Your search keyword '"Anthroposphere"' showing total 7 results

1. Glyphosate impairs aversive learning in bumblebees.

Author

Nouvian, Morgane, Foster, James J., and Weidenmüller, Anja

Published

2023

2. Ecology: Science or philately? An interdisciplinary analysis of sustainability by exploring if it is possible to get more and more information by reducing collateral environmental damages.

Author

Rodríguez, Ricardo A., Riera, Rodrigo, and Delgado, Juan D.

Subjects

*SUSTAINABILITY, *ENVIRONMENTAL impact analysis, *SUSTAINABLE development, *BIOSPHERE, *MAXWELL'S demon

Abstract

We herein explore the connections between the current condition of ecology concerning to sustainable development and the statement of Rutherford regarding the importance of physics to understand sustainability and biological conservation. The recent emergence of organic biophysics of ecosystems (OBEC) may constitute a feasible alternative to fill the gap between conventional ecological thinking and physics, especially thermodynamics. However, our comprehension of sustainability and biological conservation is influenced by the interactions between information and entropy, because we tend to exclude parts of the biosphere as well as their relationships among them. We explore the use of a holistic analysis of sustainability and biological conservation using physics, and also establish a parallelism between Maxwell's demons and human beings. Lastly, the ecological meaning of the hypothetical feasibility of Maxwell's demon at the anthroposphere scale is analyzed starting from the objections of von Smoluchowski, Szilard and Bennet. [ABSTRACT FROM AUTHOR]

Published

2017

3. (Climate) Change in young people's minds – From categories towards interconnections between the anthroposphere and natural sphere.

Author

Körfgen, Annemarie, Keller, Lars, Kuthe, Alina, Oberrauch, Anna, and Stötter, Hans

Subjects

*CLIMATE change, *EARTH sciences, *YOUNG adult psychology, *SUSTAINABLE development, *CLIMATE change education, *ETHICS

Abstract

The grand challenges of the 21st century will increasingly require societies to reconsider the pathways taken thus far. Engagement with climate change is of ever-growing importance to young people. They will be confronted with the effects of climate change throughout their entire lives and, as future decision-makers, they will vitally shape societal developments. Education will thus play a crucial role in the transformation to a sustainable society. In terms of awareness-raising, an important first step in preparing young people for the challenges of the 21st century is to understand what content is connected with climate change. As complex challenges, such as climate change, demand ways of thinking that go beyond categories, interconnections between the anthroposphere and the natural sphere have to be taken into consideration. This study provides an insight into the questions and topics young people develop whilst becoming involved in climate change in an in-school learning setting and in an out-of-school learning setting (a high mountain environment). The analysis focuses on the question of in which spheres students predominantly make their thematic choices and how far the interconnections between different spheres are formed. Our results show that the choice of the learning setting influences the topics students connect with climate change. Interconnections between sub-spheres of the anthroposphere and natural sphere are made only occasionally. These findings serve as a basis for reconsidering the content and foundation of climate change communication with young people. We recommend that climate change educational programmes should include phases that allow the following: a) involvement with climate change issues related to single spheres in the first phase, and b) consideration of the interconnections between spheres when becoming involved with climate change issues in the second phase. As the educational setting can considerably influence the focus of the learning process, it should be chosen thoughtfully. [ABSTRACT FROM AUTHOR]

Published

2017

4. Tracking chemicals in products around the world: introduction of a dynamic substance flow analysis model and application to PCBs.

Author

Li, Li and Wania, Frank

Subjects

*ENVIRONMENTAL impact analysis, *WASTE management, *SENSITIVITY analysis, *POLYCHLORINATED biphenyls, *INDUSTRIAL chemistry

Abstract

Dynamically tracking flows and stocks of problematic chemicals in products (CiPs) in the global anthroposphere is essential to understanding their environmental fates and risks. The complex behavior of CiPs during production, use and waste disposal makes this a challenging task. Here we introduce and describe a dynamic substance flow model, named Chemicals in Products - Comprehensive Anthropospheric Fate Estimation (CiP-CAFE), which facilitates the quantification of time-variant flows and stocks of CiPs within and between seven interconnected world regions and the generation of global scale emission estimates. We applied CiP-CAFE to polychlorinated biphenyls (PCBs), first to evaluate its ability to reproduce previously reported global-scale atmospheric emission inventories and second to illustrate its potential applications and merits. CiP-CAFE quantifies the pathways of PCBs during production, use and waste disposal stages, thereby deducing the temporal evolution of in-use and waste stocks and identifying their long-term final sinks. Time-variant estimates of PCB emissions into air, water and soil can be attributed to different processes and be fed directly into a global fate and transport model. By capturing the international movement of PCBs as technical chemicals, and in products and waste, CiP-CAFE reveals that the extent of global dispersal caused by humans is larger than that occurring in the natural environment. Sensitivity analysis indicates that the model output is most sensitive to the PCB production volume and the lifetime of PCB-containing products, suggesting that a shortening of that lifetime is key to reducing future PCB emissions. [ABSTRACT FROM AUTHOR]

Published

2016

5. Thermodynamic analysis of human–environment systems: A review focused on industrial ecology

Author

Liao, Wenjie, Heijungs, Reinout, and Huppes, Gjalt

Subjects

*THERMODYNAMICS research, *HUMAN ecology, *ECOLOGY methodology, *INDUSTRIAL ecology, *SUSTAINABILITY, *EFFECT of human beings on climate change

Abstract

The term Anthropocene, which is used by many scientists to refer to the current era, reflects various environmental issues caused by anthropogenic activities. The energy flows and conversions in the anthroposphere and the anthropogenic impacts on the ecosphere, as two major aspects of the physical part of industrial ecology, are both subject to the laws of thermodynamics. After an introduction to human–environment systems and industrial ecology in the Anthropocene, this review focuses on the role and applications of thermodynamic analysis in industrial ecology based on a thermodynamic definition of human–environment systems at four levels, i.e., the ecosphere (A), the anthroposphere (B), the supply chain (C), and the foreground system (D). It argues that process engineering thermodynamics (at level D) and ecological energetics (at level A) are the most mature applications, and the primary benefit added by thermodynamic analysis to industrial ecology lies in the physical validation and quantitative formulation of thermodynamics. The review also indicates the challenges of using thermodynamic analysis to understand the physical complexity of industrial ecology and to guide sustainability decision-making call for a joint effort by thermodynamic analysis and ecosystems ecology and for more insights from social sciences. [Copyright &y& Elsevier]

Published

2012

6. Natural resource demand of global biofuels in the Anthropocene: A review

Author

Liao, Wenjie, Heijungs, Reinout, and Huppes, Gjalt

Subjects

*NATURAL resources management, *BIOMASS energy, *HOLOCENE Epoch, *ECONOMIC demand, *ENERGY budget (Geophysics), *FACTORS of production

Abstract

Abstract: The Anthropocene is the later part of the Holocene where human activity has become a major driver for global ecosystem development. The demand of natural resources, renewable and non-renewable, is a crucial aspect of environmental (un-) sustainability. When considering a societal transition scheme towards sustainability, bio-based options come to the fore. The article develops a global framework for the analysis of natural resource demand of global biofuels. The framework defines the biofuel system in terms of exergy at four levels, i.e., the foreground system, the supply chain, the anthroposphere, and the ecosphere. Various measures of resource demand, such as cumulative exergy demand, global and anthropogenic exergy budgets are incorporated into the framework. Based on reviews of global biofuel production and natural resource demand of the anthroposphere, the study finds that the production of conventional biofuels, i.e., first generation of biodiesel and bioethanol by key producer countries in 2008 consumed 9.32E+11MJ of exergy from non-renewable resources and accounted for 0.23% of the total anthropogenic non-renewable resource demand. In addition, it shows that the contribution to climate change due to the heat emission of the global biofuel production was 5.79E−05W/m2, which would reach up to 0.002% of global greenhouse warming if anthropogenic heat flux is treated as a climate forcing. [Copyright &y& Elsevier]

Published

2012

7. Legacy iron and steel wastes in the UK: Extent, resource potential, and management futures.

Author

Riley, Alex L., MacDonald, John M., Burke, Ian T., Renforth, Phil, Jarvis, Adam P., Hudson-Edwards, Karen A., McKie, Jessica, and Mayes, William M.

Subjects

*STEEL wastes, *WASTE recycling, *ATMOSPHERIC nitrogen, *BASIC oxygen furnaces, *IRON, *STEELWORK, *IRON alloys

Abstract

The iron and steel industry has a long tradition of bulk reuse of slags for a range of construction applications. Growing interest in recent years has seen slag resource recovery options extend to critical raw material recovery and atmospheric carbon capture. Full scale deployment of such technologies is currently limited in part by absent or partial inventories of slag deposit locations, data on composition, and volume estimates in many jurisdictions. This paper integrates a range of spatial information to compile a database of iron and steel slag deposits in mainland United Kingdom (UK) for the first time and evaluate the associated resource potential. Over 190 million tonnes of legacy iron and steel slag are present across current and former iron and steel working regions of the UK, with particular concentrations in the north west and north east of England, and central Scotland. While significant potential stockpiles of blast furnace and basic oxygen furnace slag could provide up to 0.9 million tonnes of vanadium and a cumulative carbon dioxide capture potential of 57–138 million tonnes, major management challenges for resource recovery are apparent. Over one third are located in close proximity to designated conservation areas which may limit resource recovery. Furthermore, land use analyses show that many of the sites have already been redeveloped for housing (nearly 30% urban cover). Deposits from recent decades in current or recently closed steel-working areas may have the greatest potential for resource recovery where such ambitions could be coupled with site restoration and regeneration efforts. Unlabelled Image • Iron and steel-making slags have considerable resource recovery potential. • The extent of legacy iron and steel slag deposits was previously not well quantified. • A national database of slag deposits was created and analysed for mainland UK sites. • Carbon capture potential and critical raw materials (CRM) recovery potential estimated. • Current land use and conservation designations may limit resource recovery viability. [ABSTRACT FROM AUTHOR]

Published

2020