Study sites in relation to surficial geology and major soil landscapes
Figure 1. Study sites in relation to surficial geology and major soil landscapes. Surficial materials are grouped into rock uplands (browns), silty uplands (yellow), gravelly–sandy lowlands (orange), and peaty–silty lowlands (greens). Other landscapes, such as riverine (red) and glaciated (blue), we...
| Main Authors: | , , , , , , , , , |
|---|---|
| Format: | Still Image |
| Language: | unknown |
| Published: |
IOP Publishing
2013
|
| Subjects: | |
| Online Access: | https://dx.doi.org/10.6084/m9.figshare.1011737 https://iop.figshare.com/articles/figure/_Study_sites_in_relation_to_surficial_geology_and_major_soil_landscapes/1011737 |
| id |
ftdatacite:10.6084/m9.figshare.1011737 |
|---|---|
| record_format |
openpolar |
| spelling |
ftdatacite:10.6084/m9.figshare.1011737 2023-05-15T16:36:44+02:00 Study sites in relation to surficial geology and major soil landscapes M Torre Jorgenson Shur, Yuri Qianlai Zhuang Manies, Kristen Ewing, Stephanie Wickland, Kim O'Donnell, Jonathan Kanevskiy, Mikhail Harden, Jennifer Striegl, Robert 2013 https://dx.doi.org/10.6084/m9.figshare.1011737 https://iop.figshare.com/articles/figure/_Study_sites_in_relation_to_surficial_geology_and_major_soil_landscapes/1011737 unknown IOP Publishing Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 CC-BY Environmental Science Image Figure graphic ImageObject 2013 ftdatacite https://doi.org/10.6084/m9.figshare.1011737 2021-11-05T12:55:41Z Figure 1. Study sites in relation to surficial geology and major soil landscapes. Surficial materials are grouped into rock uplands (browns), silty uplands (yellow), gravelly–sandy lowlands (orange), and peaty–silty lowlands (greens). Other landscapes, such as riverine (red) and glaciated (blue), were not included in this study. Boundaries of permafrost zones (gray) are based on Jorgenson et al (2008). Study areas include Innoko (I), Koyukuk (K), Hess Creek (H), Nome Creek (N), Twelve-mile Lake (M), and Taylor Highway (T). Abstract The diversity of ecosystems across boreal landscapes, successional changes after disturbance and complicated permafrost histories, present enormous challenges for assessing how vegetation, water and soil carbon may respond to climate change in boreal regions. To address this complexity, we used a chronosequence approach to assess changes in vegetation composition, water storage and soil organic carbon (SOC) stocks along successional gradients within four landscapes: (1) rocky uplands on ice-poor hillside colluvium, (2) silty uplands on extremely ice-rich loess, (3) gravelly–sandy lowlands on ice-poor eolian sand and (4) peaty–silty lowlands on thick ice-rich peat deposits over reworked lowland loess. In rocky uplands, after fire permafrost thawed rapidly due to low ice contents, soils became well drained and SOC stocks decreased slightly. In silty uplands, after fire permafrost persisted, soils remained saturated and SOC decreased slightly. In gravelly–sandy lowlands where permafrost persisted in drier forest soils, loss of deeper permafrost around lakes has allowed recent widespread drainage of lakes that has exposed limnic material with high SOC to aerobic decomposition. In peaty–silty lowlands, 2–4 m of thaw settlement led to fragmented drainage patterns in isolated thermokarst bogs and flooding of soils, and surface soils accumulated new bog peat. We were not able to detect SOC changes in deeper soils, however, due to high variability. Complicated soil stratigraphy revealed that permafrost has repeatedly aggraded and degraded in all landscapes during the Holocene, although in silty uplands only the upper permafrost was affected. Overall, permafrost thaw has led to the reorganization of vegetation, water storage and flow paths, and patterns of SOC accumulation. However, changes have occurred over different timescales among landscapes: over decades in rocky uplands and gravelly–sandy lowlands in response to fire and lake drainage, over decades to centuries in peaty–silty lowlands with a legacy of complicated Holocene changes, and over centuries in silty uplands where ice-rich soil and ecological recovery protect permafrost. Still Image Ice permafrost Thermokarst DataCite Metadata Store (German National Library of Science and Technology) Browns ENVELOPE(-44.583,-44.583,-60.700,-60.700) Hess ENVELOPE(-65.133,-65.133,-67.200,-67.200) Nome Creek ENVELOPE(-130.853,-130.853,59.783,59.783) Twelve Mile Lake ENVELOPE(-95.333,-95.333,74.817,74.817) |
| institution |
Open Polar |
| collection |
DataCite Metadata Store (German National Library of Science and Technology) |
| op_collection_id |
ftdatacite |
| language |
unknown |
| topic |
Environmental Science |
| spellingShingle |
Environmental Science M Torre Jorgenson Shur, Yuri Qianlai Zhuang Manies, Kristen Ewing, Stephanie Wickland, Kim O'Donnell, Jonathan Kanevskiy, Mikhail Harden, Jennifer Striegl, Robert Study sites in relation to surficial geology and major soil landscapes |
| topic_facet |
Environmental Science |
| description |
Figure 1. Study sites in relation to surficial geology and major soil landscapes. Surficial materials are grouped into rock uplands (browns), silty uplands (yellow), gravelly–sandy lowlands (orange), and peaty–silty lowlands (greens). Other landscapes, such as riverine (red) and glaciated (blue), were not included in this study. Boundaries of permafrost zones (gray) are based on Jorgenson et al (2008). Study areas include Innoko (I), Koyukuk (K), Hess Creek (H), Nome Creek (N), Twelve-mile Lake (M), and Taylor Highway (T). Abstract The diversity of ecosystems across boreal landscapes, successional changes after disturbance and complicated permafrost histories, present enormous challenges for assessing how vegetation, water and soil carbon may respond to climate change in boreal regions. To address this complexity, we used a chronosequence approach to assess changes in vegetation composition, water storage and soil organic carbon (SOC) stocks along successional gradients within four landscapes: (1) rocky uplands on ice-poor hillside colluvium, (2) silty uplands on extremely ice-rich loess, (3) gravelly–sandy lowlands on ice-poor eolian sand and (4) peaty–silty lowlands on thick ice-rich peat deposits over reworked lowland loess. In rocky uplands, after fire permafrost thawed rapidly due to low ice contents, soils became well drained and SOC stocks decreased slightly. In silty uplands, after fire permafrost persisted, soils remained saturated and SOC decreased slightly. In gravelly–sandy lowlands where permafrost persisted in drier forest soils, loss of deeper permafrost around lakes has allowed recent widespread drainage of lakes that has exposed limnic material with high SOC to aerobic decomposition. In peaty–silty lowlands, 2–4 m of thaw settlement led to fragmented drainage patterns in isolated thermokarst bogs and flooding of soils, and surface soils accumulated new bog peat. We were not able to detect SOC changes in deeper soils, however, due to high variability. Complicated soil stratigraphy revealed that permafrost has repeatedly aggraded and degraded in all landscapes during the Holocene, although in silty uplands only the upper permafrost was affected. Overall, permafrost thaw has led to the reorganization of vegetation, water storage and flow paths, and patterns of SOC accumulation. However, changes have occurred over different timescales among landscapes: over decades in rocky uplands and gravelly–sandy lowlands in response to fire and lake drainage, over decades to centuries in peaty–silty lowlands with a legacy of complicated Holocene changes, and over centuries in silty uplands where ice-rich soil and ecological recovery protect permafrost. |
| format |
Still Image |
| author |
M Torre Jorgenson Shur, Yuri Qianlai Zhuang Manies, Kristen Ewing, Stephanie Wickland, Kim O'Donnell, Jonathan Kanevskiy, Mikhail Harden, Jennifer Striegl, Robert |
| author_facet |
M Torre Jorgenson Shur, Yuri Qianlai Zhuang Manies, Kristen Ewing, Stephanie Wickland, Kim O'Donnell, Jonathan Kanevskiy, Mikhail Harden, Jennifer Striegl, Robert |
| author_sort |
M Torre Jorgenson |
| title |
Study sites in relation to surficial geology and major soil landscapes |
| title_short |
Study sites in relation to surficial geology and major soil landscapes |
| title_full |
Study sites in relation to surficial geology and major soil landscapes |
| title_fullStr |
Study sites in relation to surficial geology and major soil landscapes |
| title_full_unstemmed |
Study sites in relation to surficial geology and major soil landscapes |
| title_sort |
study sites in relation to surficial geology and major soil landscapes |
| publisher |
IOP Publishing |
| publishDate |
2013 |
| url |
https://dx.doi.org/10.6084/m9.figshare.1011737 https://iop.figshare.com/articles/figure/_Study_sites_in_relation_to_surficial_geology_and_major_soil_landscapes/1011737 |
| long_lat |
ENVELOPE(-44.583,-44.583,-60.700,-60.700) ENVELOPE(-65.133,-65.133,-67.200,-67.200) ENVELOPE(-130.853,-130.853,59.783,59.783) ENVELOPE(-95.333,-95.333,74.817,74.817) |
| geographic |
Browns Hess Nome Creek Twelve Mile Lake |
| geographic_facet |
Browns Hess Nome Creek Twelve Mile Lake |
| genre |
Ice permafrost Thermokarst |
| genre_facet |
Ice permafrost Thermokarst |
| op_rights |
Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 |
| op_rightsnorm |
CC-BY |
| op_doi |
https://doi.org/10.6084/m9.figshare.1011737 |
| _version_ |
1766027068943892480 |