin, 19(9): 1044–1052 (
Messerli B and Ives J D. 1997. Mountains of the World: A Global Priority. New York: Parthenon: 495
Miller N, Jin J M and Tsang C F. 2005. Local climate sensitivity of the Three Gorges Dam. Geophysical Research Letters, 32(16): L16704
Mostovoy G V, King R L, Reddy K R, Gopal Kakani V and Filippova M G. 2006. Statistical estimation of daily maximum and minimum air temperatures from MODIS LST data over the state of Mississippi. GIScience and Remote Sensing, 43(1): 78–110
Ouarda T B M J, Charron C, Marpu P R and Chebana F. 2016. The generalized additive model for the assessment of the direct, diffuse, and global solar irradiances Using SEVIRI images, with application to the UAE. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 9(4): 1553–1566
Oyler J W, Ballantyne A, Jencso K, Sweet M and Running S W. 2015. Creating a topoclimatic daily air temperature dataset for the conterminous United States using homogenized station data and remotely sensed land skin temperature. International Journal of Climatology, 35(9): 2258–2279
Oyler J W, Dobrowski S Z, Holden Z A and Running S W. 2016. Remotely sensed land skin temperature as a spatial predictor of air temperature across the conterminous United States. Journal of Applied Meteorology and Climatology, 55(7): 1441–1457
Park N W and Chi K H. 2008. Quantitative assessment of landslide susceptibility using high-resolution remote sensing data and a generalized additive model. International Journal of Remote Sensing, 29(1): 247–264
Park S. 2011. Integration of satellite-measured LST data into cokriging for temperature estimation on tropical and temperate islands. International Journal of Climatology, 31(11): 1653–1664
Parmentier B, McGill B, Wilson A M, Regetz J, Jetz W, Guralnick R P, Tuanmu M N, Robinson N and Schildhauer M. 2014. An assessment of methods and remote-sensing derived covariates for regional predictions of 1 km daily maximum air temperature. Remote Sensing, 6(9): 8639–8670
Pepin N, Bradley R S, Diaz H F, Baraer M, Caceres E B, Forsythe N, Fowler H, Greenwood G, Hashmi M Z, Liu X D, Miller J R, Ning L, Ohmura A, Palazzi E, Rangwala I, Schöner W, Severskiy I, Shahgedanova M, Wang M B, Williamson S N and Yang D Q. 2015. Elevation-dependent warming in mountain regions of the world. Nature Climate Change, 5(5): 424–430
任芝花, 熊安元. 2007. 地面自动站观测资料三级质量控制业务系统的研制. 气象, 33(1): 19–24
Ren Z H and Xiong A Y. 2007. Operational system development on three step quality control of observations from AWS. Meteorological Monthly, 33(1): 19–24 (
Rhines A, McKinnon K A, Tingley M P and Huybers P. 2017. Seasonally resolved distributional trends of north American temperatures show contraction of winter variability. Journal of Climate, 30(3): 1139–1157
Tietäväinen H, Tuomenvirta H and Venäläinen A. 2010. Annual and seasonal mean temperatures in Finland during the last 160 years based on gridded temperature data. International Journal of Climatology, 30(15): 2247–2256
Vancutsem C, Ceccato P, Dinku T and Connor S J. 2010. Evaluation of MODIS land surface temperature data to estimate air temperature in different ecosystems over Africa. Remote Sensing of Environment, 114(2): 449–465
Wan Z, Zhang Y, Zhang Q and Li Z L. 2004. Quality assessment and validation of the MODIS global land surface temperature. International Journal of Remote Sensing, 25(1): 261–274
王圆圆, 郭徵, 李贵才, 郭兆迪. 2017. 基于广义加性模型估算1979—2014年三峡库区降水及其特征分析. 地理学报, 72(7): 1207–1220
Wang Y Y, Guo Z, Li G C and Guo Z D. 2017. Precipitation estimation and analysis of the Three Gorges Dam region (1979—2014) by combining gauge measurements and MSWEP with generalized additive model. Acta Geographica Sinica, 72(7): 1207–1220 (
Wood S N. 2003. Thin plate regression splines. Journal of the Royal Statistical Society Series B (Statistical Methodology), 65(1): 95–114
Wu J, Gao X J, Giorgi F, Chen Z H and Yu D F. 2012. Climate effects of the three Gorges Reservoir as simulated by a high resolution double nested regional climate model. Quaternary International, 282: 27–36
Wu L G, Zhang Q and Jiang Z H. 2006. Three Gorges Dam affects regional precipitation. Geophysical Research Letters, 33(13): L13806
于强, 彭乃志, 傅抱璞. 1996. 三峡气候的基本特征和成因的初步研究. 湖泊科学, 8(4): 305–311
Yu Q, Peng N Z and Fu B P. 1996. A preliminary study on climatic characteristics and cause of formation in three gorges. Journal of Lake Science, 8(4): 305–311 (
张强, 万素琴, 毛以伟, 陈正洪, 廖要明. 2005. 三峡库区复杂地形下的气温变化特征. 气候变化研究进展, 1(4): 164–167
Zhang Q, Wan S Q, Mao Y W, Chen Z H and Liao Y M. 2005. Characteristics of temperature changes around the Three Gorges with complex topography. Advances in Climate Change Research, 1(4): 164–167 (
张天宇, 范莉, 孙杰, 何永坤, 董新宁, 任永建. 2010. 1961~2008年三峡库区气候变化特征分析. 长江流域资源与环境, 19(S1): 52–61
Zhang T Y, Fan L, Sun J, He Y K, Dong X N and Ren Y J. 2010. Characteristics of climate change in the three gorges reservoir area during 1961~2008. Resources and Environment in the Yangtze Basin, 19(S1): 52–61 (
Zhang X T, Liang S L, Song Z, Niu H L, Wang G X, Tang W J, Chen Z Q and Jiang B. 2016. Local adaptive calibration of the satellite-derived surface incident shortwave radiation product using smoothing spline. IEEE Transactions on Geoscience and Remote Sensing, 54(2): 1156–1169
Zhao F and Shepherd M. 2012. Precipitation changes near Three Gorges Dam, China. Part I: a spatiotemporal Validation Analysis. Journal of Hydrometeorology, 13(2): 735–745
周英, 袁久坤. 2016. 三峡库区“腹心”地带蓄水前后气温变化特征. 气象科技, 44(5): 783–787
Zhou Y and Yuan J K. 2016. Analysis of temperature variation before and after impoundment of Three Gorges reservoir. Meteorological Science and Technology, 44(5): 783–787 (
相关作者
相关机构
京公网安备11010802024621