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Bioplastics are alternatives of conventional petroleum-based plastics. Bioplastics are polymers processed from renewable sources and are biodegradable. This study aims at conducting an environmental impact assessment of the bioprocessing of agricultural wastes into bioplastics compared to petro-plastics using an LCA approach. Bioplastics were produced from potato peels in laboratory. In a biochemical reaction under heating, starch was extracted from peels and glycerin, vinegar and water were added with a range of different ratios, which resulted in producing different samples of bio-based plastics. Nevertheless, the environmental impact of the bioplastics production process was evaluated and compared to petro-plastics. A life cycle analysis of bioplastics produced in laboratory and petro-plastics was conducted. The results are presented in the form of global warming potential, and other environmental impacts including acidification potential, eutrophication potential, freshwater ecotoxicity potential, human toxicity potential, and ozone layer depletion of producing bioplastics are compared to petro-plastics. The results show that the greenhouse gases (GHG) emissions, through the different experiments to produce bioplastics, range between 0.354 and 0.623 kg CO2 eq. per kg bioplastic compared to 2.37 kg CO2 eq. per kg polypropylene as a petro-plastic. The results also showed that there are no significant potential effects for the bioplastics produced from potato peels on different environmental impacts in comparison with poly-β-hydroxybutyric acid and polypropylene. Thus, the bioplastics produced from agricultural wastes can be manufactured in industrial scale to reduce the dependence on petroleum-based plastics. This in turn will mitigate GHG emissions and reduce the negative environmental impacts on climate change.

We provide a dataset from a household survey in Mpanda region in Western Tanzania (N = 137) that was conducted in 2011. Household heads (or replacements) were interviewed. The topics addressed covered a broad range of socio-economic data and including, among others, household information (number of household members, age, sex, religion etc.), agricultural production (e.g. crops produced and livestock owned) including number and size of plots, income generation, energy access and owned assets.

The delta(34)S values of biological material, especially food commodities, serve as indicators for origin assignments. However, in the metabolism of higher plants sulfur isotope fractionations must be expected. As a matter of fact, the delta(34)S values of the sulfate- and organic-S, respectively, of Brassicaceae and Allium species vegetables showed differences between 3 and 6 per thousand, and differences in glucosinolates were between 0 and 14 per thousand. delta(34)S-value differences of total-S between individual tissues of the same plant were approximately 3 per thousand. It is believed that these relatively small and variable fractionations are due to the partition of individual S-metabolism steps to different plant compartments, where they may occur independently and quantitatively. The delta(34)S values of herbivore muscle meat and milk relative to the diet and between an animal and its child had trophic shifts of approximately 1.5 per thousand. (34)S enrichments of up to 4 per thousand were observed for hair, hooves, and horn, an isotope fractionation of -5 per thousand between the diet sulfate and cartilage. Therefore, the reported agreements between delta(34)S value of biomass and primary S sources are true for only bulk material and not for individual compounds or tissues.

Background. Laws that enable a circular economy (CE) are being enacted globally, but reliable standardized and digitized CE data about products is scarce, and many CE platforms have differing exclusive formats. In response to these challenges, the Ministry of The Economy of Luxembourg launched the Circularity Dataset Standardization Initiative to develop a globalized open-source industry standard to allow the exchange of standardized data throughout the supply cycle, based on these objectives: (a) Provide basic product circularity data about products. (b) Improve circularity data sharing efficiency. (c) Encourage improved product circularity performance. A policy objective was to have the International Organization for Standardization (ISO) voted to create a working group. Methods. A state-of-play analysis was performed concurrently with consultations with industry, auditors, data experts, and data aggregation platforms. Results. Problem statements were generated. Based on those, a solution called Product Circularity Data Sheet (PCDS) was formulated. A proof of concept (POC) template and guidance were developed and piloted with manufacturers and platforms, thus fulfilling objective (a). For objective (b), IT ecosystem requirements were developed, and aspects are being piloted in third party aggregation platforms. Objective (c) awaits implementation of the IT ecosystem. The policy objective related to the ISO was met. Conclusions and future research. In order to fully test the PCDS, it is necessary to: conduct more pilots, define governance, and establish auditing and authentication procedures.

Los nuevos sistemas inteligentes para ayudar a la transición energética y mejorar la sostenibilidad y la vida de las personas se pueden implementar a diferentes escalas, desde una casa hasta una región entera. Los campus universitarios son un tamaño intermedio interesante (lo suficientemente grande como para importar y lo suficientemente pequeño como para ser manejable) para la investigación, el desarrollo, las pruebas y la capacitación sobre la integración de la inteligencia en todos los niveles, lo que llevó a la aparición del concepto de "campus inteligente" en los últimos años. Este artículo de revisión propone un amplio análisis de la literatura científica sobre campus inteligentes de la última década (2010-2020). Las 182 publicaciones seleccionadas se distribuyen en siete categorías de inteligencia: edificio inteligente, entorno inteligente, movilidad inteligente, vida inteligente, personas inteligentes, gobierno inteligente y datos inteligentes. Las principales preguntas y desafíos abiertos con respecto a los campus inteligentes se presentan al final de la revisión y abordan la sostenibilidad y la transición energética, la aceptabilidad y la ética, los modelos de aprendizaje, las políticas de datos abiertos y la interoperabilidad. El presente trabajo se realizó en el marco de la Red de Energía de la Cumbre de Líderes Regionales (RLS-Energy) como parte de sus esfuerzos de investigación multilateral sobre regiones inteligentes. De nouveaux systèmes intelligents pour aider à la transition énergétique et améliorer la durabilité et la vie des gens peuvent être déployés à différentes échelles, allant d'une maison à une région entière. Les campus universitaires sont une taille intermédiaire intéressante (assez grande pour compter et assez petite pour être maniable) pour la recherche, le développement, les tests et la formation sur l'intégration de l'intelligence à tous les niveaux, ce qui a conduit à l'émergence du concept de « campus intelligent » au cours des dernières années. Cet article de synthèse propose une analyse approfondie de la littérature scientifique sur les campus intelligents de la dernière décennie (2010-2020). Les 182 publications sélectionnées sont réparties en sept catégories d'intelligence : smart building, smart environment, smart mobility, smart living, smart people, smart governance et smart data. Les principales questions et défis ouverts concernant les campus intelligents sont présentés à la fin de l'examen et traitent de la durabilité et de la transition énergétique, de l'acceptabilité et de l'éthique, des modèles d'apprentissage, des politiques de données ouvertes et de l'interopérabilité. Le présent travail a été réalisé dans le cadre du Réseau de l'énergie du Sommet des dirigeants régionaux (RLS-Energy) dans le cadre de ses efforts multilatéraux de recherche sur les régions intelligentes. Novel intelligent systems to assist the energy transition and improve sustainability and people's life can be deployed at different scales, ranging from a house to an entire region. University campuses are an interesting intermediate size (big enough to matter and small enough to be tractable) for research, development, test and training on the integration of smartness at all levels, which led to the emergence of the concept of "smart campus" over the last few years. This review article proposes an extensive analysis of the scientific literature on smart campuses from the last decade (2010-2020). The 182 selected publications are distributed into seven categories of smartness: smart building, smart environment, smart mobility, smart living, smart people, smart governance and smart data. The main open questions and challenges regarding smart campuses are presented at the end of the review and deal with sustainability and energy transition, acceptability and ethics, learning models, open data policies and interoperability. The present work was carried out within the framework of the Energy Network of the Regional Leaders Summit (RLS-Energy) as part of its multilateral research efforts on smart regions. يمكن نشر أنظمة ذكية جديدة للمساعدة في انتقال الطاقة وتحسين الاستدامة وحياة الناس على مستويات مختلفة، تتراوح من منزل إلى منطقة بأكملها. تعتبر الجامعات ذات حجم متوسط مثير للاهتمام (كبيرة بما يكفي لتكون مهمة وصغيرة بما يكفي لتكون قابلة للتتبع) للبحث والتطوير والاختبار والتدريب على تكامل الذكاء على جميع المستويات، مما أدى إلى ظهور مفهوم "الحرم الجامعي الذكي" على مدى السنوات القليلة الماضية. تقترح مقالة المراجعة هذه تحليلاً شاملاً للأدبيات العلمية حول الجامعات الذكية من العقد الماضي (2010-2020). يتم توزيع المنشورات الـ 182 المختارة على سبع فئات من الذكاء: البناء الذكي، والبيئة الذكية، والتنقل الذكي، والمعيشة الذكية، والأشخاص الأذكياء، والحوكمة الذكية، والبيانات الذكية. يتم تقديم الأسئلة والتحديات الرئيسية المفتوحة المتعلقة بالحرم الجامعي الذكي في نهاية المراجعة والتعامل مع الاستدامة وانتقال الطاقة والقبول والأخلاقيات ونماذج التعلم وسياسات البيانات المفتوحة وقابلية التشغيل البيني. تم تنفيذ العمل الحالي في إطار شبكة الطاقة التابعة لقمة القادة الإقليميين (RLS - Energy) كجزء من جهودها البحثية متعددة الأطراف حول المناطق الذكية.

Abstract Biofuels and the oleochemical industry are highly dependent on plant oils for the generation of renewable product lines. Consequently, production of plant lipids, such as palm and rapeseed oil, for industrial applications competes with agricultural activity and is associated with a negative environmental impact. Additionally, established chemical routes for upgrading bio-lipids to renewable products depend on metal-containing catalysts. Metal leaching during oil processing results in heavy metal contaminated process wastewater. This water is difficult to remediate and leads to the loss of precious metals. Therefore, the biofuels and chemical industry requires sustainable solutions for production and upgrading of bio-lipids. With regard to the former, a promising approach is the fermentative conversion of abundant, low-value biomass into microbial, particularly yeast-based lipids. This study describes the holistic, value-adding conversion of underexploited, macroalgae feedstocks into yeast oil, animal feed and biosorbents for metal-based detoxification of process wastewater. The initial step comprises a selective enzymatic liquefaction step that yields a supernatant containing 62.5% and 59.3% (w/dwbiomass) fermentable sugars from L. digitata and U. lactuca, respectively. By dispensing with chemical pretreatment constraints, we achieved a 95% (w/w) glucose recovery. Therefore, the supernatant was qualified as a cultivation media without any detoxification step or nutrition addition. Additionally, the hydrolysis step provided 27–33% (w/dwbiomass) of a solid residue, which was qualified as a metal biosorbent. Cultivation of the oleaginous yeast C. oleaginosus on the unprocessed hydrolysis supernatant provided 44.8 g L−1 yeast biomass containing 37.1% (w/dwbiomass) lipids. The remaining yeast biomass after lipid extraction is targeted as a performance animal feed additive. Selectivity and capacity of solid macroalgae residues as biosorbents were assessed for removal and recycling of rare and heavy metals, such as Ce+3, Pb+2, Cu+2 and Ni+2 from model wastewater. The biosorption capacity of the macroalgae residues (sorption capacity ∼ 0.7 mmol g−1) exceeds that of relevant commercially available adsorption resins and biosorbents. To facilitate the integration of our technology in existing chemical and biotechnological production environments, we have devised simple, rapid and cost-efficient methods for monitoring both lipogenesis and metal sorption processes. The application of the new optical monitoring tools is essential to determine yeast cell harvesting times and biosorption capacities respectively. For the first time we report on a waste-free bioprocess that combines sustainable, microbial lipid production from low value marine biomass with in-process precious metal recycling options. Our data allowed for a preliminary economic analysis, which indicated that each product could be cost competitive with current market equivalents. Hence, the synaptic nature of the technology platform provides for the economic and ecologic viability of the overall process chain.

AbstractConversion of semi-natural habitats, such as field margins, fallows, hedgerows, grassland, woodlots and forests, to agricultural land could increase agricultural production and help meet rising global food demand. Yet, the extent to which such habitat loss would impact biodiversity and wild species is unknown. Here we survey species richness for four taxa (vascular plants, earthworms, spiders, wild bees) and agricultural yield across a range of arable, grassland, mixed, horticulture, permanent crop, for organic and non-organic agricultural land on 169 farms across 10 European regions. We find that semi-natural habitats currently constitute 23% of land area with 49% of species unique to these habitats. We estimate that conversion of semi-natural land that achieves a 10% increase in agricultural production will have the greatest impact on biodiversity in arable systems and the least impact in grassland systems, with organic practices having better species retention than non-organic practices. Our findings will help inform sustainable agricultural development.

Impacts in the form of innovation and commercialization are essential components of publicly funded research projects. PHUSICOS ("According to nature" in Greek), an EU Horizon 2020 program (H2020) Innovation Action project, aims to demonstrate the use of nature-based solutions (NBS) to mitigate hydrometeorological hazards in rural and mountainous areas. The work program is built around key innovation actions, and each Work Package (WP) leader is specifically responsible for nurturing innovation processes, maintaining market focus, and ensuring relevance for the intended recipients of the project results. Key success criteria for PHUSICOS include up-scaling and mainstream implementation of NBS to achieve broader market access. An innovation strategy and supporting tools for implementing this within PHUSICOS has been developed and key concepts forming the basis for this strategy are presented in this research note.