Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic

Overview: It has long been thought that temperature exerts a direct control on growth of treeline trees and the position of the treeline. However, our recent work in the Arctic with white spruce suggests that indirect effects of temperature on soil nutrient availability may be of equal or greater im...

Full description

Bibliographic Details
Main Authors: Patrick Sullivan, Michael Weintraub
Format: Dataset
Language:unknown
Published: Arctic Data Center 2020
Subjects:
Online Access:https://search.dataone.org/view/urn:uuid:222a4fd0-c7b5-428d-a377-54301a889966
id dataone:urn:uuid:222a4fd0-c7b5-428d-a377-54301a889966
record_format openpolar
spelling dataone:urn:uuid:222a4fd0-c7b5-428d-a377-54301a889966 2024-10-03T18:45:46+00:00 Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic Patrick Sullivan Michael Weintraub Agashashok River, Alaska ENVELOPE(-162.25,-162.17,67.49,67.46) BEGINDATE: 2016-01-01T00:00:00Z ENDDATE: 2021-01-01T00:00:00Z 2020-01-01T00:00:00Z https://search.dataone.org/view/urn:uuid:222a4fd0-c7b5-428d-a377-54301a889966 unknown Arctic Data Center Arctic Boreal Treeline White spruce Snow Microbe Nitrogen Phosphorus Carbon Picea glauca Dataset 2020 dataone:urn:node:ARCTIC 2024-10-03T18:19:00Z Overview: It has long been thought that temperature exerts a direct control on growth of treeline trees and the position of the treeline. However, our recent work in the Arctic with white spruce suggests that indirect effects of temperature on soil nutrient availability may be of equal or greater importance. We hypothesize that cold soils at the treeline, particularly during winter, limit microbial activity and nutrient availability to the point where trees are barely able to survive and grow. Measurements made during winter have revealed that Arctic forests maintain snowpacks that are much deeper than observed at treeline. Trees are thought to trap snow and lead to a deeper snowpack, insulating the soil from cold air and allowing for greater overwinter microbial activity and greater nutrient mineralization. Indeed, we found a strong positive correlation between white spruce growth and winter snow depth. We propose to isolate the mechanisms underlying this correlation by using snowfences to manipulate winter snow depth and fertilizer to increase soil nutrient availability at three treelines that differ in soil moisture. To provide an experimental test of the importance of temperature as a direct control on treeline tree growth, we propose to incorporate experimental shoot warming into our snowfence experiment in a factorial design. We predict that both experimental snow and nutrient additions will lead to large increases in microbial activity, photosynthesis, tree growth, seed quality, seed production, seedling establishment and recruitment of new trees. We expect to observe the greatest positive responses where soils are wet and cold. Meanwhile, we predict that shoot warming will lead to negligible changes in growth. This research will elucidate the relationship between snow depth and soil nutrient availability, and determine the relative importance of nutrient and temperature limitations at treeline to white spruce – a dominant member of the boreal forest and the northernmost tree species in North America. Intellectual Merit: The position of the Arctic treeline is an important regulator of surface energy budgets, carbon cycling and subsistence resources in high latitude environments. Our recent research provides correlative evidence of the importance of winter snow depth as a driver of tree growth. Here, we propose to experimentally isolate the importance of snow depth and soil nutrient availability and examine the consequences for microbial processes and tree performance. This is a novel proposal, as we aim to link microbial ecology with large-scale landscape patterns of relevance to regional and global climates. If our hypotheses are confirmed, our findings will contradict the prevailing theory of treeline causation, alter our predictions of where and when treelines may advance and necessitate revision of the many paleoclimate reconstructions based upon correlations between temperature and tree growth near the Arctic treeline. Dataset Arctic Alaska Arctic Data Center (via DataONE) Arctic ENVELOPE(-162.25,-162.17,67.49,67.46)
institution Open Polar
collection Arctic Data Center (via DataONE)
op_collection_id dataone:urn:node:ARCTIC
language unknown
topic Arctic
Boreal
Treeline
White spruce
Snow
Microbe
Nitrogen
Phosphorus
Carbon
Picea glauca
spellingShingle Arctic
Boreal
Treeline
White spruce
Snow
Microbe
Nitrogen
Phosphorus
Carbon
Picea glauca
Patrick Sullivan
Michael Weintraub
Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic
topic_facet Arctic
Boreal
Treeline
White spruce
Snow
Microbe
Nitrogen
Phosphorus
Carbon
Picea glauca
description Overview: It has long been thought that temperature exerts a direct control on growth of treeline trees and the position of the treeline. However, our recent work in the Arctic with white spruce suggests that indirect effects of temperature on soil nutrient availability may be of equal or greater importance. We hypothesize that cold soils at the treeline, particularly during winter, limit microbial activity and nutrient availability to the point where trees are barely able to survive and grow. Measurements made during winter have revealed that Arctic forests maintain snowpacks that are much deeper than observed at treeline. Trees are thought to trap snow and lead to a deeper snowpack, insulating the soil from cold air and allowing for greater overwinter microbial activity and greater nutrient mineralization. Indeed, we found a strong positive correlation between white spruce growth and winter snow depth. We propose to isolate the mechanisms underlying this correlation by using snowfences to manipulate winter snow depth and fertilizer to increase soil nutrient availability at three treelines that differ in soil moisture. To provide an experimental test of the importance of temperature as a direct control on treeline tree growth, we propose to incorporate experimental shoot warming into our snowfence experiment in a factorial design. We predict that both experimental snow and nutrient additions will lead to large increases in microbial activity, photosynthesis, tree growth, seed quality, seed production, seedling establishment and recruitment of new trees. We expect to observe the greatest positive responses where soils are wet and cold. Meanwhile, we predict that shoot warming will lead to negligible changes in growth. This research will elucidate the relationship between snow depth and soil nutrient availability, and determine the relative importance of nutrient and temperature limitations at treeline to white spruce – a dominant member of the boreal forest and the northernmost tree species in North America. Intellectual Merit: The position of the Arctic treeline is an important regulator of surface energy budgets, carbon cycling and subsistence resources in high latitude environments. Our recent research provides correlative evidence of the importance of winter snow depth as a driver of tree growth. Here, we propose to experimentally isolate the importance of snow depth and soil nutrient availability and examine the consequences for microbial processes and tree performance. This is a novel proposal, as we aim to link microbial ecology with large-scale landscape patterns of relevance to regional and global climates. If our hypotheses are confirmed, our findings will contradict the prevailing theory of treeline causation, alter our predictions of where and when treelines may advance and necessitate revision of the many paleoclimate reconstructions based upon correlations between temperature and tree growth near the Arctic treeline.
format Dataset
author Patrick Sullivan
Michael Weintraub
author_facet Patrick Sullivan
Michael Weintraub
author_sort Patrick Sullivan
title Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic
title_short Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic
title_full Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic
title_fullStr Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic
title_full_unstemmed Winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the Arctic
title_sort winter snow depth as a driver of microbial activity, nutrient cycling, tree growth and treeline advance in the arctic
publisher Arctic Data Center
publishDate 2020
url https://search.dataone.org/view/urn:uuid:222a4fd0-c7b5-428d-a377-54301a889966
op_coverage Agashashok River, Alaska
ENVELOPE(-162.25,-162.17,67.49,67.46)
BEGINDATE: 2016-01-01T00:00:00Z ENDDATE: 2021-01-01T00:00:00Z
long_lat ENVELOPE(-162.25,-162.17,67.49,67.46)
geographic Arctic
geographic_facet Arctic
genre Arctic
Alaska
genre_facet Arctic
Alaska
_version_ 1811920475044970496