Spatiotemporal Variability in Start and End of Growing Season in China Related to Climate Variability

Ge, Quansheng; Dai, Junhu; Cui, Huijuan; Wang, Huanjiong

doi:10.3390/rs8050433

Cited by 33 publications

(23 citation statements)

References 67 publications

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“…Therefore, a longer duration of cooling, in days, is required at high altitudes to initiate a delayed EOS. This finding is consistent with other studies [71][72][73]. Crabbe et al [71] showed that warmer temperatures in extreme warm autumn events lead to significantly delayed EOS for needle leaf evergreen forest, broad-leaf deciduous forests, and mixed forests.…”

Section: Relationships Between Phenology Metrics and Climatic Factorssupporting

confidence: 91%

Forest Phenology Dynamics to Climate Change and Topography in a Geographic and Climate Transition Zone: The Qinling Mountains in Central China

Xia

Qin

Feng

et al. 2019

Forests

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Forest ecosystems in an ecotone and their dynamics to climate change are growing ecological and environmental concerns. Phenology is one of the most critical biological indicators of climate change impacts on forest dynamics. In this study, we estimated and visualized the spatiotemporal patterns of forest phenology from 2001 to 2017 in the Qinling Mountains (QMs) based on the enhanced vegetation index (EVI) from MODerate-resolution Imaging Spectroradiometer (MODIS). We further analyzed this data to reveal the impacts of climate change and topography on the start of the growing season (SOS), end of the growing season (EOS), and the length of growing season (LOS). Our results showed that forest phenology metrics were very sensitive to changes in elevation, with a 2.4 days delayed SOS, 1.4 days advanced EOS, and 3.8 days shortened LOS for every 100 m increase in altitude. During the study period, on average, SOS advanced by 0.13 days year−1, EOS was delayed by 0.22 days year−1, and LOS increased by 0.35 day year−1. The phenological advanced and delayed speed across different elevation is not consistent. The speed of elevation-induced advanced SOS increased slightly with elevation, and the speed of elevation-induced delayed EOS shift reached a maximum value of 1500 m from 2001 to 2017. The sensitivity of SOS and EOS to preseason temperature displays that an increase of 1 °C in the regionally averaged preseason temperature would advance the average SOS by 1.23 days and delay the average EOS by 0.72 days, respectively. This study improved our understanding of the recent variability of forest phenology in mountain ecotones and explored the correlation between forest phenology and climate variables in the context of the ongoing climate warming.

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Section: Relationships Between Phenology Metrics and Climatic Factorssupporting

confidence: 91%

Forest Phenology Dynamics to Climate Change and Topography in a Geographic and Climate Transition Zone: The Qinling Mountains in Central China

Xia

Qin

Feng

et al. 2019

Forests

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“…Among the multiple preseason (here preseason refers to the period preceding a certain phonological date in which a climate factor has strongest impact on that phonology event; details are given in the method section) meteorological factors that could explain these changes, low temperature was identified as a major driver of leaf senescence in autumn (Cong, Shen, & Piao, ; Ding et al, ; Ge et al, ; Jeong et al, ; Liu, Fu, Zeng, et al, ; Liu, Fu, Zhu, et al, ; Marchand et al, ; Yang et al, ; Zeng et al, ; Zhao et al, ). In most of these studies, the interannual variations in the date of autumn phenology onset were related to daily mean temperature.…”

Section: Introductionmentioning

confidence: 99%

Asymmetric Responses of the End of Growing Season to Daily Maximum and Minimum Temperatures on the Tibetan Plateau

et al. 2017

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Climate warming has delayed the end of the growing season (EOS) in temperate and cold ecosystems. However, it is unclear whether asymmetric warming (higher warming at night than during the day) has triggered different responses in the timing of EOS. Here we used satellite‐observed EOS of alpine vegetation to reveal its asymmetric responses to nighttime and daytime warming on the Tibetan Plateau. Increased preseason minimum temperature could postpone EOS by 7.92 day K−1 (P < 0.01), probably by slowing low‐temperature induced leaf senescence, whereas increased preseason maximum temperature could advance EOS by 3.57 day K−1 (P < 0.05), likely due to the confounding effects of water limitations. The delaying effect of nighttime warming was stronger in more arid areas of the plateau, where daytime warming has a stronger advancing effect on EOS. Our results provide new insights into understanding and modeling autumn vegetation phenology on the Tibetan Plateau and grassland ecosystems in other temperate and cold regions.

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“…This is especially true since the year 2000, a time during which China has experienced remarkably strong El Niño events [22]. Moreover, such research in China has mainly focused on SOS changes in temperate China [17,19,20,23]; to the best of our knowledge, few studies [20,24] have considered or discussed corresponding EOS or LOS changes. More importantly, previous studies of SOS within the Tibetan Plateau have reached contradictory conclusions [23,25] that appear to have depended on datasets or methodology.…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal Variability of Land Surface Phenology in China from 2001–2014

Luo

2017

Remote Sensing

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Abstract:Land surface phenology is a highly sensitive and simple indicator of vegetation dynamics and climate change. However, few studies on spatiotemporal distribution patterns and trends in land surface phenology across different climate and vegetation types in China have been conducted since 2000, a period during which China has experienced remarkably strong El Niño events. In addition, even fewer studies have focused on changes of the end of season (EOS) and length of season (LOS) despite their importance. In this study, we used four methods to reconstruct Moderate Resolution Imaging Spectroradiometer (MODIS) Enhanced Vegetation Index (EVI) dataset and chose the best smoothing result to estimate land surface phenology. Then, the phenophase trends were analyzed via the Mann-Kendall method. We aimed to assess whether trends in land surface phenology have continued since 2000 in China at both national and regional levels. We also sought to determine whether trends in land surface phenology in subtropical or high altitude areas are the same as those observed in high latitude areas and whether those trends are uniform among different vegetation types. The result indicated that the start of season (SOS) was progressively delayed with increasing latitude and altitude. In contrast, EOS exhibited an opposite trend in its spatial distribution, and LOS showed clear spatial patterns over this region that decreased from south to north and from east to west at a national scale. The trend of SOS was advanced at a national level, while the trend in Southern China and the Tibetan Plateau was opposite to that in Northern China. The transaction zone of the SOS within Northern China and Southern China occurred approximately between 31.4 • N and 35.2 • N. The trend in EOS and LOS were delayed and extended, respectively, at both national and regional levels except that of LOS in the Tibetan Plateau, which was shortened by delayed SOS onset more than by delayed EOS onset. The absolute magnitude of SOS was decreased after 2000 compared with previous studies, and the phenophase trends are species specific.

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Spatiotemporal Variability in Start and End of Growing Season in China Related to Climate Variability

Cited by 33 publications

References 67 publications

Forest Phenology Dynamics to Climate Change and Topography in a Geographic and Climate Transition Zone: The Qinling Mountains in Central China

Forest Phenology Dynamics to Climate Change and Topography in a Geographic and Climate Transition Zone: The Qinling Mountains in Central China

Asymmetric Responses of the End of Growing Season to Daily Maximum and Minimum Temperatures on the Tibetan Plateau

Spatiotemporal Variability of Land Surface Phenology in China from 2001–2014

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