Global vulnerability of peatlands to fire and carbon loss
about
The role of fire in UK peatland and moorland management: the need for informed, unbiased debateA novel testate amoebae trait-based approach to infer environmental disturbance in Sphagnum peatlandsRegime shifts in the anthropocene: drivers, risks, and resilienceLiving on a flammable planet: interdisciplinary, cross-scalar and varied cultural lessons, prospects and challenges.Fire effects on soils: the human dimension.Keep wetlands wet: the myth of sustainable development of tropical peatlands - implications for policies and management.Threats to intact tropical peatlands and opportunities for their conservation.An expert system model for mapping tropical wetlands and peatlands reveals South America as the largest contributor.In the line of fire: the peatlands of Southeast AsiaRegional variation in fire weather controls the reported occurrence of Scottish wildfires.Detecting peatland drains with Object Based Image Analysis and Geoeye-1 imagerySpatial evaluation of Indonesia's 2015 fire-affected area and estimated carbon emissions using Sentinel-1.Dynamics of Viral Abundance and Diversity in a Sphagnum-Dominated Peatland: Temporal Fluctuations Prevail Over Habitat.Fire effects and ecological recovery pathways of Tropical Montane Cloud Forests along a time chronosequence.Denial of long-term issues with agriculture on tropical peatlands will have devastating consequences.Effect of oil palm sustainability certification on deforestation and fire in Indonesia.Simulating the long-term impacts of drainage and restoration on the ecohydrology of peatlandsA global assessment of the carbon cycle and temperature responses to major changes in future fire regimeRoot oxygen loss from Raphia taedigera palms mediates greenhouse gas emissions in lowland neotropical peatlandsEnvironmental feedbacks in temperate aquatic ecosystems under global change: why do we need to consider chemical stressors?Particulate emissions from large North American wildfires estimated using a new top-down methodFine-scale distribution of moisture in the surface of a degraded blanket bog and its effects on the potential spread of smouldering fireContributions of wildland fire to terrestrial ecosystem carbon dynamics in North America from 1990 to 2012The influence of daily meteorology on boreal fire emissions and regional trace gas variabilityCentury-scale patterns and trends of global pyrogenic carbon emissions and fire influences on terrestrial carbon balanceEmissions and Partitioning of Intermediate-Volatility and Semi-Volatile Polar Organic Compounds (I/SV-POCs) During Laboratory Combustion of Boreal and Sub-Tropical PeatInformed debate on the use of fire for peatland management means acknowledging the complexity of socio-ecological systemsSustained Biogeochemical Impacts of Wildfire in a Mountain Lake CatchmentInfluence of Holocene permafrost aggradation and thaw on the paleoecology and carbon storage of a peatland complex in northwestern CanadaFuel accumulation in a high-frequency boreal wildfire regime: from wetland to uplandHydrological dynamics and fire history of the last 1300years in western Siberia reconstructed from a high-resolution, ombrotrophic peat archive
P2860
Q26746429-F10E4EC2-FD8D-4349-9245-0F272D000B5FQ28598408-EA778DC9-CFCC-4520-A129-066663F7702CQ30987000-B990F3D5-6F30-4AE5-9A03-D9F1D231614FQ31100325-22E8C405-90CA-4871-A5C5-C55BB2D813A6Q31100340-6F1AF268-4A70-42AB-9360-44859B044EA8Q31113805-80C5421B-BAA6-4C08-BC23-55220A96798AQ36300542-B9B30F75-176E-4446-B37A-D82987E4665CQ36308626-335EF2B0-87BB-47C4-AFC9-11BE2BD29E97Q36920982-B333EB9A-B027-4FBB-9D36-C2325B19356CQ37402715-4F187152-1CF3-48AA-B669-1B8340C05CDDQ37691940-3321FF65-FE39-4D8F-BA65-E042524F45ACQ38659970-6F3F75A7-284C-4F19-B925-E4BCDF412636Q40969374-FA22E273-8E13-4AE7-9F8C-B7E17ECC0119Q42695414-681C5D23-CED3-4D40-9377-57FCE197518EQ44416925-E2EB43CB-C680-4673-B7B5-87C6AE756A04Q45959142-F6388F97-123E-408F-885D-451F39719E76Q56838481-FCE61051-7A62-46A1-A591-67D613AA2AF0Q57189651-29ED8341-EFFD-4B2F-A53E-E69B01456F8DQ57249852-6564B821-B208-482D-8B6C-37766B4EBC65Q57662558-6CA3B473-061F-4557-9834-C32123D222C8Q57880277-3C7ED8EB-D8B7-4D67-AB29-112922BFA70EQ57916128-0F8DE9E1-3E22-48CF-B7F9-D10E8B4CC774Q58053783-DCD69A66-69E7-439E-AC98-AD1EB00BBF13Q58077246-0B0FD85C-10CC-4FC4-A110-53651928A2CDQ58388323-6A62136B-2903-4FF4-972D-3110EED432F5Q58643025-9E09AC0E-483F-41F9-8EEF-7ED9F47FA765Q58643192-FF4D60B6-9986-4382-B383-B84732D712ABQ58649272-1F14964D-63BD-486A-9BDD-A9E84DC03E70Q58650640-FD9D2580-7E73-4C4A-B2C7-432B20591B76Q58654947-DB5099FA-7A0A-4828-9237-6031762CCCE6Q58841258-6B9C34A9-8CC0-426C-B1AD-A3E589A3693E
P2860
Global vulnerability of peatlands to fire and carbon loss
description
im Januar 2015 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в січні 2015
@uk
name
Global vulnerability of peatlands to fire and carbon loss
@en
Global vulnerability of peatlands to fire and carbon loss
@nl
type
label
Global vulnerability of peatlands to fire and carbon loss
@en
Global vulnerability of peatlands to fire and carbon loss
@nl
prefLabel
Global vulnerability of peatlands to fire and carbon loss
@en
Global vulnerability of peatlands to fire and carbon loss
@nl
P2860
P50
P356
P1433
P1476
Global vulnerability of peatlands to fire and carbon loss
@en
P2093
Merritt R. Turetsky
Susan Page
P2860
P2888
P356
10.1038/NGEO2325
P407
P577
2015-01-01T00:00:00Z