After determination of dry mass (DM) of each stem, allometric relationships were established between stem or shoot diameter and aboveground dry mass, fitted as DM = a⋅Db for both genotypes, with a and b as regression
coefficients ( Broeckx et al., 2012). Root samples were analyzed for their C and N mass fractions by dry combustion using a NC-2100 element analyzer (Carlo Erba Instruments, Italy). Root selleck screening library mass was converted to C mass using the average root C mass fraction, and expressed in g C m−2. For 2011 and 2012, Fr production (P) and mortality (M) were calculated using the “decision matrix” approach ( Fairley and Alexander, 1985). The values of P and M were calculated separately for each Fr diameter class (i.e. 0–1 mm and 1–2 mm) and then added on each sampling date. All differences in biomass and necromass were taken into account during the calculation, assuming that the living and dead pools were continuously changing. This approach was better than using the significant differences between root mass of consecutive sampling dates, especially in the case of high-frequency sampling ( Brunner et al., 2013), such as in our sampling campaign. For the calculation of the annual P,
the productivity values from all sampling periods were summed from the beginning till the end Fluorouracil chemical structure of the year. More details on the calculation of root productivity and on the comparison of different methods to assess P can be found in Berhongaray et al. (2013a). Allometric equations were used to scale-up belowground woody biomass components
based on measurements of basal area (BA). The BA of each tree was calculated as BA = Σ(π∗(Di/2)2), the sum of the calculated area of all the shoots (Di = diameter of each individual shoot) for each selected tree. All stem or shoot diameters, and all BAs refer to measurements taken at a height of 22 cm above the soil. Stu, Cr and Mr biomasses were plotted against BA and allometric linear equations were fitted. The most reliable equations with higher determination coefficients (R2) were selected. Average belowground woody root biomass (Cr and Mr) and stump biomass pool were estimated from the allometric equations and the full stem diameter inventory of each sampling year, made up in winter 2011–2012 and in winter 2013–2014. The root:shoot ratio is commonly Adenosine defined as the root biomass divided by the shoot biomass. The distinction between ‘root’ and ‘shoot’ is generally made at the ground surface level: the term ‘root’ refers to all biomass below the ground surface and ‘shoot’ represents all biomass above the ground surface. In the present study, the root:shoot ratio was calculated using woody biomass only (Cr, Mr, Stu, stem and branches), and excluding Fr and leaves. As the studied trees were planted in a SRWC plantation, we considered the harvesting height as the upper limit for the belowground biomass, instead of the ground surface.