Abstract
Scots pine (Pinus sylvestris L.) is a widespread species throughout Europe and at the same time is dominant in Polish forests and of key importance in the wood industry. Pine stands are subjected to numerous environmental stresses, and one of them is the different physico-chemical and biological properties of post-agricultural soils compared to forest soils, which may affect the properties of the resulting wood and its industrial suitability. The research material taken at the height of 1.3 m from tree trunks (breast height diameter, dbh) in the form of sections and discs was collected in an 80-year-old pine stand from four plots, representing former agricultural and ancient forest land, and two types of habitats: fresh coniferous forest and fresh mixed coniferous forest. The forest habitat trophy had a decisive impact on the dendrometric characteristics and properties of pine wood (density, modulus of elasticity, bending strength, and compressive strength along the tracheids). The history of soil use (post-agricultural or forestry) did not affect the analyzed pine wood properties. Regardless of the forest habitat type and soil type history, pine wood at the dbh height showed a variability of features typical of century-old cultivated stands. Individual pine trunks were characterized by significant individual variability.
Highlights
The course of xylogenesis in trees as well as the properties of wood tissue resulting from this process are important issues in cognitive as well as practical aspects, in particular for forest management
The present work is a part of wider research on the trunk wood structure and properties of Scots pines from stands on former farmlands or ancient forests within two habitats: fresh coniferous forest and fresh mixed coniferous forest
Scots pine trunks from fresh coniferous forest were characterized by smaller diameters at the breast height and a smaller proportion of sapwood compared to the trunks of pine trees from the moist mixed forest
Summary
The course of xylogenesis in trees as well as the properties of wood tissue resulting from this process are important issues in cognitive as well as practical aspects, in particular for forest management Both the division activity of cambium underlying the entire process of secondary wood formation [1,2] as well as the subsequent stages of derivative cell differentiation are controlled genetically [3,4] and epigenetically—i.e., regulated by internal and external factors acting in the environment [5,6]. The formation of forests on former agricultural land can arise through a natural secondary progression, but in recent times, especially in Europe, it is mainly the result of intentional afforestation [10,11,12] This initiative was promoted by the European Economic Community‘s (EEC)
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