Seasonal variation in root growth capacity during cultivation of container grown Pinus sylvestris seedlings

Root growth capacity (RGC) in Scots pine seedlings was studied from the time of sowing and during the following two growing seasons. The method used for measuring RGC is also described. In the first growing season root growth was intense during the period mid‐July to mid‐September with an earlier peak for early sowing dates. After a period of low growth activity during winter, RGC rose sharply in early spring. During periods of intensive shoot elongation in May and June root growth was depressed. After shoot elongation was completed, RGC rose again before declining during the autumn. During winter and the second growing season, higher RGC levels were obtained for seedlings sown in June compared to the ones sown in April. This result is discussed with regard to differences in cultivation regimes.     

Photosynthesis and root respiration of Pinus sylvestris and picea abies seedlings after different root freezing and storage temperatures

Photosynthetic performance and root respiration were measured for seedlings of Scots pine and Norway spruce under constant conditions in an open gas exchange system in the laboratory. Measurements were carried out after root exposure to ‐20, ‐5 and 0°C and subsequent longtime storage in darkness at +1 or +4°C. Stomatal conductance in relation to net photosynthetic rates was also investigated after the same treatment of seedlings. Root respiration was low for seedlings whose root system had been exposed to ‐20°C, Scots pine showing lower rates than Norway spruce. This was probably an indication of root damage. At least for one provenance of Scots pine, respiration rates were higher for seedlings stored at +1 than at +4°C. Photosynthetic performance was also lowest for seedlings whose roots had been exposed to +20°C compared to higher temperatures, the difference being more clear‐cut for Norway spruce than for Scots pine. Storage at +1 gave slightly higher photosynthetic rates than at +4°C. There was a close relation between stomatal conductance measured on individual needles and photosynthetic performance measured on the whole seedling.     

Planting performance potential of Pinus sylvestris seedlings as evaluated by root growth capacity and triphenyl tetrazolium chloride reduction methods

Root growth capacity (RGC) and root viability by the reduction of triphenyl tetrazolium chloride (TTC) of Scots pine (Pinus sylvestris L.) seedlings were measured in the winter and spring after freeze‐induced stress (0, ‐10, ‐15, ‐20°C). After freezing, seedlings were also stressed with different storage temperatures, and drying. Field performance during two years at two sites was used to determine the prediction abilities of the two test methods. RGC and TTC differed between the winter and spring tests. Coefficients of variation (CV) for RGC were larger in the winter than in the spring. The opposite applied for TTC. RGC was significantly lower in the winter than in the spring. TTC reduction was lower in the spring than in the winter. RGC‐ and TTC‐values decreased as freezing temperatures were lowered. Correlation coefficients between treatment means of RGC and TTC were low. Coefficients of determination (r ²) of linear regressions of RGC to the field performance attributes, first and second year diameter increment, height increment, and survival, were between 0.30 and 0.40. For TTC the revalues ranged from 0.50 to 0.80. In general, the TTC‐method seemed to be a better indicator of Scots pine seedling performance in the field.