The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021
Understanding the key mechanisms that control northern treelines is important to accurately predict biome shifts and terrestrial feedbacks to climate. At a global scale, it has long been observed that elevational and latitudinal treelines occur at similar mean growing season air temperature (GSAT) i...
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NSF Arctic Data Center
2022
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| Online Access: | https://dx.doi.org/10.18739/a2zk55n5m https://arcticdata.io/catalog/view/doi:10.18739/A2ZK55N5M |
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ftdatacite:10.18739/a2zk55n5m 2023-05-15T17:57:38+02:00 The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021 Maher, Colin Dial, Roman Pastick, Neal Hewitt, Rebecca Jorgenson, M. Torre Sullivan, Patrick 2022 text/xml https://dx.doi.org/10.18739/a2zk55n5m https://arcticdata.io/catalog/view/doi:10.18739/A2ZK55N5M en eng NSF Arctic Data Center tundra-taiga ecotone Growth limitation hypothesis boreal forest permafrost Dataset dataset 2022 ftdatacite https://doi.org/10.18739/a2zk55n5m 2022-04-01T17:54:54Z Understanding the key mechanisms that control northern treelines is important to accurately predict biome shifts and terrestrial feedbacks to climate. At a global scale, it has long been observed that elevational and latitudinal treelines occur at similar mean growing season air temperature (GSAT) isotherms, inspiring the growth limitation hypothesis (GLH) that cold GSAT limits aboveground growth of treeline trees, with mean treeline GSAT ~6-7 degrees celsius (°C). Treelines with mean GSAT warmer than 6-7 °C may indicate other limiting factors. Many treelines globally are not advancing despite warming, and other climate variables are rarely considered at broad scales. Our goals were to test whether current boreal treelines in northern Alaska correspond with the GLH isotherm, determine which environmental factors are most predictive of treeline presence, and to identify areas beyond the current treeline where advance is most likely. We digitized ~12,400 kilometers (km) of treelines (greater than 26K points) and computed seasonal climate variables across northern Alaska. We then built a generalized additive model predicting treeline presence to identify key factors determining treeline. Two metrics of mean GSAT at Alaska’s northern treelines were consistently warmer than the 6-7 °C isotherm (means of 8.5 °C and 9.3 °C), indicating that direct physiological limitation from low GSAT is unlikely to explain the position of treelines in northern Alaska. Our final model included cumulative growing degree-days, near-surface (≤ 1 meters (m)) permafrost probability, and growing season total precipitation, which together may represent the importance of soil temperature. Our results indicate that mean GSAT may not be the primary driver of treeline in northern Alaska or that its effect is mediated by other more proximate, and possibly non-climatic, controls. Our model predicts treeline potential in several areas beyond current treelines, pointing to possible routes of treeline advance if unconstrained by non-climatic factors. Dataset permafrost taiga Tundra Alaska DataCite Metadata Store (German National Library of Science and Technology) |
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Open Polar |
| collection |
DataCite Metadata Store (German National Library of Science and Technology) |
| op_collection_id |
ftdatacite |
| language |
English |
| topic |
tundra-taiga ecotone Growth limitation hypothesis boreal forest permafrost |
| spellingShingle |
tundra-taiga ecotone Growth limitation hypothesis boreal forest permafrost Maher, Colin Dial, Roman Pastick, Neal Hewitt, Rebecca Jorgenson, M. Torre Sullivan, Patrick The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021 |
| topic_facet |
tundra-taiga ecotone Growth limitation hypothesis boreal forest permafrost |
| description |
Understanding the key mechanisms that control northern treelines is important to accurately predict biome shifts and terrestrial feedbacks to climate. At a global scale, it has long been observed that elevational and latitudinal treelines occur at similar mean growing season air temperature (GSAT) isotherms, inspiring the growth limitation hypothesis (GLH) that cold GSAT limits aboveground growth of treeline trees, with mean treeline GSAT ~6-7 degrees celsius (°C). Treelines with mean GSAT warmer than 6-7 °C may indicate other limiting factors. Many treelines globally are not advancing despite warming, and other climate variables are rarely considered at broad scales. Our goals were to test whether current boreal treelines in northern Alaska correspond with the GLH isotherm, determine which environmental factors are most predictive of treeline presence, and to identify areas beyond the current treeline where advance is most likely. We digitized ~12,400 kilometers (km) of treelines (greater than 26K points) and computed seasonal climate variables across northern Alaska. We then built a generalized additive model predicting treeline presence to identify key factors determining treeline. Two metrics of mean GSAT at Alaska’s northern treelines were consistently warmer than the 6-7 °C isotherm (means of 8.5 °C and 9.3 °C), indicating that direct physiological limitation from low GSAT is unlikely to explain the position of treelines in northern Alaska. Our final model included cumulative growing degree-days, near-surface (≤ 1 meters (m)) permafrost probability, and growing season total precipitation, which together may represent the importance of soil temperature. Our results indicate that mean GSAT may not be the primary driver of treeline in northern Alaska or that its effect is mediated by other more proximate, and possibly non-climatic, controls. Our model predicts treeline potential in several areas beyond current treelines, pointing to possible routes of treeline advance if unconstrained by non-climatic factors. |
| format |
Dataset |
| author |
Maher, Colin Dial, Roman Pastick, Neal Hewitt, Rebecca Jorgenson, M. Torre Sullivan, Patrick |
| author_facet |
Maher, Colin Dial, Roman Pastick, Neal Hewitt, Rebecca Jorgenson, M. Torre Sullivan, Patrick |
| author_sort |
Maher, Colin |
| title |
The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021 |
| title_short |
The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021 |
| title_full |
The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021 |
| title_fullStr |
The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021 |
| title_full_unstemmed |
The climate envelope of Alaska’s northern treelines: implications for controlling factors and future treeline advance. Primary data and analyses 2019 - 2021 |
| title_sort |
climate envelope of alaska’s northern treelines: implications for controlling factors and future treeline advance. primary data and analyses 2019 - 2021 |
| publisher |
NSF Arctic Data Center |
| publishDate |
2022 |
| url |
https://dx.doi.org/10.18739/a2zk55n5m https://arcticdata.io/catalog/view/doi:10.18739/A2ZK55N5M |
| genre |
permafrost taiga Tundra Alaska |
| genre_facet |
permafrost taiga Tundra Alaska |
| op_doi |
https://doi.org/10.18739/a2zk55n5m |
| _version_ |
1766166110963499008 |