Man-Made and Natural Fibres as a Reinforcement in Fully Biodegradable Polymer Composites: A Concise Study

Biodegradable and ecologically friendly polymer materials attract great attention of many scientific groups in the world as they fit well in the sustainable development policy and are considered to be “a right thing to do” by the general public. Such polymers can be modified by the addition of different fillers, favorably of natural origin. In the paper we provide a comparison between composites based on two biodegradable polymers: poly(lactic acid)—biodegradable, natural stock polymer and poly(butylene succinate)—biodegradable polymer produced from fossil based materials. For each polymer we have prepared a series of composites with different fibres (natural: hemp and flax, and manmade: Cordenka) and different filler loadings. To fully characterize obtained materials thermal, mechanical and surface free energy measurements were performed, completed with morphology observations and an attempt to compare the experimental data for tensile measurements with values obtained using the modified rule of mixtures. The tensile results calculated using the modified rule of mixture for below 30% fibre loading are found to be fitting the experimental data. Composites mechanical properties and morphology were strongly affected by the type of fibre used and its loading, however thermal properties remained almost unchanged. In specific, Cordenka fibres tend to form bunches which presence greatly influences the mechanical properties but still our studies have shown clear advantage of manmade Cordenka fibres over the hemp and flax fibres when considering distribution and fibre–polymer interaction.     

Optimizing a GC-MS method for screening of Stachybotrys mycotoxins in indoor environments

Presence of Stachybotrys chartarum in indoor environments has been linked to building-associated disease, however, the causative agents are unknown. Verrucarol (VER) and trichodermol (TRID) are hydrolysis products of some major S. chartarum mycotoxins, i.e. macrocyclic trichothecenes and trichodermin. We optimized gas chromatography-mass spectrometry (GC-MS) methods for detecting VER and TRID in S. chartarum-contaminated indoor environmental samples. Heptafluorobutyryl derivatives of both VER and TRID exhibited little MS fragmentation and gave much higher detection sensitivity (sub-picogram injected onto the GC column), both in GC-MS and GC-MSMS, than trimethylsilyl derivatives. Optimal detection sensitivity and specificity was achieved by combining chemical ionization and negative ion (NICI) detection with MSMS. With this method, VER and TRID were detected in building materials colonized by S. chartarum and TRID was demonstrated in dust settled in the breathing zone in a house where an inner wall was colonized. In summary, we have shown that NICI-GC-MSMS can be used to demonstrate mycotoxins in house dust in S. chartarum-contaminated dwellings.     

Physical factors influencing refraction of the echolocative sound beam in delphinid cetaceans

The delphinid melon has been postulated to function as a sound lens in which lipids refract and collimate the ultrasonic beam used for echolocation. To identify the major physical factors influencing sound-beam refraction, lipid samples from the 4 regions of the Tursiops truncatus melon were examined for variation of sound velocity with temperature. These results were then combined with available sound velocity data for Tursiops sp. melon tissue, Globicephala melaena melon lipids, G. melaena melon tissue, and seawater to model the total melon/seawater system encountered by the projected sound beam in both delphinids. Our analysis suggests that much of the refractive collimation occurs at the tissue/seawater interface rather than in the main body of the delphinid melon. Abrupt changes in the temperature and sound velocity at or near this convex interface (the forehead) cause this refraction.     

Modeling of the long-term tropospheric trends of hydroxyl radical for the Northern Hemisphere

The MGO 2D (altitude–longitude) channel photochemical transport model has been applied to elucidate the spatial and temporal behavior of the hydroxyl radical in the troposphere of the northern temperate belt for the pre-industrial (1850) period and the last few decades (1960 and 1995). The relation between the tropospheric OH content and the carbon monoxide, methane, nitrogen oxides emissions during 1850–1995 is studied. The distribution of the carbon monoxide concentration is calculated and validated using the observational data collected in the different locations because of the geographical non-homogeneity of its emissions. The response of the hydroxyl radical concentrations to the non-homogeneity of the CO and other atmospheric species distribution is estimated. The carbon monoxide and methane contributions to the hydroxyl photochemical sink are also evaluated. Because the changes of OH in the troposphere alternate the intensity of methane and carbon monoxide oxidation, the CO, CH₄ and OH lifetime evolution due to the increase of anthropogenic pollution intensity is analyzed and discussed.     

Reconstruction of the methane fluxes from the west Siberia gas fields by the 3D regional chemical transport model

A 3D mesoscale tropospheric photochemical transport model of high spatial resolution has been developed and used for assessment of the methane concentrations and methane emission in the West Siberian region of intensive mining of natural gas and oil deposits. The model is validated against the measurements of methane concentration at the surface and in the lower troposphere collected during July 1993 and June 1996 experiments. Comparison of the simulated and observed concentrations allowed to estimate that during the above periods the average natural methane fluxes were as high as 65 mg m⁻² day⁻¹. The anthropogenic methane fluxes (leakage from gas deposits) integrated over model domain during the same time period were about 20% of the total methane emission from relevant areas.     

Mapping atmospheric depositions of cadmium and lead in Germany based on EMEP deposition data and the European Moss Survey 2005

Background

The vertical migration of phytoplankton was investigated in natural waters using in situ fluorescence profiling, chlorophyll a concentrations and life counts at two study sites differing in coloured dissolved organic matter (cDOM) concentrations. The data from the corresponding water depths (50-cm intervals down to 10 m) and times (hourly, before dawn to sunset, several days) were related to the highly resolved (2 nm) underwater ultraviolet radiation (UVR)/photosynthetic active radiation (PAR) transparency (290 to 700 nm).

Results

Chlorophyll a maxima of mainly motile dinoflagellates were observed in situ at all days and at both study sites (open marine, brackish waters), independent on prevailing weather conditions or cDOM concentrations. Phytoplankton migration was triggered solely by irradiance in the 400- to 700-nm wavelength range (PAR) at the particular water depth, irrespective of PAR/UVR ratios and surface UVR (290 to 400 nm), after an illumination period of about 40 min. Interestingly, the PAR tolerance levels of the phytoplankton, which have been lower in cDOM-rich waters, matched their light acclimation values determined by parallel PAM measurements.

Conclusions

The response of the phytoplankton to PAR is not a sufficient protection strategy versus increasing UVR levels, which might have wide ecological implications beyond the level of primary producers to impact important ecosystem functions such as the delicate trophic interactions.     

Wild plant species in bio-indication of radioactive-contaminated sites around Jaslovské Bohunice nuclear power plant in the Slovak Republic

In a long-term study of contaminated soil around Jaslovské Bohunice nuclear power plant (NPP), 24 species of local flora were used to show impact of serious accidents from 1976 to 1977. The 19-km-long banks of the Jaslovské Bohunice NPP wastewater recipient have been identified as contaminated by (137)Cs. In total, more than 67,000m(2) of riverbanks have been found as being contaminated at levels exceeding 1Bq (137)Csg(-1) of soil. Used phytotoxic and cytogenetic "in situ" tests were extended by analyses of pollen grains. Although the dose of some samples of radioactive soil was relatively high (322kBqkg(-1)) no significant impact on the biological level of tested wild plant species was observed.     

Methane Fluxes in West Siberia: 3-D Regional Model Simulation

The West Siberian region is one of the main contributors of theatmospheric greenhouse gas methane due to the large areas ofwetlands, rivers, lakes and numerous gas deposits situated there.But there are no reliable estimations of integral methane flux fromthis area into the atmosphere. For assessment of methane fluxes inWest Siberia the specially constructed 3-D regional chemicaltransport model was applied. The 3-D distribution of methane iscalculated on the basis of the current meteorological data fields(wind, temperature, geopotential) updated 4 times a day. The methaneconcentrations measured near the main gas fields of West Siberia inthe summer season of 1999, were used for correction of methane fluxintensity estimates obtained previously by comparison ofmeasurements carried out in summer 1993 and 1996 with modelledmethane mixing ratio distribution. This set of field and modelexperiments confirmed the preliminary conclusion about low leakageintensity: anthropogenic methane flux does not exceed 5–15% oftotal summer methane flux, estimated as 11–12 Mt CH₄ in summer from this region, in spite of the large areas of gas deposits located there.     

Klimawandel und zukünftig mögliche temperaturgesteuerte Malariatransmission in Deutschland

Background, aim and scope On behalf of the Centre of Excellence for Climate Effects and Adaption (KomPass) of the German Federal Environment Agency (UBA) an Expert Information System on Climate Change and Adaption (FISKA) was developed. FISKA shall provide the governmental institutions with basic information and models on climate change impacts for the development and accomplishment of adaption strategies. In this paper the impact model on potential temperature-dependent malaria transmissions is presented. It shows how, together with the REMO and WettReg climate models implemented in FISKA, areas at risk of malaria can be identified. Materials and methods FISKA was developed as an open and modular expert information system and allows the exchange of data and information with other institutions. Climate change impacts are implemented as calculation engines. The system allows for implementing additional data and impact models to improve existing impact models. For the calculation of the temperature-dependent potential secondary malaria infections the basic reproduction rate was used and the according algorithms were implemented in two calculation engines. One engine allows the calculation of the secondary infections and the other allows the calculation of the seasonal transmission gates. Measured air temperatures for the period 1961–2007 were provided by the German Meteorological Service (DWD), data on future air temperatures were extracted from the climate models REMO and WettReg for the climate reference periods 1991–2020, 2021–2050, and 2051–2080. The respective secondary infections and the resulting seasonal transmission gates for each period were regionalised on the basis of an ecological land classification to analyse significant ecoregional differences. Results Comparing the climate reference period 1961–1990 and the following period 1991–2007, the proportion of Germany featuring a potential seasonal malaria transmission gate of one or rather two months has been reduced in favour of a three months transmission gate. Accordingly, in the period 1991–2007 malaria transmissions during three months are possible on 70?% of the German territory instead of 26?% in 1961–1990. The percentage of a four months transmission gate has increased from 0.02?% to 0.76?%, and even a five months transmission is possible on 0.15?% of Germany. For future periods the number of potential secondary infections increases and further extensions of the seasonal transmission gates were revealed. In case of REMO A1B in 2051–2080, almost whole Germany features thermal conditions allowing malaria transmissions during four or rather five months. Discussion Rising air temperatures lead to changes in the spatial structure of the ecological elementary factor temperature, which can, under otherwise identical conditions, facilitate the reproduction of pathogens (here Plasmodium vivax) and vectors (here Anopheles atroparvus) as well as the spread of diseases. The basic reproduction rate serves the calculation of secondary malaria infections, which are the infections of host by a vector under the assumption that every member of the host population is susceptible for the pathogen. Improved thermal conditions alone do not necessarily imply the development of a malaria epidemic. Other factors like population density or medical care and the presence of vector habitats are of major importance, however, not considered by the calculation engines. The example of malaria is intended to be a model for a range of temperature-dependent vector-borne diseases. Conclusions The impact model on temperature-dependent malaria infections shows exemplarily the information content and functionality of FISKA. Data and functionality of FISKA serve as an expert information system for the detection of risks due to climate change. The results can be published as interactive maps via the FISKA internet interface. From a technical point of view, every impact model based on a calculation engine can be implemented and published via the web interface, provided that the impact models and the resulting risk maps rely on scientific reliable assumptions and are documented comprehensively. Recommendations and perspectives An improvement of FISKA considering the European scale is technically possible. It would require the development of GIS- and model applications on the basis of Europe-wide basic and specific data. For small-scale model runs a dynamic modelling of the water balance including soil hydrology as well as consideration of microclimate effects are required.