333.7 Natürliche Ressourcen, Energie und Umwelt
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Human exposure to endocrine disruptors is well documented by biomonitoring data. However, this information is limited to few chemicals like bisphenol A or phthalate plasticizers. To account for so-far unidentified endocrine disruptors and potential mixture effects we employ bioassays to detect endocrine activity in foodstuff and consequently characterize the integrated exposure to endocrine active compounds. Recently, we reported a broad contamination of commercially available bottled water with estrogenic activity and presented evidence for the plastic packaging being a source of this contamination. In continuation of that work, we here compare different sample preparation methods to extract estrogen-like compounds from bottled water. These data demonstrate that inappropriate extraction methods and sample treatment may lead to false-negative results when testing water extracts in bioassays. Using an optimized sample preparation strategy, we furthermore present data on the estrogenic activity of bottled water from France, Germany, and Italy: eleven of the 18 analyzed water samples (61.1%) induced a significant estrogenic response in a bioassay employing a human carcinoma cell line (MCF7, E-Screen). The relative proliferative effects ranged from 19.8 to 50.2% corresponding to an estrogenic activity of 1.9-12.2 pg estradiol equivalents per liter bottled water. When comparing water of the same spring that is packed in glass or plastic bottles made of polyethylene terephthalate (PET), estrogenic activity is three times higher in water from plastic bottles. These data support the hypothesis that PET packaging materials are a source of estrogen-like compounds. Furthermore, the findings presented here conform to previous studies and indicate that the contamination of bottled water with endocrine disruptors is a transnational phenomenon.
This assessment concept paper provides a methodological approach for the formative assessment and summative assessment of GIZ’s International Water Stewardship Programme (IWaSP) and its component partnerships. IWaSP promotes partnerships between the private sector (corporations and SMEs), the public sector and the society to tackle shared water risks and to manage water equitably to meet competing demands. This evaluative assessment concept describes the generic approach of the assessment, the cycle for the assessment of partnerships, the country coordination and the programme.
The overall goal of the assessment is to provide evidence for taxpayers in the donor countries and for citizens in the partnership countries. It also aims to examine the relevance of the programme’s approach, its underlying assumptions, and the heterogeneity of stakeholders and their specific interests. Since the assessment is also formative feedback to GIZ and IWaSP stakeholders, it aims to guide the future implementation of the partnerships and the programme.
The assessment is guided by several generic principles: assessing for learning (formative assessment); assessment of learning (summative assessment); iteration; structuring complex problems; unblocking results; and conformity with other assessment criteria set out by the OECD the Development Assistance Committee (DAC) and GIZ’s Capacity Works success factors (GTZ 2010).
These generic criteria are adapted to the three levels of the IWaSP structure. First, the assessment cycle for partnerships includes the validation of stakeholders (mapping), the analysis of secondary literature, face-to-face interviews and a process for feeding back the findings. Generic tools are provided to guide the assessment, such as a list of key documents and an interview guide. Partnerships will undergo a baseline, interim assessment and final assessment. As progress varies across individual IWaSP partnerships, the steps taken by each partnership to assess shared water risks, prioritise and agree interventions, are expected to differ slightly. In response to these differences the sequencing and content of the assessment may need to be adapted for the different partnerships.
Second, the country-level assessment considers issues such as the coordination of partnerships within a country, scoping strategies, and interaction between partnership and the programme. Information gathered during the partnership assessment feeds into the country-level assessment.
Third, the assessment cycle for the programme involves a document and monitoring plan analysis, reflection on the different perspectives of the programme staff, country staff and external stakeholders.
The final section is concerned with reporting. Several annexes are provided relating to the organisation and preparation of the assessment, including question guidelines and analysis procedures.
The use of decentralised, sustainable urban drainage systems (SUDS) for the treatment of stormwater runoff is becoming increasingly prevalent in Germany. Decentralised SUDS can offer a viable and attractive alternative to end of pipe treatment systems for stormwater runoff from urban areas. However, there is still some uncertainty regarding the long-term performance of SUDS, and the general legislative requirements for SUDS approval and testing. Whilst the allowable pollution levels in stormwater runoff that infiltrate into ground and/or water table are regulated across Germany by the Federal Soil Protection Law, there is presently no federal law addressing the discharge requirements for surface water runoff. The lack of clear guidance can make it difficult for planners and designers to implement these innovative and sustainable stormwater treatment systems. This study clarifies the current understanding of urban stormwater treatment requirements and new technical approval guidelines for decentralised SUDS devices in Germany. The study findings should assist researchers, designers and asset managers to better anticipate and understand the performance, effective life-spans, and the planning and maintenance requirements for decentralised SUDS systems. This should help promote even greater use of these systems in the future.
This study examines the urban heat island (UHI) of Brussels, for both current (2000–2009) and projected future (2060–2069) climate conditions, by employing very high resolution (250 m) modelling experiments, using the urban boundary layer climate model UrbClim. Meteorological parameters that are related to the intensity of the UHI are identified and it is investigated how these parameters and the magnitude of the UHI evolve for two plausible trajectories for future climate conditions. UHI intensity is found to be strongly correlated to the inversion strength in the lowest 100 m of the atmosphere. The results for the future scenarios indicate that the magnitude of the UHI is expected to decrease slightly due to global warming. This can be attributed to the increased incoming longwave radiation, caused by higher air temperature and humidity values. The presence of the UHI also has a significant impact on the frequency of extreme temperature events in the city area, both in present and future climates, and exacerbates the impact of climate change on the urban population as the amount of heat wave days in the city increases twice as fast as in the rural surroundings.
Transforming the current rather centralized electricity generating system into a climate neutral system based on renewable energy is an important approach to reduce greenhouse gas emissions and thus mitigate climate change. Stakeholders have each of them their own perception of the best strategies to achieve such a transformation. All perspectives are equally legitimate and needed for developing a specific transformation strategy suited for the region in focus....
Science is under pressure. In times when it is a matter of nothing less that a transformation toward sustainable development, society and politics are demanding not just reliable knowledge but above all useful knowledge. In order to be able to produce such knowledge science must change its structures and ways of working. A renewed understanding of critique can provide guidance to the process of change that must be actively shaped by science itself.* The “Great Transformation” in the direction of sustainable development is a global challenge for society (WBGU2011). All involved have stressed that this transformation, if it succeeds, will lead to profound changes in all parts of society (see PIK 2007). This applies to science as well, which after all is a part of society (WBGU2011, pp. 341 f.). For in view of an unprecedented social-ecological crisis science is coming increasingly under pressure to provide knowledge that is not only methodically reliable but also useful for dealing with the challenges ahead. It is obvious this pressure can strike at the very core of the scientific project: Any orientation toward nonscientific criteria with respect to what is to count as relevant knowledge threatens to undermine the reflexive and cooperative search for “true knowledge.”
In this situation we believe it to be crucial that science does not allow itself to become a plaything of calls for change, but rather that it itself shapes its own response to the new historical challenges. In the following, we argue that a renewed understanding of critique should be the starting point for such an endeavor.1 We will illustrate what a renewed understanding of critique might look like by posing nine theses.2 We see these theses as a contribution to the ongoing discourse on sustainability science or research for sustainable development.
The anthropocene – the epoch of humankind – is currently a topic of great interest. What consequences does the idea of humanity as a geological force have for the undertaken path of sustainable development? What new questions are arising for sustainability science? Diagnosing contemporary society from an anthropocene perspective could change the relationship between natural and social sciences, as well as between society and science: science will be needed even more as a critical authority and must be organized to an even greater extent in a transdisciplinary manner. New forms of social participation in the process of producing scientifically legitimated knowledge are indispensable.∗
More than ten years ago the Dutch chemist and Nobel laureate Paul Crutzen coined the term “Anthropocene” to describe the period during which humans have begun to significantly influence biological, geological and atmospheric processes, thus becoming a relevant geological force on planet Earth (Crutzen and Stoermer 2000, Crutzen 2002). In the earth sciences the anthropocene represents nothing less than a transition to a new epoch and is therefore being discussed intensively. Until 2016 data have been collected by geologists from the International Commission on Stratigraphy (ICS) to provide evidence that might help answer the question whether a turning point has been reached in the history of the Earth (Zalasiewicz et al. 2011). A decision will be made as to whether and when a new epoch in Earth history has begun.
The significance and consequences outside the geoscientific discourse of identifying an “epoch of humans” (Zalasiewicz 2013) has, so far, only been understood to a small extent. Yet this change of perspective is one of the most important in the last 100 hundred years, for it means society and nature have become so closely intertwined that they can no longer be studied independently of each other. Natural spheres and societal spheres have merged into one large system (Guillaume 2015, Becker und Jahn 2006). A well-founded acceptance of the concept of the anthropocene, however, has been lacking, especially where transitions to a sustainable development are being researched. It remains unclear whether the concept of the Anthropocene will lead to a new fundamental understanding of the relationships between nature and society and, if so, what opportunities this new understanding might open for shaping these relationships in a more sustainable manner. And lastly, and equally importantly, it is still unclear whether science’s role and responsibilities will change in the course of developing visions of the future. With this article we hope to stimulate further discussions of these issues.
Historically – if one can say that given the infancy of the field – environmental plastic debris has been the baby of marine research. Driven by the rediscovery of long forgotten, 1970s studies on the occurrence of small plastic fragments (today termed microplastics) in the oceans, oceanographers and marine biologists resurrected the topic in the early 2000s. Since then, the field has rapidly expanded and established that plastics are ubiquitous in the marine system, from the Arctic to Antarctic and from the surface to the deep sea. ...
In energy modelling, open data and open source code can help enhance traceability and reproducibility of model exercises which contribute to facilitate controversial debates and improve policy advice. While the availability of open power plant databases increased in recent years, they often differ considerably from each other and their data quality has not been systematically compared to proprietary sources yet. Here, we introduce the python-based ‘powerplantmatching’ (PPM), an open source toolset for cleaning, standardizing and combining multiple power plant databases. We apply it once only with open databases and once with an additional proprietary database in order to discuss and elaborate the issue of data quality, by analysing capacities, countries, fuel types, geographic coordinates and commissioning years for conventional power plants. We find that a derived dataset purely based on open data is not yet on a par with one in which a proprietary database has been added to the matching, even though the statistical values for capacity matched to a large degree with both datasets. When commissioning years are needed for modelling purposes in the final dataset, the proprietary database helps crucially to increase the quality of the derived dataset.
The green building evolution
(2019)
The Green Building Evolution illuminates global examples and makes use of case studies mainly from South Africa. This book is in five parts: Part I is a single introductory chapter centred on the evolution of the green building movement; Part II addresses the green building terrain; Part III presents selected case studies; Part IV focuses on chapters that address pushing the boundaries in the green building space; while Part V presents emerging trends and policy perspectives. Further details are contained in the main body of the book. It is our sincere hope that readers will experience the book as an informative and ground-breaking adventure. Written by 14 authors from different academic disciplines and areas of specialisation, the book comes as the sixth in a series that addresses global and national concerns on climate change, sustainable development and the green economy transition agenda. The book series is conceptualised and coordinated by the Exxaro Chair in Business and Climate Change, led by Prof. Godwell Nhamo and hosted by the Institute for Corporate Citizenship (ICC) at the University of South Africa (UNISA). The books are published by the Human Sciences Research Council (HSRC) through the Africa Institute of South Africa.