HPCCprojects:Numerical Modeling of Permafrost Dynamics in Alaska using a High Spatial Resolution Dataset: Difference between revisions

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==Project description==
==Project description==
Permafrost is a lithospheric material where temperatures have remained at or below 00C for a period of at least two consecutive years.<br />
Permafrost is a lithospheric material where temperatures have remained at or below 0°C for a period of at least two consecutive years.<br />
Permafrost is one of the main components of the cryosphere in northern
Permafrost is one of the main components of the cryosphere in northern
regions, which influences hydrological processes, energy exchanges,
regions, which influences hydrological processes, energy exchanges,
Line 27: Line 27:
The nature of permafrost existence is complex enough and cannot be
The nature of permafrost existence is complex enough and cannot be
addressed based only on climatic data (Shur and Jorgenson, 2007). In
addressed based only on climatic data (Shur and Jorgenson, 2007). In
this project we employed more sophisticated approach which includes all important factors affecting permafrost thermal regime such as snow, organic layer, soil physical properties and subsurface water content. The original version of the model was developed by G. Tipenko and V. Romanovsky (2004). Later it was extended to the spatial case and first time applied for the entire Alaskan permafrost domain with 0.50 spatial resolution by Marchenko et al, (2008). <br />
this project we employed more sophisticated approach which includes all important factors affecting permafrost thermal regime such as snow, organic layer, soil physical properties and subsurface water content. The original version of the model was developed by G. Tipenko and V. Romanovsky (2004). Later it was extended to the spatial case and first time applied for the entire Alaskan permafrost domain with 0.spatial resolution by Marchenko et al, (2008). <br />
To determine the social-economic impart of permafrost thaw on ecosystem and infrastructure higher spatial resolution is required. In order to employ the model to simulate the ground temperatures in higher spatial resolution we need make it parallel by distributing the amount of computational load  between processors. The GIPL2-MPI is a parallel version of the GIPL2 spatial model used by Marchenko et al, 2008.
To determine the social-economic impact of permafrost thaw on ecosystem and infrastructure higher spatial resolution is required. In order to employ the model to simulate the ground temperatures in higher spatial resolution we need make it parallel by distributing the amount of computational load  between processors. The GIPL2-MPI is a parallel version of the GIPL2 spatial model used by Marchenko et al, 2008.
==Objectives==
==Objectives==
* Bulleted list item
* How well is the simulated map represent the current thermal state of permafrost? (model calibration and validation)
* How well the simulated map represent the present state of permafrost (model calibration and validation)


* What might be the possible future permafrost thermal state?
* The importance of microclimate and other environmental controls affecting permafrost thermal regime.


* The importance of microclimate and other environmental controls affecting permafrost
* What might be the possible permafrost thermal state by the end of 21st century?


==Time-line==
==Time-line==
<span class="remove_this_tag">Provide (estimated) start date & end date, etc</span>
{|
|Start date:
|01/01/2008
|-
|End date:
|12/31/2014
|}


==Models in use==
==Models in use==
<span class="remove_this_tag">Information about models / software you use</span>
{|
| [[Model:GIPL|GIPL]]
| numerical transient heat flow model
|}


==Results==
==Results==
Line 51: Line 59:


==Funding==
==Funding==
<span class="remove_this_tag">Provide your project funding sources including the award number</span>
Financial support provided by the National Science Foundation ( projects [http://www.nsf.gov/awardsearch/showAward.do?AwardNumber=0520578 0520578];
[http://www.nsf.gov/awardsearch/showAward.do?AwardNumber=0632400 0632400];
[http://www.nsf.gov/awardsearch/showAward.do?AwardNumber=0856864 0856864]) and the State of
Alaska


==Publications and presentations==
==Publications and presentations==

Revision as of 14:55, 3 December 2010


Numerical Modeling of Permafrost Dynamics in Alaska using a High Spatial Resolution Dataset

Project description

Permafrost is a lithospheric material where temperatures have remained at or below 0°C for a period of at least two consecutive years.
Permafrost is one of the main components of the cryosphere in northern regions, which influences hydrological processes, energy exchanges, natural hazards and carbon budgets. Recent publications report a gradual increase of mean annual permafrost temperatures in Alaska (Romaniovsky et al, 2010 and Smith et al, 2010). Thawing of permafrost might cause the land to sink and collapse, damaging forests, homes, and infrastructure. Economists estimate that thawing permafrost will add billions of dollars in repair costs to public infrastructure (Larsen et al., 2008).

The nature of permafrost existence is complex enough and cannot be addressed based only on climatic data (Shur and Jorgenson, 2007). In this project we employed more sophisticated approach which includes all important factors affecting permafrost thermal regime such as snow, organic layer, soil physical properties and subsurface water content. The original version of the model was developed by G. Tipenko and V. Romanovsky (2004). Later it was extended to the spatial case and first time applied for the entire Alaskan permafrost domain with 0.5° spatial resolution by Marchenko et al, (2008).
To determine the social-economic impact of permafrost thaw on ecosystem and infrastructure higher spatial resolution is required. In order to employ the model to simulate the ground temperatures in higher spatial resolution we need make it parallel by distributing the amount of computational load between processors. The GIPL2-MPI is a parallel version of the GIPL2 spatial model used by Marchenko et al, 2008.

Objectives

  • How well is the simulated map represent the current thermal state of permafrost? (model calibration and validation)
  • The importance of microclimate and other environmental controls affecting permafrost thermal regime.
  • What might be the possible permafrost thermal state by the end of 21st century?

Time-line

Start date: 01/01/2008
End date: 12/31/2014

Models in use

GIPL numerical transient heat flow model

Results

List the results of your project

Users

List the CSDMS HPCC users of your project:

  • <name HPCCuser>

Funding

Financial support provided by the National Science Foundation ( projects 0520578; 0632400; 0856864) and the State of Alaska

Publications and presentations

This would be the place to list your achievements, journal articles, conference abstracts, etc

Links

This would be the place to provide links that are related to your project.

Choose one of the two categories mentioned below, that your project suites the best

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