Diagnosing Spring Onset Across the North American Arctic-Boreal Region Using Complementary Satellite Environmental Data Records

IF 3.7 3区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES Journal of Geophysical Research: Biogeosciences Pub Date : 2024-08-18 DOI:10.1029/2023JG007977
Youngwook Kim, John S. Kimball, Nicholas Parazoo, Xiaolan Xu, Andreas Colliander, Rolf Reichle, Jingfeng Xiao, Xing Li
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Abstract

The timing and progression of the spring thaw transition in high northern latitudes (HNL) coincides with warmer temperatures and landscape thawing, promoting increased soil moisture and growing season onset of gross primary productivity (GPP), heterotrophic respiration (HR), and evapotranspiration (ET). However, the relative order and spatial pattern of these events is uncertain due to vast size and remoteness of the HNL. We utilized satellite environmental data records (EDRs) derived from complementary passive microwave and optical sensors to assess the progression of spring transition events across Alaska and Northern Canada from 2016 to 2020. Selected EDRs included land surface and soil freeze-thaw status, solar-induced chlorophyll fluorescence (SIF) signifying canopy photosynthesis, root zone soil moisture (RZSM), and GPP, HR, and ET as indicators of ecosystem carbon and water-energy fluxes. The EDR spring transition maps showed thawing as a precursor to rising RZSM and growing season onset. Thaw timing was closely associated with ecosystem activation from winter dormancy, including seasonal increases in SIF, GPP, and ET. The HR onset occurred closer to soil thawing and prior to GPP activation, reducing spring carbon (CO2) sink potential. The mean duration of the spring transition spanned ∼6 ± 1.5 weeks between initial and final onset events. Spring thaw timing and maximum RZSM were closely related to active layer thickness in HNL permafrost zones, with deeper active layers showing generally earlier thawing and greater RZSM. Our results confirm the utility of combined satellite EDRs for regional monitoring and better understanding of the complexity of the spring transition.

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利用互补卫星环境数据记录诊断整个北美北极-北方地区的春季开始时间
北半球高纬度地区(HNL)春季解冻过渡的时间和进程与气温升高和地表解冻相吻合,从而促进了土壤水分的增加以及生长季节总初级生产力(GPP)、异养呼吸作用(HR)和蒸散作用(ET)的开始。然而,由于 HNL 面积巨大且地处偏远,这些事件的相对顺序和空间模式并不确定。我们利用从互补无源微波和光学传感器获得的卫星环境数据记录(EDR),评估了 2016 年至 2020 年阿拉斯加和加拿大北部春季过渡事件的进展情况。选定的环境数据记录包括地表和土壤冻融状态、太阳诱导的叶绿素荧光(SIF)(表示冠层光合作用)、根带土壤湿度(RZSM)以及作为生态系统碳通量和水能量通量指标的 GPP、HR 和 ET。EDR 春季过渡图显示,解冻是 RZSM 上升和生长季开始的前兆。解冻时间与生态系统从冬季休眠中激活密切相关,包括 SIF、GPP 和蒸散发的季节性增加。生长季开始的时间与土壤解冻的时间更接近,并且早于 GPP 的激活时间,从而降低了春季碳(CO2)汇的潜力。从最初开始到最后结束,春季过渡的平均持续时间为 6±1.5 周。春季解冻时间和最大RZSM与HNL永久冻土带的活动层厚度密切相关,较深的活动层一般解冻较早,RZSM也较大。我们的研究结果证实了结合卫星环境数据记录仪进行区域监测和更好地了解春季过渡复杂性的实用性。
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来源期刊
Journal of Geophysical Research: Biogeosciences
Journal of Geophysical Research: Biogeosciences Earth and Planetary Sciences-Paleontology
CiteScore
6.60
自引率
5.40%
发文量
242
期刊介绍: JGR-Biogeosciences focuses on biogeosciences of the Earth system in the past, present, and future and the extension of this research to planetary studies. The emerging field of biogeosciences spans the intellectual interface between biology and the geosciences and attempts to understand the functions of the Earth system across multiple spatial and temporal scales. Studies in biogeosciences may use multiple lines of evidence drawn from diverse fields to gain a holistic understanding of terrestrial, freshwater, and marine ecosystems and extreme environments. Specific topics within the scope of the section include process-based theoretical, experimental, and field studies of biogeochemistry, biogeophysics, atmosphere-, land-, and ocean-ecosystem interactions, biomineralization, life in extreme environments, astrobiology, microbial processes, geomicrobiology, and evolutionary geobiology
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