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Tree cores were sampled using increment borers. At each site three trees were chosen for coring, with two or three cores taken per tree. Cores were sanded and ring widths measured based on high-resolution images of the sanded cores. Cores were cross-dated and summary statistics used to compare cross-dating accuracy. The dataset contains the resulting dated ring width series. This dataset includes tree ring width data, derived from tree cores, that were sampled from sites across the Rhön Biosphere Reserve (Germany). At each chosen site three trees were cored, with two or three cores taken per cored tree. Data was collected in August 2021.

The promotion of electric vehicles (EVs) is an important measure for dealing with climate change and reducing carbon emissions, which are widely agreed goals worldwide. Being an important operating mode for electric vehicle charging stations in the future, the integrated photovoltaic and energy storage charging station (PES-CS) is receiving a fair amount of attention and discussion. However, how to optimally configure photovoltaic and energy storage capacity to achieve the best economy is essential and a huge challenge to overcome. In this paper, based on the historical data-driven search algorithm, the photovoltaic and energy storage capacity allocation method for PES-CS is proposed, which determines the capacity ratio of photovoltaic and energy storage by analyzing the actual operation data, which is performed while considering the target of maximizing economic benefits. In order to achieve the proposed capacity allocation, the method is as follows: First, the economic benefit model of the charging stations is established, taking the net present value and investment payback period as evaluation indicators; then, by analyzing the operation data of the existing charging station with the target of maximizing economic benefits, the initial configuration capacity is obtained; finally, the capacity configuration is verified through a comprehensive case analysis for the actual operation data. The results show that the capacity configuration obtained through the data analysis features an optimized economic efficiency and photovoltaic utilization. The proposed method can provide a theoretical and practical basis for newly planned or improved large-scale charging stations.

The current energy transition imposes a rapid implementation of energy storage systems with high energy density and eminent regeneration and cycling efficiency. Metal hydrides are potential candidates for generalized energy storage, when coupled with fuel cell units and/or batteries. An overview of ongoing research is reported and discussed in this review work on the light of application as hydrogen and heat storage matrices, as well as thin films for hydrogen optical sensors. These include a selection of single-metal hydrides, Ti-V(Fe) based intermetallics, multi-principal element alloys (high-entropy alloys), and a series of novel synthetically accessible metal borohydrides. Metal hydride materials can be as well of important usefulness for MH-based electrodes with high capacity (e.g. MgH2 ~ 2000 mAh g-1) and solid-state electrolytes displaying high ionic conductivity suitable, respectively, for Li-ion and Li/Mg battery technologies. To boost further research and development directions some characterization techniques dedicated to the study of M-H interactions, their equilibrium reactions, and additional quantification of hydrogen concentration in thin film and bulk hydrides are presented at the end of this manuscript.

Abstract The Organic Rankine Cycle can be applied to convert low temperature heat to electrical power using organic working fluids. Recently, a new generation of working fluids has been introduced with almost no Ozone Depletion Potential and significantly smaller Global Warming Potential, compared to currently used refrigerants. R1233zd-E is a promising low-GWP (global warming potential) alternative to R245fa, a widely used fluid in ORC (Organic Rankine Cycle) systems. This paper analyzes the applicability of the new fluid as drop-in replacement for R245fa in existing systems and compares system parameters such as cycle efficiency and power output. To this end, the influence of the process parameters mass-flow rate, condensation temperature and expander rotational speed is investigated experimentally for both fluids. The test rig used has an electrical heater as a heat source and a scroll compressor as an expander. As a conclusion, R1233zd-E can be used as a substitute for R245fa in existing ORC systems. In addition to the advantage of having a much smaller GWP, the use of R1233zd-E may lead to higher thermal efficiencies. Comparing the highest achieved thermal efficiency, R1233zd-E performs 6.92% better than R245fa. However, comparing the maximal gross power output, R245fa performs 12.17% better than R1233zd-E.

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.

We summarize and critically evaluate the available data on nuclear fusion cross sections important to energy generation in the Sun and other hydrogen-burning stars and to solar neutrino production. Recommended values and uncertainties are provided for key cross sections, and a recommended spectrum is given for 8B solar neutrinos. We also discuss opportunities for further increasing the precision of key rates, including new facilities, new experimental techniques, and improvements in theory. This review, which summarizes the conclusions of a workshop held at the Institute for Nuclear Theory, Seattle, in January 2009, is intended as a 10-year update and supplement to Reviews of Modern Physics 70 (1998) 1265. 54 pages, 20 figures, version to be published in Reviews of Modern Physics; various typos corrected and several updates made

Climate warming may threaten the germination strategies of many plants that are uniquely adapted to today’s climate. For instance, species that employ physical dormancy (PY) – the production of seeds that are impermeable to water until high temperatures break them, consequently synchronizing germination with favorable growing conditions – may find that their seeds germinate during unfavorable or potentially fatal periods if threshold temperatures are reached earlier in the year. To explore this, we subjected the seeds of five species with physical dormancy (from the genera Abrus, Bauhinia, Cassia, Albizia, and Acacia) to “mild” (+2°C) and “extreme” (+4°C) future warming scenarios and documented their germination over 2 years relative to a control treatment. Under current climatic conditions, a proportion of seeds from all five species remained dormant in the soil for 2 years. A mild warming of 2°C had little to no effect on the germination of four of the five study species. Contrastingly, an extreme warming of 4°C dramatically increased germination in all five species within the first year, indicating a reduction in their ability to persist in the soil long-term. Cassia fistula was particularly susceptible to warming, exhibiting a similar increase in germination under both mild and extreme warming relative to control. Our findings suggest that climate warming in the tropics may cause the seeds of species that rely on physical dormancy to stagger the risk of unsuccessful germination across years to leave soil seed banks prematurely – the long-term implications of which remain unknown.