从全球到实地测绘和监测泥炭地条件

IF 3.9 3区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES
Budiman Minasny, Diana Vigah Adetsu, Matt Aitkenhead, Rebekka R. E. Artz, Nikki Baggaley, Alexandra Barthelmes, Amélie Beucher, Jean Caron, Giulia Conchedda, John Connolly, Raphaël Deragon, Chris Evans, Kjetil Fadnes, Dian Fiantis, Zisis Gagkas, Louis Gilet, Alessandro Gimona, Stephan Glatzel, Mogens H. Greve, Wahaj Habib, Kristell Hergoualc’h, Cecilie Hermansen, Darren B. Kidd, Triven Koganti, Dianna Kopansky, David J. Large, Tuula Larmola, Allan Lilly, Haojie Liu, Matthew Marcus, Maarit Middleton, Keith Morrison, Rasmus Jes Petersen, Tristan Quaife, Line Rochefort,  Rudiyanto, Linda Toca, Francesco N. Tubiello, Peter Lystbæk Weber, Simon Weldon, Wirastuti Widyatmanti, Jenny Williamson, Dominik Zak
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引用次数: 0

摘要

泥炭地只覆盖了地球表面的3-4%,但它们储存了全球近30%的土壤碳储量。随着泥炭地在世界各地以惊人的速度不断退化,这种重要的碳储量正受到威胁。它促使世界各国制定法规,以保护和减少这个富含碳的生态系统的排放。例如,欧盟实施了新规则,要求对泥炭地进行可持续管理,这对到2050年实现碳中和目标至关重要。然而,由于缺乏关于泥炭地范围和状况的信息,阻碍了国家政策的制定和恢复工作。本文回顾了从实地到全球泥炭地测绘和监测的知识现状,并确定了需要进一步研究的领域。它概述了九个国家用于绘制泥炭地地图的不同方法,这些方法在泥炭土和泥炭地的定义、地图覆盖范围和地图细节方面各不相同。尽管仅用一种方法绘制世界各地泥炭地的地图是不可能的,但该论文强调,在泥炭地类型和气候相似的地区,需要更一致的方法来为其保护和紧急恢复提供信息。该综述进一步总结了用于监测泥炭地条件和功能的各种方法。其中包括在地块尺度上监测腐殖化程度和化学计量比,以及在野外到景观尺度上进行近端传感,如伽马辐射测量和电磁感应,以绘制泥炭厚度图并确定温室气体排放热点。在区域和国家范围内,使用无源和有源传感器的遥感技术可以帮助监测沉降率、地下水位、泥炭湿度、山体滑坡和温室气体排放。尽管使用地下水位深度作为泥炭地年际温室气体排放的代表已经得到了很好的证实,但还没有一种单一的遥感方法或数据产品经过地方或区域尺度的验证。全球范围内更广泛的土地利用变化和火灾监测可能进一步有助于国家温室气体清单报告。监测泥炭地条件以评估个别恢复方案的成功与否,仍然需要实地工作,结合遥感和建模来评估当地的代理。长期监测对于重新湿润泥炭地的植被恢复结果和相关温室气体排放得出有效结论是必要的,因为在现场层面还没有完全了解其动态。需要监测恢复泥炭地的植被发展和水文情况,作为评估水的回归以及营养循环和生物多样性变化的指标。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Mapping and monitoring peatland conditions from global to field scale

Mapping and monitoring peatland conditions from global to field scale

Peatlands cover only 3–4% of the Earth’s surface, but they store nearly 30% of global soil carbon stock. This significant carbon store is under threat as peatlands continue to be degraded at alarming rates around the world. It has prompted countries worldwide to establish regulations to conserve and reduce emissions from this carbon rich ecosystem. For example, the EU has implemented new rules that mandate sustainable management of peatlands, critical to reaching the goal of carbon neutrality by 2050. However, a lack of information on the extent and condition of peatlands has hindered the development of national policies and restoration efforts. This paper reviews the current state of knowledge on mapping and monitoring peatlands from field sites to the globe and identifies areas where further research is needed. It presents an overview of the different methodologies used to map peatlands in nine countries, which vary in definition of peat soil and peatland, mapping coverage, and mapping detail. Whereas mapping peatlands across the world with only one approach is hardly possible, the paper highlights the need for more consistent approaches within regions having comparable peatland types and climates to inform their protection and urgent restoration. The review further summarises various approaches used for monitoring peatland conditions and functions. These include monitoring at the plot scale for degree of humification and stoichiometric ratio, and proximal sensing such as gamma radiometrics and electromagnetic induction at the field to landscape scale for mapping peat thickness and identifying hotspots for greenhouse gas (GHG) emissions. Remote sensing techniques with passive and active sensors at regional to national scale can help in monitoring subsidence rate, water table, peat moisture, landslides, and GHG emissions. Although the use of water table depth as a proxy for interannual GHG emissions from peatlands has been well established, there is no single remote sensing method or data product yet that has been verified beyond local or regional scales. Broader land-use change and fire monitoring at a global scale may further assist national GHG inventory reporting. Monitoring of peatland conditions to evaluate the success of individual restoration schemes still requires field work to assess local proxies combined with remote sensing and modeling. Long-term monitoring is necessary to draw valid conclusions on revegetation outcomes and associated GHG emissions in rewetted peatlands, as their dynamics are not fully understood at the site level. Monitoring vegetation development and hydrology of restored peatlands is needed as a proxy to assess the return of water and changes in nutrient cycling and biodiversity.

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来源期刊
Biogeochemistry
Biogeochemistry 环境科学-地球科学综合
CiteScore
7.10
自引率
5.00%
发文量
112
审稿时长
3.2 months
期刊介绍: Biogeochemistry publishes original and synthetic papers dealing with biotic controls on the chemistry of the environment, or with the geochemical control of the structure and function of ecosystems. Cycles are considered, either of individual elements or of specific classes of natural or anthropogenic compounds in ecosystems. Particular emphasis is given to coupled interactions of element cycles. The journal spans from the molecular to global scales to elucidate the mechanisms driving patterns in biogeochemical cycles through space and time. Studies on both natural and artificial ecosystems are published when they contribute to a general understanding of biogeochemistry.
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