Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions

© Author(s) 2018. Thaw and release of permafrost carbon (C) due to climate change is likely to offset increased vegetation C uptake in northern high-latitude (NHL) terrestrial ecosystems. Models project that this permafrost C feedback may act as a slow leak, in which case detection and attribution o...

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Published in:The Cryosphere
Main Authors: Parazoo, NC, Koven, CD, Lawrence, DM, Romanovsky, V, Miller, CE
Format: Article in Journal/Newspaper
Language:English
Published: eScholarship, University of California 2018
Subjects:
Arctic
Talik
Climate change
permafrost
Online Access:http://www.escholarship.org/uc/item/5z6634d2
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author Parazoo, NC
Koven, CD
Lawrence, DM
Romanovsky, V
Miller, CE
author_facet Parazoo, NC
Koven, CD
Lawrence, DM
Romanovsky, V
Miller, CE
author_sort Parazoo, NC
collection University of California: eScholarship
container_issue 1
container_start_page 123
container_title The Cryosphere
container_volume 12
description © Author(s) 2018. Thaw and release of permafrost carbon (C) due to climate change is likely to offset increased vegetation C uptake in northern high-latitude (NHL) terrestrial ecosystems. Models project that this permafrost C feedback may act as a slow leak, in which case detection and attribution of the feedback may be difficult. The formation of talik, a subsurface layer of perennially thawed soil, can accelerate permafrost degradation and soil respiration, ultimately shifting the C balance of permafrost-affected ecosystems from long-term C sinks to long-term C sources. It is imperative to understand and characterize mechanistic links between talik, permafrost thaw, and respiration of deep soil C to detect and quantify the permafrost C feedback. Here, we use the Community Land Model (CLM) version 4.5, a permafrost and biogeochemistry model, in comparison to long-term deep borehole data along North American and Siberian transects, to investigate thaw-driven C sources in NHL ( > 55° N) from 2000 to 2300. Widespread talik at depth is projected across most of the NHL permafrost region (14 millionĝ€†km2) by 2300, 6.2 millionĝ€†km2 of which is projected to become a long-term C source, emitting 10 Pgĝ€†C by 2100, 50 Pgĝ€†C by 2200, and 120 Pgĝ€†C by 2300, with few signs of slowing. Roughly half of the projected C source region is in predominantly warm sub-Arctic permafrost following talik onset. This region emits only 20 Pgĝ€†C by 2300, but the CLM4.5 estimate may be biased low by not accounting for deep C in yedoma. Accelerated decomposition of deep soil C following talik onset shifts the ecosystem C balance away from surface dominant processes (photosynthesis and litter respiration), but sink-to-source transition dates are delayed by 20-200 years by high ecosystem productivity, such that talik peaks early ( ĝ1/4 2050s, although borehole data suggest sooner) and C source transition peaks late ( ĝ1/4 2150-2200). The remaining C source region in cold northern Arctic permafrost, which shifts to a net source early (late 21st century), emits 5 times more C (95 Pgĝ€†C) by 2300, and prior to talik formation due to the high decomposition rates of shallow, young C in organic-rich soils coupled with low productivity. Our results provide important clues signaling imminent talik onset and C source transition, including (1) late cold-season (January-February) soil warming at depth ( ĝ1/4 2 m), (2) increasing cold-season emissions (November-April), and (3) enhanced respiration of deep, old C in warm permafrost and young, shallow C in organic-rich cold permafrost soils. Our results suggest a mosaic of processes that govern carbon source-to-sink transitions at high latitudes and emphasize the urgency of monitoring soil thermal profiles, organic C age and content, cold-season CO2 emissions, and atmospheric 14CO2 as key indicators of the permafrost C feedback.
format Article in Journal/Newspaper
genre Arctic
Climate change
permafrost
genre_facet Arctic
Climate change
permafrost
geographic Arctic
Talik
geographic_facet Arctic
Talik
id ftcdlib:qt5z6634d2
institution Open Polar
language English
long_lat ENVELOPE(146.601,146.601,59.667,59.667)
op_collection_id ftcdlib
op_container_end_page 144
op_coverage 123 - 144
op_doi https://doi.org/10.5194/tc-12-123-2018
op_relation qt5z6634d2
http://www.escholarship.org/uc/item/5z6634d2
op_rights public
op_source Parazoo, NC; Koven, CD; Lawrence, DM; Romanovsky, V; & Miller, CE. (2018). Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions. Cryosphere, 12(1), 123 - 144. doi:10.5194/tc-12-123-2018. Lawrence Berkeley National Laboratory: Retrieved from: http://www.escholarship.org/uc/item/5z6634d2
publishDate 2018
publisher eScholarship, University of California
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spelling ftcdlib:qt5z6634d2 2025-01-16T20:40:14+00:00 Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions Parazoo, NC Koven, CD Lawrence, DM Romanovsky, V Miller, CE 123 - 144 2018-01-12 application/pdf http://www.escholarship.org/uc/item/5z6634d2 english eng eScholarship, University of California qt5z6634d2 http://www.escholarship.org/uc/item/5z6634d2 public Parazoo, NC; Koven, CD; Lawrence, DM; Romanovsky, V; & Miller, CE. (2018). Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions. Cryosphere, 12(1), 123 - 144. doi:10.5194/tc-12-123-2018. Lawrence Berkeley National Laboratory: Retrieved from: http://www.escholarship.org/uc/item/5z6634d2 article 2018 ftcdlib https://doi.org/10.5194/tc-12-123-2018 2018-06-22T22:53:07Z © Author(s) 2018. Thaw and release of permafrost carbon (C) due to climate change is likely to offset increased vegetation C uptake in northern high-latitude (NHL) terrestrial ecosystems. Models project that this permafrost C feedback may act as a slow leak, in which case detection and attribution of the feedback may be difficult. The formation of talik, a subsurface layer of perennially thawed soil, can accelerate permafrost degradation and soil respiration, ultimately shifting the C balance of permafrost-affected ecosystems from long-term C sinks to long-term C sources. It is imperative to understand and characterize mechanistic links between talik, permafrost thaw, and respiration of deep soil C to detect and quantify the permafrost C feedback. Here, we use the Community Land Model (CLM) version 4.5, a permafrost and biogeochemistry model, in comparison to long-term deep borehole data along North American and Siberian transects, to investigate thaw-driven C sources in NHL ( > 55° N) from 2000 to 2300. Widespread talik at depth is projected across most of the NHL permafrost region (14 millionĝ€†km2) by 2300, 6.2 millionĝ€†km2 of which is projected to become a long-term C source, emitting 10 Pgĝ€†C by 2100, 50 Pgĝ€†C by 2200, and 120 Pgĝ€†C by 2300, with few signs of slowing. Roughly half of the projected C source region is in predominantly warm sub-Arctic permafrost following talik onset. This region emits only 20 Pgĝ€†C by 2300, but the CLM4.5 estimate may be biased low by not accounting for deep C in yedoma. Accelerated decomposition of deep soil C following talik onset shifts the ecosystem C balance away from surface dominant processes (photosynthesis and litter respiration), but sink-to-source transition dates are delayed by 20-200 years by high ecosystem productivity, such that talik peaks early ( ĝ1/4 2050s, although borehole data suggest sooner) and C source transition peaks late ( ĝ1/4 2150-2200). The remaining C source region in cold northern Arctic permafrost, which shifts to a net source early (late 21st century), emits 5 times more C (95 Pgĝ€†C) by 2300, and prior to talik formation due to the high decomposition rates of shallow, young C in organic-rich soils coupled with low productivity. Our results provide important clues signaling imminent talik onset and C source transition, including (1) late cold-season (January-February) soil warming at depth ( ĝ1/4 2 m), (2) increasing cold-season emissions (November-April), and (3) enhanced respiration of deep, old C in warm permafrost and young, shallow C in organic-rich cold permafrost soils. Our results suggest a mosaic of processes that govern carbon source-to-sink transitions at high latitudes and emphasize the urgency of monitoring soil thermal profiles, organic C age and content, cold-season CO2 emissions, and atmospheric 14CO2 as key indicators of the permafrost C feedback. Article in Journal/Newspaper Arctic Climate change permafrost University of California: eScholarship Arctic Talik ENVELOPE(146.601,146.601,59.667,59.667) The Cryosphere 12 1 123 144
spellingShingle Parazoo, NC
Koven, CD
Lawrence, DM
Romanovsky, V
Miller, CE
Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions
title Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions
title_full Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions
title_fullStr Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions
title_full_unstemmed Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions
title_short Detecting the permafrost carbon feedback: Talik formation and increased cold-season respiration as precursors to sink-to-source transitions
title_sort detecting the permafrost carbon feedback: talik formation and increased cold-season respiration as precursors to sink-to-source transitions
url http://www.escholarship.org/uc/item/5z6634d2

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