The role of biogeophysical feedbacks and their impacts in the arctic and boreal climate system
The physical environment in the northern high latitudes including the Arctic cryosphere has undergone dramatic changes due to anthropogenic greenhouse gas warming, which since pre-industrial times has been twice or more the rate of global mean warming. Global climate models predict that this acceler...
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| Format: | Doctoral or Postdoctoral Thesis |
| Language: | English |
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Department of Physical Geography and Ecosystem Science, Lund University
2015
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| Online Access: | https://lup.lub.lu.se/record/4936205 https://portal.research.lu.se/files/5848064/4936253.pdf |
| Summary: | The physical environment in the northern high latitudes including the Arctic cryosphere has undergone dramatic changes due to anthropogenic greenhouse gas warming, which since pre-industrial times has been twice or more the rate of global mean warming. Global climate models predict that this accelerated warming will continue for at least the next few decades. Meanwhile, the arctic and subarctic vegetation have been reported to be rather sensitive to such rapid warming. Biogeophysical feedbacks associated with ecosystem responses to climate change are regarded as important contributors to the amplified warming seen over the Arctic. This motivates a study to assess firstly how vegetation dynamics and ecosystem biogeochemistry will evolve under plausible future scenarios, and further how biogeophysical feedbacks associated with vegetation change will influence the climate, carbon cycle and sea ice. In addition, a regional Earth system model (ESM), as a complementary modeling alternative to relatively well-established global ESMs, can describe relevant processes and interactions in more detail and at a finer resolution in time and space. This can lead to better understanding of feedback phenomena characteristic of the Arctic climate system, as well as providing useful information on ecosystem impacts and the associated needs for adaptation they may imply. In this thesis, I present findings from studies using an individual-based dynamic vegetation model (LPJ-GUESS) and regional Earth system models (RCA-GUESS, and RCAO-GUESS) to explore the role of biogeophysical feedbacks and their impacts on the Arctic climate system. These models demonstrate good performance in reproducing the present-day dominant vegetation distribution, carbon, water and energy exchange between the land and atmosphere, the mean state of carbon pools and climate, sea ice concentration and areal extent. Thereby they provide a robust base-line for understanding and characterizing ecosystem feedbacks to the Arctic climate. Under future projections, ... |
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