Estimating fine-root biomass and pr

Estimating fine-root biomass and production of boreal and cool temperate forests using aboveground measurements
The most important methodological difference between estimates of aboveground and fine-root biomass is that the biomass of aboveground components is usually estimated at the tree level (TerMikaelian and Korzukhin, 1997) whereas fine-root biomass is typically estimated at the stand level (e.g., Kurz et al., 1996; Cairns et al., 1997; Vogt et al., 1996). For aboveground components, researchers typically sample trees over a wide-range of tree sizes and measure the biomass of these components for each tree. Tree-level allometric equations are then developed by relating the biomass of these components to easily measurable variables such as tree diameter at breast height (DBH). Bio- mass of all these aboveground components can then be estimated at the stand-level using these allometric equations in combination with the tree size distribution (e.g., Baskerville, 1965; Chen, 2002). In contrast, measurements of fine-root biomass generally represent a stand – level average instead of that of a specific tree because linking fine-roots to a specific tree is very difficult – if not impossible (Vogt et al., 1998). Direct tracing of fine-roots to individual trees is only possible under some particular situations such as a sub-arctic lichen woodland where fine-roots tend to occur directly below the lichen mat and penetrate the soil humus layer only slightly if at all (Rencz and Aclair, 1980).
Variation in FRB in relation to stand and environmental characteristics
To analyse the relationships between FRB and stand or environ- mental characteristics we used a larger dataset with more variation in the dependent variables (Table 2) than had been done earlier (Vogt et al., 1986, 1996; Leuschner and Hertel, 2003; Chen et al., 2004; Finér et al., 2007) and found only one significant relationship between the tree stand (age and basal area) and the environmental variables (latitude, elevation and precipitation) and the stand level FRB. That was less than in the earlier studies, since we accepted only statistically significant results and equations where the degree of determination was ≥30%. The combination of all the tree stand and environmental variables in the regression models could not explain more than that achieved with any of the tree stand or environmental variables alone. Also, only a small proportion of the variation in the stand level FRB had been explained with these variables in the previous works. Additional explanatory variables, ones related to soil e.g. nutrition, water availability, permeability or above-ground biomass characteristics, or else more comparable data, could probably increase the degree of determination somewhat (Li et al., 2003; Helmisaari et al., 2007; Vogt et al., 1996). The stand variables age or stand density did not explain the variation in total FRB or the FRB of trees in our material. Total FRB did not have any relationship with stand basal area and the FRB of trees increased with the stand basal area. In earlier studies in which the relationships were studied by tree species or species groups the FRB has either increased or decreased with stand age and decreased with stand basal area (Leuschner and Hertel, 2003; Finér et al., 2007). Chen et al. (2004), who also combined data on different tree species in the temperate and boreal zones, found that FRB increased with stand basal area. We did not find significant relationships between the environmental variables and FRB opposite to earlier studies (Vogt et al., 1986, 1996; Leuschner and Hertel, 2003; Finér et al., 2007). Our results were not fully comparable with earlier ones since we combined several species in our analyses, our data had wider variations in latitude, elevation and annual precipitation. that the variation in FRB at the tree level can be explained on the basis of tree stand variables to a higher degree than at the stand level (Chen et al., 2004; Finér et al., 2007; Helmisaari et al., 2007).