Impacts of different thinning regimes in the yield of uneven-structured Scots pine stands on drained peatland

Abstract

Sydänpuuvaltaisen erikoiskuivatun mäntysahatavaran kosteuspitoisuus kuivausjännitykset eri puuaineen tiheyksissä

Puualan lisääntyvä tarve tuottaa jatkojalosteita on asettanut kuivauksen laatutasolle uusia haasteita ja laadukkaan kuivauksen tulos on perusta jatkojalosteiden toimivuudelle. Yhä enemmän tarvitaan kuivausprosessin ja kuivattavan puumateriaalin kontrollointia läpi koko kuivausprosessin. Näillä toimenpiteillä varmistetaan haluttu kuivauslaatu sisäisille ja ulkoisille asiakkaille yrityksessä. Tämän tutkimuksen tarkoituksena oli selvittää männyn sydänpuuhun muodostuvaa kosteuspitoisuutta kamarikuivausprosessissa. Keinokuivauksen tavoitteellinen loppukosteus oli 12 % kuivapainosta puumateriaalia. Jo aikaisempien tutkimusten perusteella on voitu osoittaa, että loppukosteuden arvo vaihtelee kuivauserässä eri _kappaleiden välillä johtuen puumateriaalin epähomogeenisuudesta. Sydänpuuvaltainen ja tiheä mäntysahatavara, joka sahataan tyvitukeista läheltä juuriosaa sisältää tämän tutkimuksen mukaan runsaasti pihkaa verrattuna latvaosassaan samaa sahetta. Kosteusgradientti on myös suurempi sahatavarakappaleiden tyviosassa. Vuosikasvun ja tiheyden korrelaatio on heikko männyn sydänpuulla. Kesäpuuprosentin korrelaatio tiheyteen on erittäin merkittävä. Pihkapitoisuus lisää puuaineen tiheyttä tyviosassa sahetta. Pintakovuus on puumateriaalin muodonmuutos potentiaali, kun kosteuspitoisuudet tasaantuvat poikkileikkauksessa. Kosteusgradientilla on selvä yhteyspintakovuuteen eli muodonmuutospotentiaaliin.

Fibre-reinforced composites as root canal posts

Fibre-reinforced composite (FRC) root canal posts are suggested to have biomechanical benefits over traditional metallic posts, but they lack good adhesion to resin composites. The aim of this series of studies was to evaluate the adhesion of individually formed fibre-reinforced composite material to composite resin and dentin, as well as some mechanical properties. Flexural properties were evaluated and compared between individually formed FRC post material and different prefabricated posts. The depth of polymerization of the individually formed FRC post material was evaluated with IR spectrophotometry and microhardness measurements, and compared to that of resin without fibres. Bonding properties of the individually formed FRC post to resin cements and dentin were tested using Pull-out- and Push-out-force tests, evaluated with scanning electron microscopy, and compared to those of prefabricated FRC and metal posts. Load-bearing capacity and microstrain were evaluated and failure mode assessment was made on incisors restored with individually formed FRC posts of different structures and prefabricated posts. The results of these studies show that the individually polymerized and formed FRC post material had higher flexural properties compared to the commercial prefabricated FRC posts. The individually polymerized FRC material showed almost the same degree of conversion after light polymerization as monomer resin without fibres. Moreover, it was found that the individually formed FRC post material with a semiinterpenetrating polymer network (IPN) polymer matrix bonded better to composite resin luting cement, than did the prefabricated posts with a cross-linked polymer matrix. Furthermore, it was found that, contrary to the other posts, there were no adhesive failures between the individually formed FRC posts and composite resin luting cement. This suggests better interfacial adhesion of cements to these posts. Although no differences in load-bearing capacity or microstrain could be seen, the incisors restored with individually formed FRC posts with a hollow structure showed more favourable failures compared to other prefabricated posts. These studies suggest that it is possible to use individually formed FRC material with semi-IPN polymer matrix as root canal post material. They also indicate that there are benefits especially regarding the bonding properties to composite resin and dentin with this material compared to prefabricated FRC post material with a cross-linked matrix. Furthermore, clinically more repairable failures were found with this material compared to those of prefabricated posts.

Quantitative elemental analysis of dry-ashed bark and wood samples of birch, spruce and pine from south-western Finland using PIXE

A total of over 200 different samples of bark and wood of Silver birch, Norway spruce and Scots pine were analysed. Samples were taken from several areas in western Finland, some with known sources of atmospheric heavy metal emission (Harjavalta, Ykspihlaja). Also analytical data for pine needles from some sites are reported. The chemical analyses were performed by thick-target particle-induced X-ray emission (PIXE) spectrometry after preconcentration by dry ashing of samples at 550oC. The following elements were quantified in most of the samples: P, S, K, Ca, Mn, Fe, Ni, Cu, Zn, Rb, Sr, Cd, Ba and Pb. The ash percentage and the chemical composition of ashes of different wood materials were also obtained, as dry ashing was used in the analytical procedure. The variations in elemental concentrations in wood and bark of an individual tree, expressed as RSDs, were mostly in the range 10 – 20 %. For several trees of the same species sampled from small areas (< 1 ha), the variations in elemental concentrations were surprisingly high (RSDs 20 – 50 %). In the vicinity of metal plants, effects of strong atmospheric heavy metal pollution (pollution factor above 100) were observed in pine bark. The increase of heavy metal content in wood samples from the same sites was quite small. Elemental concentrations in ashes of bark and wood, from areas with no local source of atmospheric pollution, were relatively uniform. Based on this observation an alternative way of demonstrating atmospheric pollution of tree bark is discussed.