Education | Forest Function | Global Carbon | Land/Water | Landcover/Land Use | Science in Public Affairs
Building Tours | Seminars | Global Warming Primer | Staff Essays | Published Literature | Related Sites
Education | Forest Function | Global Carbon | Land/Water | Landcover/Land Use | Science in Public Affairs
Building Tours | Seminars | Global Warming Primer | Staff Essays | Published Literature | Related Sites
 |
Delta Junction Field MeasurementsPAR cell phenology
The Fraction of Photosynthetically Active Radiation (FPAR) absorbed by the forest canopy has been the subject of a great deal of research in the past two decades. In simple terms FPAR is a measure of the amount of incident visible light absorbed by plant tissues, or the amount of light harvested by a canopy. Because light absorption drives the photsynthetic process, FPAR is directly related to photosynthesis and the rate of carbon fixation. Therefore, measurements of FPAR are often used to drive models of net annual carbon uptake or net primary production (NPP). FPAR varies in both spatial and temporal extent. Spatially, FPAR exhibits a large amount of variability between stands due to differences in species composition and canopy structure. Temporally, FPAR varies throughout the growing season due to spring leaf growth and fall leaf litter as well as changes in sun angle. Because coniferous species hold their needles year-round, coniferous stands do not show the same seasonal variability in FPAR as deciduous stands. In the Delta Junction study region we use arrays of PAR cells (see images to the right) to measure both the temporal and spatial variability in FPAR across a number of different stand types under differing environmental conditions. Because the PAR cells measure transmitted light, we must also measure PAR above the canopy and calculate FPAR based on the difference between above canopy and below canopy PAR values:
FPAR = 1 - (PARbelow canopy / PARabove canopy)
The FPAR data we obtain are then used to parameterize models of NPP and validate remotely sensed estimates of FPAR. Leaf Area Index (LAI)
LAI is a fundamental characteristic of vegetation relating directly to the exchange of energy, mass, and water between the plant canopy and the atmosphere. It is an index of canopy density that compares the foliage surface area to the ground area beneath the canopy. It is strictly defined as one-half the total green leaf area per unit of ground surface area. Estimates of LAI are used as an ecophysiological measure of the effective photosynthetic and transpirational surface within a canopy, which has important implications for modelling net primary production and evapotranspiration between forests and the atmosphere. It is important to note however, that LAI is less frequently used to drive ecosystem carbon models due to the more direct association of FPAR with photosynthesis.
In the Delta Junction study region, coordinated ground and remotely based measurements of LAI are carried out throughout the growing season. These data are used to compare different methods of field-based measurement (using the LAI-2000 and AccuPar instruments), and to assess the accuracy of ongoing remote estimates of FPAR and leaf area index. The data exhibit a large amount of variability between stands. Inter-stand variability is generally a result of differences in species composition, stand age, and the chemical and physical characteristics of the landscape, such as water and nutrient availability.
Flux TowersIn order to directly monitor how fire and changes in climate will affect net ecosystem carbon exchange, we make use of eddy covariance measurements to estimate local carbon exchange. Eddy covariance essentially measures 3-dimensional wind velocity and gas exchange simultaneously and results in an estimate of the vertical carbon dioxide exchange. Eddy covariance measurements have been collected by collaborator Jim Randerson and co-investigator Heping Liu continuously since early 2000 at two towers in the study area, one in the 1999 burn, and another in the 1920 burn now occupied by black spruce forest. An additional tower was established in 2001 and is operating in the 1987 burn site, now occupied predominantly by aspen.
|
|
||||||||||||||||||||||||||||||||||||||||||
©Woods Hole Research Center, 2007 |
||||||||||||||||||||||||||||||||||||||||||||
