Yaoming Ma, Zhipeng Xie, Yingying Chen, Shaomin Liu, Tao Che, Ziwei Xu, Lunyu Shang, Xiaobo He, Xianhong Meng, Weiqiang Ma, Baiqing Xu, Huabiao Zhao, Junbo Wang, Guangjian Wu, Xin Li
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Three categories of observations are provided in this dataset: meteorological gradient data (met), soil hydrothermal data (soil), and turbulent flux data (flux). To assure data quality, a set of rigorous data-processing and quality control procedures are implemented for all observation elements (e.g., wind speed and direction at different height) in this dataset. The operational workflow and procedures are individually tailored to the varied types of elements at each station, including automated error screening, manual inspection, diagnostic checking, adjustments, and quality flagging. The hourly raw data series; the quality-assured data; and supplementary information, including data integrity and the percentage of correct data on a monthly scale, are provided via the National Tibetan Plateau Data Center (https://doi.org/10.11888/Atmos.tpdc.300977, Ma et al., 2023a). 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引用次数: 0
摘要
摘要由于青藏高原易受全球气候变化的影响,近几十年来该地区的气候发生了巨大变化。在整个青藏高原观测到的变化与区域陆地-大气相互作用密切相关。目前的模式和卫星都难以准确描述这种相互作用;因此,本文概述的有关陆地-大气相互作用的关键实地观测数据提供了必要的独立验证数据和精细尺度过程见解,用于约束再分析产品、遥感检索和陆地表面模式参数化。科学数据共享对热带雨林至关重要,因为在这些恶劣条件下很少有实地观测数据。然而,实地观测数据目前分散在个人或小组中,尚未整合起来进行综合分析。这就阻碍了我们更好地了解这些相互作用、它们产生的前所未有的变化以及它们带来的重大生态和环境后果。在这项研究中,我们与不同的机构和组织合作,提供了一个全面的数据集,每小时测量地表能量平衡成分、土壤热液特性和近地表微气象条件,时间跨度长达 17 年(2005-2021 年)。该数据集来自 12 个野外观测站,涵盖了各种典型的大陆坡地貌,在空间覆盖范围和持续时间方面提供了迄今为止最广泛的原位观测数据,用于研究大陆坡上陆地与大气的相互作用。该数据集提供了三类观测数据:气象梯度数据(气象)、土壤热液数据(土壤)和湍流通量数据(通量)。为确保数据质量,对该数据集中的所有观测要素(如不同高度的风速和风向)都实施了一套严格的数据处理和质量控制程序。操作工作流程和程序是根据每个站点不同类型的要素量身定制的,包括自动错误筛选、人工检查、诊断检查、调整和质量标记。通过国家青藏高原数据中心(https://doi.org/10.11888/Atmos.tpdc.300977, Ma et al., 2023a)提供每小时原始数据序列、质量保证数据以及补充信息,包括数据完整性和月度正确数据百分比。该数据集覆盖的站点数量最多、气象要素收集最全、观测和记录时间最长,是迄今为止青藏高原最广泛的陆地-大气相互作用小时观测数据集。它将成为评估和完善陆地表面模式、再分析产品和遥感检索的基准,也是描述大洋洲热带雨林细尺度陆地-大气相互作用过程及其影响机制的特征的基准。
Dataset of spatially extensive long-term quality-assured land–atmosphere interactions over the Tibetan Plateau
Abstract. The climate of the Tibetan Plateau (TP) has experienced substantial changes in recent decades as a result of the location's susceptibility to global climate change. The changes observed across the TP are closely associated with regional land–atmosphere interactions. Current models and satellites struggle to accurately depict the interactions; therefore, critical field observations on land–atmosphere interactions outlined here provide necessary independent validation data and fine-scale process insights for constraining reanalysis products, remote sensing retrievals, and land surface model parameterizations. Scientific data sharing is crucial for the TP since in situ observations are rarely available under these harsh conditions. However, field observations are currently dispersed among individuals or groups and have not yet been integrated for comprehensive analysis. This has prevented a better understanding of the interactions, the unprecedented changes they generate, and the substantial ecological and environmental consequences they bring about. In this study, we collaborated with different agencies and organizations to present a comprehensive dataset for hourly measurements of surface energy balance components, soil hydrothermal properties, and near-surface micrometeorological conditions spanning up to 17 years (2005–2021). This dataset, derived from 12 field stations covering a variety of typical TP landscapes, provides the most extensive in situ observation data available for studying land–atmosphere interactions on the TP to date in terms of both spatial coverage and duration. Three categories of observations are provided in this dataset: meteorological gradient data (met), soil hydrothermal data (soil), and turbulent flux data (flux). To assure data quality, a set of rigorous data-processing and quality control procedures are implemented for all observation elements (e.g., wind speed and direction at different height) in this dataset. The operational workflow and procedures are individually tailored to the varied types of elements at each station, including automated error screening, manual inspection, diagnostic checking, adjustments, and quality flagging. The hourly raw data series; the quality-assured data; and supplementary information, including data integrity and the percentage of correct data on a monthly scale, are provided via the National Tibetan Plateau Data Center (https://doi.org/10.11888/Atmos.tpdc.300977, Ma et al., 2023a). With the greatest number of stations covered, the fullest collection of meteorological elements, and the longest duration of observations and recordings to date, this dataset is the most extensive hourly land–atmosphere interaction observation dataset for the TP. It will serve as the benchmark for evaluating and refining land surface models, reanalysis products, and remote sensing retrievals, as well as for characterizing fine-scale land–atmosphere interaction processes of the TP and underlying influence mechanisms.
Earth System Science DataGEOSCIENCES, MULTIDISCIPLINARYMETEOROLOGY-METEOROLOGY & ATMOSPHERIC SCIENCES
CiteScore
18.00
自引率
5.30%
发文量
231
审稿时长
35 weeks
期刊介绍:
Earth System Science Data (ESSD) is an international, interdisciplinary journal that publishes articles on original research data in order to promote the reuse of high-quality data in the field of Earth system sciences. The journal welcomes submissions of original data or data collections that meet the required quality standards and have the potential to contribute to the goals of the journal. It includes sections dedicated to regular-length articles, brief communications (such as updates to existing data sets), commentaries, review articles, and special issues. ESSD is abstracted and indexed in several databases, including Science Citation Index Expanded, Current Contents/PCE, Scopus, ADS, CLOCKSS, CNKI, DOAJ, EBSCO, Gale/Cengage, GoOA (CAS), and Google Scholar, among others.