What evidence exists for temporal variability in Arctic terrestrial and freshwater biodiversity throughout the Holocene? A systematic map protocol.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Andrew C Martin, Jakob J Assmann, Richard H W Bradshaw, Mari Kuoppamaa, Niina I Kuosmanen, Signe Normand, James D M Speed, Marc Macias-Fauria
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Abstract

Background: The Arctic tundra is subject to the greatest climate change-induced temperature rises of any biome. Both terrestrial and freshwater biota are responding to recent climate warming through variability in their distribution, abundance, and richness. However, uncertainty arises within models of future change when considering processes that operate over centennial timescales. A systematic evidence synthesis of centennial-scale variability in biodiversity does not currently exist for the Arctic biome. Here, we sought to address the primary research question: what evidence exists for temporal variability in Arctic terrestrial and freshwater biodiversity throughout the Holocene (11,650 years before present (yBP)-0yBP)?

Methods: Consultation with stakeholders informed key definitions, scoping and the appropriateness of the research question. The research question was structured using a PECO framework-Arctic biota (P), a timestamped year in the Holocene (E), another year in the Holocene (C), and the dimensions of biodiversity that have been measured (O)-to inform the search strategy. Search strings were benchmarked against a test list of 100 known sources to ensure a specific and comprehensive return of literature. Searches will occur across 13 bibliographic databases. The eligibility criteria specify that sources must: (a) use 'proxy' methods to measure biodiversity; (b) fall within the spatial extent of the contemporary Arctic tundra biome; and (c) consist of a time-series that overlaps with 11,650yBP to 0yBP (1950AD). Information coded from studies will include proxy-specific information to account for both temporal uncertainty (i.e., the characteristics of age-depth models and dating methods) and taxonomic uncertainty (i.e., the samples and processes used for taxonomic identification). We will assess temporal uncertainty within each source by determining the quality of dating methods and measures; this information will be used to harmonise dates onto the IntCal20 calibration curve and determine the available temporal resolution and extent of evidence through space. Key outputs of this systematic map will be: (1) a graph database containing the spatial-temporal properties of each study dataset with taxonomic harmonisation; and (2) a geographical map of the evidence base.

在整个全新世,北极陆地和淡水生物多样性的时间变化存在什么证据?系统的地图协议
背景:在所有生物群落中,北极苔原受气候变化引起的温度上升影响最大。陆地生物群和淡水生物群正在通过其分布、丰度和丰富度的变化对近期的气候变暖做出反应。然而,在考虑百年时间尺度上的变化过程时,未来变化模型中出现了不确定性。目前还没有针对北极生物群落生物多样性百年尺度变异性的系统证据综述。在此,我们试图解决主要研究问题:在整个全新世(距今 11,650 年-0yBP),北极陆地和淡水生物多样性的时间变异性存在哪些证据?与利益相关者的磋商为研究问题的关键定义、范围界定和适当性提供了信息。研究问题的结构采用 PECO 框架--北极生物群(P)、全新世中有时间戳的年份(E)、全新世中的另一个年份(C)以及已测量的生物多样性维度(O)--为检索策略提供信息。检索字符串以 100 个已知来源的测试列表为基准,以确保检索到具体而全面的文献。将在 13 个书目数据库中进行检索。资格标准规定资料来源必须(a) 使用 "替代 "方法测量生物多样性;(b) 在当代北极苔原生物群落的空间范围内;(c) 包含与 11,650yBP 至 0yBP(公元 1950 年)重叠的时间序列。研究中的编码信息将包括特定区域的信息,以考虑时间上的不确定性(即年龄深度模型和测年方法的特征)和分类学上的不确定性(即用于分类鉴定的样本和过程)。我们将通过确定年代测定方法和措施的质量来评估每个来源中的时间不确定性;这一信息将用于协调 IntCal20 校准曲线上的日期,并确定可用的时间分辨率和空间证据范围。该系统地图的主要产出将是(1) 包含每个研究数据集的时空属性的图形数据库,并进行分类协调;以及 (2) 证据库的地理图。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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