Climate Warming Does Not Always Extend the Plant Growing Season in Inner Mongolian Grasslands: Evidence From a 30‐Year In Situ Observations at Eight Experimental Sites

Wang, Guocheng; Huang, Yao; Wei, Yang; Zhang, Wen; Li, Tingting; Zhang, Qing

doi:10.1029/2019jg005137

Cited by 19 publications

(13 citation statements)

References 57 publications

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“…Based on the five methods to extract SOS data from the NDVI series in temperate semi‐dry grasslands in China, the start of the growing season did not change significantly over the 1982–2015 period for the whole study area, although there was spatial variability in the temporal trends. This result is consistent with those of previous studies based on ground‐based observations and remote sensing (Hou et al., 2014; Wang et al., 2019). We found that the date of SOS displayed an advancing trend in the northern part of the study area, where the main type of vegetation is meadow steppe.…”

Section: Discussionsupporting

confidence: 93%

“…Climate change implies not only rising temperatures but also shifting temporal and spatial patterns of precipitation. Climate warming has advanced spring flushing in cold grasslands, for example, in Tibet and in geographical locations at high latitudes (Cong et al., 2012; Zhang et al., 2013), whereas in seasonally dry grasslands, less advancement and even delays in spring flushing have been observed (Ren et al., 2017; Wang et al., 2019). This scenario is mainly because spring phenology is regulated primarily by temperature in cold grasslands but by water availability in dry grasslands (Ma et al., 2019; Vico et al., 2015).…”

Section: Introductionmentioning

confidence: 99%

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Decreasing control of precipitation on grassland spring phenology in temperate China

Xing

et al. 2020

Global Ecol. Biogeogr.

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AimVegetation phenology is highly sensitive to climate change. The timing of spring phenology in temperate grasslands is regulated primarily by temperature and precipitation. The aim of this study was to determine whether the primary factor regulating vegetation phenology has changed under ongoing climate change and the underlying mechanisms.LocationTemperate semi‐dry grasslands in China.Time period1982–2015.Major taxa studiedTemperate grassland.MethodsWe extracted start of season (SOS) dates using five standard methods from satellite‐derived normalized difference vegetation index (NDVI) data and determined the primary factor regulating spring phenology using partial correlation analysis.ResultsThe SOS date did not change significantly during the entire 1982–2015 study period in these semi‐dry grasslands, but interannual variability increased significantly from the first subperiod [1982–1998, 8.8 ± 1.1 days (mean ± SE)] to the second subperiod (1999–2015, 10.3 ± 1.1 days). Interestingly, we found that the primary factor regulating SOS shifted from precipitation during 1982–1998 to temperature during 1999–2015. Specifically, we found that during the first period, the SOS in 67.5% of the study area was determined by precipitation (mean partial correlation coefficient, r = 0.58 ± 0.16), but during the second period the main regulating factor in 75.0% of the study area was temperature (r = 0.61 ± 0.14).Main conclusionsThe change in the primary driver of spring phenology was attributed mainly to significant increases in preseason precipitation. Our study highlights that the response of spring phenology to climatic factors might change under ongoing climate change. This shift should be addressed in phenology models to simulate grassland phenology better, in addition to its impact on carbon and water cycles in future climate conditions.

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Section: Discussionsupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Decreasing control of precipitation on grassland spring phenology in temperate China

Xing

et al. 2020

Global Ecol. Biogeogr.

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“…Tropospheric ozone (O 3 ) is generated by photochemical reactions involving nitrogen oxides (NO x ) and volatile organic compounds (VOCs) under strong solar radiation (Sillman, 1999;Atkinson, 2000;Jacob and Winner, 2009). It is one of the most important air pollutants and has been of widespread concern (Wang et al, 2017;Li et al, 2019). High O 3 concentrations at the surface can not only injure human respiratory health (Gauderman et al, 2004;Lelieveld et al, 2015) but also lead to considerable damage to plants and crops, which further changes the land carbon budget (Fuhrer et al, 1997;Yue and Unger, 2014;Lombardozzi et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Ozone–vegetation feedback through dry deposition and isoprene emissions in a global chemistry–carbon–climate model

Gong

Lei

et al. 2020

Atmos. Chem. Phys.

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Abstract. Ozone–vegetation feedback is essential to tropospheric ozone (O3) concentrations. The O3 stomatal uptake damages leaf photosynthesis and stomatal conductance and, in turn, influences O3 dry deposition. Further, O3 directly influences isoprene emissions, an important precursor of O3. The effects of O3 on vegetation further alter local meteorological fields and indirectly influence O3 concentrations. In this study, we apply a fully coupled chemistry–carbon–climate global model (ModelE2-YIBs) to evaluate changes in O3 concentrations caused by O3–vegetation interactions. Different parameterizations and sensitivities of the effect of O3 damage on photosynthesis, stomatal conductance, and isoprene emissions (IPE) are implemented in the model. The results show that O3-induced inhibition of stomatal conductance increases surface O3 on average by +2.1 ppbv (+1.2 ppbv) in eastern China, +1.8 ppbv (−0.3 ppbv) in the eastern US, and +1.3 ppbv (+1.0 ppbv) in western Europe at high (low) damage sensitivity. Such positive feedback is dominated by reduced O3 dry deposition in addition to the increased temperature and decreased relative humidity from weakened transpiration. Including the effect of O3 damage on IPE slightly reduces surface O3 concentrations by influencing precursors. However, the reduced IPE weaken surface shortwave radiative forcing of secondary organic aerosols, leading to increased temperature and O3 concentrations in the eastern US. This study highlights the importance of interactions between O3 and vegetation with regard to O3 concentrations and the resultant air quality.

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“…For the period MAM, four images/month were assigned to each point and plotted with a locally estimated scatterplot smoother to visualize trends in physical plant conditions during the growing season in Inner Mongolia. September images range from the 6 th to the 13 th and the 5 th to the 12 th of the month (Kawamura et al, 2005;Wang et al, 2019a;Wei et al, 2020;Zhou et al, 2017). The section covering the 45 regular points was cross validated with 127 regular points covering the entire extent of the MODIS scene over September 2000-2018.…”

Section: Methodsmentioning

confidence: 99%

Monitoring landcover change and desertification processes in northern China and Mongolia using historical written sources and vegetation indices

Kempf

2021

Preprint

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Abstract. Fighting land degradation of semi-arid and climate-sensitive grasslands are among the most urgent tasks of current eco-political agenda. Northern China and Mongolia are particularly prone to surface transformations caused by heavily increased livestock numbers during the 20th century. Extensive overgrazing and resource exploitation amplify regional climate change effects and trigger intensified surface transformation, which forces policy-driven interventions to prevent desertification. In the past, the region has been subject to major shifts in environmental and socio-cultural parameters, what makes it difficult to measure the extent of the regional anthropogenic impact and global climate change. This article analyses historical written sources, palaeoenvironmental data, and Normalized Difference Vegetation Index (NDVI) temporal series from the Moderate Resolution Imaging Spectroradiometer (MODIS) to compare landcover change during the Little Ice Age (LIA) and the reference period 2000–2018. Results show that decreasing precipitation and temperature records led to increased land degradation during the late 17th century. However, modern landcover data shows enhanced expansion of bare lands contrasting an increase in precipitation (Ptotal) and maximum temperature (Tmax). Vegetation response during the early growing season (March–May) and the late grazing season (September) does not relate to Ptotal and Tmax and generally low NDVI values indicate no major grassland recovery over the past 20 years.

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Climate Warming Does Not Always Extend the Plant Growing Season in Inner Mongolian Grasslands: Evidence From a 30‐Year In Situ Observations at Eight Experimental Sites

Cited by 19 publications

References 57 publications

Decreasing control of precipitation on grassland spring phenology in temperate China

Decreasing control of precipitation on grassland spring phenology in temperate China

Ozone–vegetation feedback through dry deposition and isoprene emissions in a global chemistry–carbon–climate model

Monitoring landcover change and desertification processes in northern China and Mongolia using historical written sources and vegetation indices

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