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AbstractNowadays, researchers are focusing on the methods of using recycled industrial/agricultural wastes as raw materials, which are not only economically but also environmentally useful. In the recent years, many scholars have conducted research on the rational use of rice husks (RHs) and found that RHs are rich in inorganic/organic components and used in combination with the certain building materials to produce new green composite building materials. This paper studies the method of using RH processed products and the sodium silicate solution (liquid glass) made from RH ash to produce cheap wood substitute composite materials, which can be improved the insulation performance of the wall greatly. Obtained results are determined by comparing with the properties of standard polymer composite materials such as particleboards, chipboards, and medium‐density fiberboards (MDF). The significance of the work is pointing out by solving the problem of recycling large‐tonnage agricultural waste and reproduce products with the consumer's value.

Abstract This study presents and evaluates the feasibility of a novel hybridization of modified Kalina cycle, reverse osmosis desalination, and low-temperature water electrolysis utilizing geothermal energy to yield power, distilled water, and hydrogen, respectively. The scientific impact of the current work has been improved considering the features of Sabalan flash-binary geothermal wells in Iran as a real model through a case study. In addition to designing a novel setup, the smart use of multi-heat recovery technique, modifying the base cycle, and utilizing a part of generated distilled water to produce hydrogen by the electrolyzer are the other structural originalities, distinguishing the current work from the previous studies. The suggested system is scrutinized via a parametric study and optimized based on a genetic algorithm. The parametric study demonstrated that the highest sensitivity of varying the performance criteria of the whole system is attributed to the change in flash tank pressure. Moreover, the multi-objective optimization led to achieving the exergy efficiency and trigeneration gain output ratio as 51.3% and 1.7 for the system, respectively. Furthermore, the system was able to produce 4795 kW of power, 5.3 kg/h of hydrogen, and 19.9 kg/s of distilled water.

The assessment of greenhouse gases (GHGs) and air pollutants emitted to and removed from the atmosphere ranks high on international political and scientific agendas. Growing international concern and cooperation regarding the climate change problem have increased the need to consider the uncertainty in inventories of GHG emissions. The approaches to address uncertainty discussed in this special issue reflect attempts to improve national inventories, not only for their own sake but also from a wider, system analytic perspective. They seek to strengthen the usefulness of national emission inventories under a compliance and/or global monitoring and reporting framework. The papers in this special issue demonstrate the benefits of including inventory uncertainty in policy analyses. The issues raised by the authors and featured in their papers, along with the role that uncertainty analysis plays in many of their arguments, highlight the challenges and the importance of dealing with uncertainty. While the Intergovernmental Panel on Climate Change (IPCC) clearly stresses the value of conducting uncertainty analyses and offers guidance on executing them, the arguments made here in favor of performing these studies go well beyond any suggestions made by the IPCC to date. Improving and conducting uncertainty analyses are needed to develop a clear understanding and informed policy. Uncertainty matters and is key to many issues related to inventorying and reducing emissions. Considering uncertainty helps to avoid situations that can create a false sense of certainty or lead to invalid views of subsystems. Dealing proactively with uncertainty allows for the generation of useful knowledge that the international community should have to hand while strengthening the 2015 Paris Agreement, which had been agreed at the 21st Conference of the Parties to the United Nations Framework Convention on Climate Change (UNFCCC). However, considering uncertainty does not come free. Proper treatment of uncertainty is demanding because it forces us to take the step from “simple to complex” and to grasp a holistic system view. Only, thereafter, can we consider potential simplifications. That is, comprehensive treatment of uncertainty does not necessarily offer quick or easy solutions for policymakers. This special issue brings together 13 papers that resulted from the 2015 (4th) International Workshop on Uncertainty in Atmospheric Emissions, in Cracow, Poland. While they deal with many different aspects of the uncertainty in emission estimates, they are guided by the same principal question: “What GHGs shall be verified at what spatio-temporal scale to support conducive legislation at local and national scales, while ensuring effective governance at the global scale?” This question is at the heart of mitigation and adaptation. It requires an understanding of the entire system of GHG sources and sinks, their spatial characteristics and the temporal scales at which they react and interact, the uncertainty (accuracy and/or precision) with which fluxes can be measured, and last but not least, the consequences that follow from all of the aforementioned aspects, for policy actors to frame compliance and/or global monitoring and reporting agreements. This bigger system context serves as a reference for the papers in the special issue, irrespective of their spatio-temporal focus, and is used as a guide for the reader.

В последние десятилетия экологическая проблема приняла глобальный характер и требует консолидации мирового сообщества. Возникающие экологические угрозы становятся все более опасными для человечества, поэтому требуются усилия всех государств для предотвращения негативных последствий изменения окружающей среды. В данной статье рассматривается деятельность международных акторов в сфере обеспечения экологической безопасности. Авторами проведен сравнительный анализ правовых основ и национальных особенностей политики экологической безопасности Дании, США и России, рассмотрены примеры использования возобновляемых источников энергии, направленных на минимизацию экологических рисков, выявлены проблемы и определены перспективы реализации экологической политики в условиях перехода к «зеленой энергетике». In recent decades, the environmental problem has become global in nature and requires the consolidation of the world community. Emerging environmental threats are becoming more and more dangerous for humanity, therefore efforts of all states are required to prevent the negative consequences of environmental change. This article examines the activities of international actors in the field of ensuring environmental safety. The authors conducted a comparative analysis of the legal framework and national characteristics of environmental safety policies in Denmark, the USA and Russia, examined examples of the use of renewable energy sources aimed at minimizing environmental risks, identified problems and identified prospects for the implementation of environmental policy in the context of the transition to “green energy”.

This study examined the potential use of macroalgae epiphytic on mangrove aerial roots as indicators of estuarine contamination. The distribution and abundance of macroalgae was investigated in four estuaries in the vicinity of Sydney, Australia, and compared to water and sediment metal concentrations, nutrient concentrations and physicochemical parameters over four seasonal surveys. Macroalgal diversity and distribution appeared to be highly influenced by the ambient contaminant concentrations, while biomass appeared to be linked with nutrient concentrations. The distribution of the Rhodophyta species, Catenella nipae Zanardini significantly decreased as metal concentrations increased among the estuaries during all seasonal surveys. This species showed strong potential for use as a bioindicator of estuarine contamination.

Innovative control method is prosed for the RED WoLF hybrid storage system. The technology is aimed for residential dwellings and allows to reduce the load from the electrical grid during time with high CO emissions. The RED WoLF system consists of a battery, water cylinder, PV array and storage heaters. This technology allows the grid energy to be stored at the “greenest” time, in order to accommodate needs of dwellings with the aid of AI. The original RED WoLF algorithm is considerably improved, following modified progressive threshold approach up to additional 14% savings of CO could be obtained. Intriguingly, savings are only slightly lower than global possible mathematical minimum, for the system barred of predictions errors. However, the computation time of the proposed control method is lower by a few orders of magnitudes, with comparison to standard optimisation techniques. Furthermore, the investigation on 11 months period was performed in order find out if there is significant difference between following a time of use tariff or an environmental signal. Results, suggest that the differences are minor in both cases following any signal improves the used energy quality. Although, the price signal has been affected slightly more to the choice of a target. Finally, the average system composition with 2 kWh battery and 4 kW PV array provides reduction by 55%–60% of both CO emissions and the bill. Such achievement could potentially lead to smooth substitution of carbon intensive residential systems with gas and oil heaters.

Closed-loop supply chain networks are gaining research popularity due to environmental, economic and social concerns. Such networks are primarily designed to overcome carbon footprints and to retrieve end of life products from customers. This study considers a multi echelon closed-loop supply chain in the presence of machine disruption. A multi-objective model is presented to optimize the total cost, the total time and emissions in a closed-loop supply chain network. The aim is to analyze the trade-off between the objectives of cost, time, and emissions and how these decisions are impacted by the selection of different available machines. A number of solution approaches are tested on a case study from the tire industry. The results suggest the improved performance of the hybrid heuristic and the importance of controlling disruption in a closed-loop supply chain network. Furthermore, there is a trade-off between the different objective functions which can help the decision maker to choose a particular solution according to the preference of an organization. Finally, conclusion and future research avenues are provided.

In 16 patients with unifocal thyroid autonomy suffering from hyperthyroidism and in 2 patients and euthyrosis 2-4 ml 96% alcohol was instilled to destroy the autonomous thyroid tissue while permanently monitoring the procedure by means of sonography. 17 of the patients were suffering from struma nodosa. Localization of the focally autonomous adenoma was possible, together with differentiation against concomitant thyroid nodes with normal or reduced function, by coinciding the findings obtained via colour Doppler sonography and scintiscanning. In one female patient local pain occurred during instillation that had to be alleviated by means of analgetics; there were no other noticeable side effects. 12 of 16 patients suffering from hyperthyroidism were euthyrotic 5 weeks after the first alcohol instillation; the thyrostatic dose had to be reduced in 4 patients. B-image sonography showed a reduction in size of the instilled adenomas and echo-poor and partly cystic transformation. Colour Doppler sonography revealed a marked reduction of internal vascularisation with preserved marginal vessels. Scintiscan control no longer visualised the autonomic foci (n = 10) or only with reduced activity (n = 7). Sonographically monitored on-target instillation of alcohol into autonomic thyroid adenoma is an effective, low-risk and low-cost procedure that can also be applied to outpatients by physicians well-versed in colour Doppler sonography and sonographic puncture technique. Colour Doppler sonographic localization of autonomic foci is methodically mandatory in patients suffering from struma multinodosa.

Is it true that a nuclear technology approach to generate electric energy offers a clean, safe, reliable and affordable, i.e., sustainable option? In principle yes, however a technology impact on the environment strongly depends on the actual implementation bearing residual risks due to technical failures, human factors, or natural catastrophes. A full response is thus difficult and can be given first when the wicked multi-disciplinary issues get well formulated and “resolved”. These problems are lying at the interface between: the necessary R&D effort, the industrial deployment and the technology impact in view of the environmental sustainability including the management of produced hazardous waste. As such, this problem is clearly of multi-dimensional nature. This enormous complexity indicates that just a description of the problem might cause a dilemma. The paper proposes a novel holistic approach applying Multi-Criteria Decision Analysis to assess the potential of nuclear energy systems with respect to a sustainable performance. It shows how to establish a multi-level criteria structure tree and examines the trading-off techniques for scoring and ranking of options. The presented framework allows multi-criteria and multi-group treatment. The methodology can be applied to support any pre-decisional process launched in a country to find the best nuclear and/or non-nuclear option according to national preferences and priorities. The approach addresses major aspects of the environmental footprint of nuclear energy systems. As a case study, advanced nuclear fuel cycles are analyzed, which were previously investigated by the Nuclear Energy Agency (NEA/OECD) expert group WASTEMAN. Sustainability facets of waste management, resource utilization and economics are in focus.

Purpose: The aim of this work is the operational electrophysical method of the control for contamination and purification of soil from oil products and the identification of changes in the soil properties in electrochemical processing to determine rational modes of processing.Methods: Investigations are performed on the laboratory setup including the two -electrode scheme of electric treatment of the artificially polluted soil .The setup is equipped with a system of micro sensors of specific electrical resistance. Traditional laboratory tests are used to determine the physical and mechanical properties of soils. The possibility of control for soil purification by electrochemical method using a system of continuous operational geophysical monitoring is considered.Results: Changes in the physical properties of contaminated soils are experimentally confirmed when exposed to the electric current. A physical model is created for coagulation of oil products in pores during the electrical processing. It increases the amount of sand and clay components with changes in the electrical resistance of soil. The physical processes in the clean and polluted soil are compared. It is shown that when electric current passes through contaminated soils, oil products in pores transfer to a solid, less toxic state, which leads to a change in the specific electrical soil resistance throughout the zone processed. This pattern should be used to control soil decontamination.