Wolfejosefsen8101

The MPs were characterized by Raman spectroscopy as polystyrene (PS), polypropylene (PP), and a variety of other materials with different levels of deterioration. The images obtained by scanning electron microscopy (SEM) showed different disintegration features. Moreover, the SEM analyses revealed the occurrence of adhered particles and diatoms on the surface of MPs. The adsorption of various elements onto the MPs surface and the adhered particles was confirmed by energy-dispersive X-ray spectroscopy. The conducted studies emphasized the significance of the impact of large urban agglomerations, such as the Warsaw metropolitan area, on the concentration of MPs in rivers. Further studies are needed to better assess, for instance, the precise mode through which MPs in urban regions are transported by rivers to the seas.Remanufacturing has been regarded as an environmentally friendly way to dispose of End-of-Life (EOL) products to like-new condition, which can effectively save resources, energy and greatly prolong the service life of products. After entering the remanufacturing system, EOL products are disassembled into individual parts that may have different failure types and degrees, thus not all of them are suitable for remanufacturing. Remanufacturability needs to be conducted to determine the feasibility of remanufacturing. Due to the products' structural complexity and customer demand uncertainty, many factors need to be considered when evaluating the remanufacturing feasibility of waste products. In this article, we take three pillars of sustainable development as decision factors and make a comprehensive literature review on the technical performance indicator (TPI), economic cost indicator (ECI) and environmental benefits indicator (EBI) of remanufacturability to emphasize the importance of remanufacturability. The purpose of this literature review is to conduct critical review on the current literature and establish a contemporary understanding of the status of remanufacturability study by assessing the advantages and disadvantages of existing methods in this field. The research results demonstrated that there was relatively a lack of research on technical feasibility assessment, more on economic and environmental assessments. Most of remanufacturability assessment approaches are comprehensive, considering multiple factors. This article summarizes the limitations of previous evaluation methods, proposes the challenges and future development trends. It is concluded that design for remanufacturing, finding it will be one of the hot topics in the future remanufacturing research, which will provide valuable insights for academia and industry.The unprecedented scale and impact of COVID-19 pandemic, and the accompanying lockdown implemented across many countries, has exacerbated water scarcity and security globally. KPT-330 ic50 Many European governments have introduced policy interventions to mitigate and protect their economies. Yet, water resources, which are a potential enabler in revitalising Europe's economy, have received few of such policy interventions since the World Health Organization declared the COVID-19 outbreak as a public health emergency only in January 2020. Our scoping review of preliminary government responses of 27 European countries revealed that only 11 (40.7%) of these countries implemented at least one policy intervention that considered the water sector. These interventions were typically short-term measures involving either full cost absorption or deferment of water bills. Much attention on water governance and management processes, policies and financial investments required to augment the resilience of the water sector amid a growing scarcity of freshwater, triggered by extreme climate variation and also by COVID-19 pandemic should therefore be central to post COVID-19 recovery efforts in Europe. This paper also proposes future research directions, including a study that will harmonise water demand and consumption trends during the pandemic in Europe and an assessment on how the water sector can withstand possible external shocks in future.Potentially Toxic Elements (PTEs) in Badgers (Meles meles), otherwise known as heavy metals, are unique amongst environmental pollutants occurring, both naturally and anthropogenically. PTEs have a broad range of negative health and environmental effects, therefore identifying their sources and pathways through the environment is imperative for public health policy. This is difficult in terrestrial systems due to the compositional nature of soil geochemistry. In this study, a compositional statistical approach was used to identify how PTEs accumulate in a terrestrial carnivorous mammal, Eurasian Badgers (Meles meles). Compositional principal component analysis (PCA) was used on geochemical data from the Tellus survey, the soil baseline and badger tissue data to map geo-spatial patterns of PTEs and show accumulative trends measured in time. Mapping PCs identified distinct regions of PTE presence in soil and PTE accumulation in badger tissues in Northern Ireland. PTEs were most elevated in liver, kidney and then muscle tissues. Liver and kidney showed the most distinct geo-spatial patterns of accumulation and muscle was the most depleted. PC1 and 2 for each type were modelled using generalised additive mixed models (GAMM) to identify trends through time. PC1 for the liver and muscle were associated with rainfall and ∂N15 in the liver, showing a link to diet and a bioaccumulation pathway, whilst PC2 for both tissues was associated with mean temperature, showing a link to seasonal activity and a bioaccessibility pathway. However, in kidney tissue these trends are reversed and PC1 was associated with bioaccessibility and PC2 with bioaccumulation. Combined these techniques can elucidate both geo-spatial trends in PTEs and the mechanisms by which they move in environment and in future may be an effective tool for assessing PTE bioavailability in environmental health surveys.The simultaneous assessment of source apportionment and secondary formation processes was comprehensively studied in a suburban area located on the western edge of Japan by combining year-round daily observation using a filter-pack method with model calculations. Secondary formation was the most important pollution source, accounting for ca. 45% (23% (secondary sulfates) + 22% (secondary nitrates)) of the sources of total atmospheric aerosol mass. For the secondary aerosol composition at this suburban site in western Japan, the secondary sulfates were mainly derived from volcanic eruptions (Sakurajima volcano and/or Aso volcano), the oxidation of SO2 from industrial combustion, ship emissions in the Kyushu area, and long-distance transportation from several coastal cities in Eastern China. Multiple regression results further revealed that the secondary sulfate formation process was significantly influenced by and related to HNO3, HCl, and the relative humidity (RH) (p less then 0.01). While the potential pollution source region of secondary nitrates was located in the northwest region of the sampling site, where air masses pass through Mongolia and Northern China, the formation mechanism of secondary nitrates was more complicated, with the important driving factors being Ox, NO2, NH3, HCl, temperature (T), and RH.