Teil I: Das Osnabrücker Umweltmanagement-Modell für Hochschulen

Through their use of energy and materials, universities cause a great deal of environmental pollution which could be reduced considerably by an effective choice of organizational and technical measures. There are some examples for environmental protection measures at several universities, but a professional environmental management system (EMS) for universities with a systematic approach to reduce the consumption of resources is lacking. At the University of Osnabrück, the basis for an EMS applicable for a university has been developed for the first time in Germany and the use of this system can also be transferred to other universities. The EMS is composed of ten building blocks, for example, alteration of the administration’s organizational structure, adoption of environmental guidelines, analysis of the energy and material flows which result in an eco-balance, an environmental program or measures to inform the staff and to help to involve them in environmental management. Over the next months, these ten building blocks will gradually be implemented at the University of Osnabrück. Five articles will provide an overview about the EMS developed for the University of Osnabrück as a whole and will describe parts of the material and energy flow analysis, and the planned environmental information system.

Part I: An Environmental Management Model for Universities: From Environmental Guidelines to the Involvement of Employees

Part II: The Energy Balance of the University of Osnabrück: Analysis of the Energy Flows and Conclusions

Part III: The Traffic Balance of the University of Osnabrück: Calculation of the Environmental Pollution which is caused by the University’s Commuters and Business Trips

Part IV: A Concept of Waste Reduction for the University of Osnabrück: Constructing the Waste Balance and Measures to Inform and Involve the Staff

Part V: The Planned Environmental Information System of the University of Osnabrück: Concept and Integration into the Management Information System

     

Teil II: Lösungsansätze für den landwirtschaftlichen Betrieb bei der Implementierung eines Umweltmanagementsystems

The registration of the present situation regarding environmental investigation is the basis for efficiently proceeding in the course of the implementation of environmental management systems (EMS). The basic analysis is found on the individual elements: reaction audit, management audit and compliance audit. Via an optimal performance of an environmental investigation while implementing an EMS, the basis for a maximum utilization has been created for the user as well for agriculture. Utilization for the company is provided by documentation of the organizational structure showing a transparency of procedures with regard to efficiency. Furthermore, an EMS is useful in the course of external tasks, e.g. public approach, business partners, position to authorities, deregulation or minimization of liability.     

Umweltindikatoren für Immissionswirkungen

“In contrast to other fields of politics, a few, minor measurements (indicators) are still lacking in the environmental policies which enable one to evaluate the environmental situation and to consequently take over a major role in political discussions” (BMU 1998). There are a multitude of suggestions for such environmental indicators on both a national and an international level. To date, however, there are still no indicators through which the ecological effects of biosphere pollution can be evaluated. This work provides two examples how biomonitoring data can be connected to environmental indicators. Based on the background concentrations of a multitude of heavy metals and dioxins/furans in two individual bioindicators (standardized grass and kale cultures), which have been combined to act as indicators for the topic in question, indices have been calculated through the determination of reference values. The results are indicators for the pollution effects of traffic-related emissions, the pollution effects from the emissions of fossil fuels and the pollution effects of dioxins and furanes. These indicators may still be combined further through the methods of calculation which are described. The further, methodical development of bioindicators, however, turned out to be problematic. Only data whose survey methods have been standardized to such an extent that the results are comparable with each other over longer periods of time can be combined to represent indicators: an inalienable requirement for the presentation of trends.     

Teil II: Die Energiebilanz der Universität Osnabrück

One central aspect of the environmental management system for universities developed in Osnabrück is the environmental audit of universities as realized by an ecobalance. This article deals with modelling of the material and energy flows caused by the energy supply of the University in Osnabrück using the software Umberto^®. The result is the university’s energy balance. 37% of the primary energy gets lost in the pre-processes of energy production, mainly during electricity generation. The final energy consumption of the university can be split into 37% electricity and 63% heat, whereas the relation of CO₂ emissions is almost the opposite. Related to this area, the electricity consumption in the different buildings is partially above that seen in similar university buildings in Germany, but below that of all the other values observed for universities located in Lower Saxony. Both the electricity and heat consumption, and therefore also the climate-damaging emissions of CO₂, have increased over the past years. Without further measures the university will not be able to achieve the CO₂-reduction target of the federal government. Recommended are the increased use of district heating power stations to produce the university’s own electricity with lower emissions and energy saving measures, especially in the field of electricity which is responsible for high CO₂-emissions.     

Treibhausgas-Emissionen zukünftiger Erdgas-Bereitstellung für Deutschland

Background

Natural gas makes a significant contribution to the current energy supply and its importance, in relation to both the German and worldwide energy supplies, will increase further in decades to come. In addition to its high degree of efficiency, the low level of direct GHG combustion emissions is also an advantageous factor. However, around 90% of natural gas is methane (CH₄), which is the second most significant GHG due to its high greenhouse potential (21 times higher than CO₂). Therefore, high levels of direct gas losses of natural gas in its production, processing, transport and distribution could neutralise its low emission advantages. This is particularly apparent when considering the growing distances between production and use, the demanding production processes and the upcoming worldwide market for LNG (liquefied natural gas).

Aim

This paper aims to analyse and illustrate the future GHG emissions of the whole process chain of natural gas (indirect emissions) to be supplied to the German border over the next 2 decades. This should allow the comparison of total GHG emissions (indirect and direct) of natural gas with the GHG emissions of other fossil fuels. By considering likely changes in gas origin as well as dynamic changes in the infrastructure and technology of gas production, processing and transport until 2030, all relevant factors are included. The study focuses on the emissions of Russian natural gas as Russia is already, and will be in the future, the most important gas supplier to the German and European gas markets.

Results and Discussion

The analysis illustrates a significant change in the gas supply over the next two decades. The EU Gas Fields are in decline and it is predicted that these will run dry. In parallel the share of Russian and Norwegian natural gas, and also the levels of LNG production (e.g. from Algeria or Egypt), will increase. Although the potential for GHG emissions tends to grow as a result of greater transport distances and demanding production and processing activities, high investment in necessary mitigation options (e.g. through replacing older and inefficient technology; updating to state-of-the-art technology) may neutralise the increase. The overall result of these counteracting trends will be to decrease GHG emissions, in a range of around 12% per TJ of direct emissions of natural gas, depending on the level of investment in the modernisation of the Russian gas infrastructure and the improvements of the LNG process. In the two given scenarios the indirect emissions of the natural gas used in Germany will decrease from about 23 million t CO₂-eq (2005) to 19.5 or 17.6 million t CO₂-eq in the year 2030. In spite of a significant higher gas consumption the emissions are reduced in the first scenario due to technical modifications. In the second scenario the emission reduction is based on the lower gas consumption.

Conclusions

At present, the indirect GHG emissions of the natural gas process chain are comparable to the indirect emissions produced by oil and coal. The emission trend of the natural gas process chain will markedly decrease if the mitigation options are followed consistently. However, in order to ensure the long-term security of natural gas supply for future decades, a high level of investment is essential. With regard to future emissions, the best available technology and, therefore, that which is most economically feasible in the long term, should be used. Under these conditions natural gas — as the fossil fuel with the lowest levels of GHG emissions — can play a major role in the transition to a renewable energy supply for the future.     

Neue horizonte für die chemie

The term ‘sustainable development’ is defined and discussed with regard to its significance and its application in the field of chemistry. This is presented using the synthetic organic chemistry as an example. A review of the history of chemistry indicates clearly the necessity for further developments in the course of concepts involving sustainability. Following the eras of bituminous coal tar and mineral oil in both of the two past centuries, a search for new raw materials and a reduction in the global ecotoxicological potential for danger is being strived for. Critical contemplations are mandatory in order to avoid making this term ‘persistence’ into a keyword. Consequently, one must take into consideration the field of research and development as well as reflecting about the classification of chemical and scientific research projects, and their political as well as social relationships. Aside from the new methods of synthesis, this will also require the formulation of other decision-relevant criteria.     

Aquatische Mesokosmosversuche im Zulassungsverfahren für Pflanzenschutzmittel

This article deals with the question of how to consider data from aquatic mesocosm tests in the registration procedure of plant protection products. The legal framework is presented. This type of test must fulfill special methodological requirements in order to become a valuable tool for risk assessment. If this is the case, the data from mesocosm studies is more important than that from laboratory tests. Such studies must only be submitted if the risk assessment on the basis of standard laboratory tests indicate a risk for aquatic organisms.     

Dynamisiertes Emissionskataster für den Freistaat Sachsen

A computer aided tool was created for the calculation of emission values in Saxony. It is based on the Geographic Information System ArcInfo and enables the emission values for past, present and future periods to be assessed. At present, the anthropogenic air pollutants SO₂, NO_x, CO, NH₃, NMVOC, TSP, CO₂, CH₄ and N₂O can be calculated by means of emission factors and statistical values. The tool is open to future expansions. The moduls represent the following emission groups: Power stations, large agricultural farms and large industrial plants as point sources, as well as transport, households, small consumer and the total emission of agriculture as area sources. The local resolution of emission values, the relationship of emission values to geographic or political territories, the inclusion of a high resolved digital street network, and the use of actual data concerning land use, density of population and density of build up areas are realized by GIS ArcInfo. The dynamic emission inventory can be used, alone or in conjunction with an atmospheric dispersion model, to assess trends in air quality.     

Entwicklung von Prüfwertempfehlungen für ausgewählte Schadstoffe zum Schutz des Bodens als Lebensraum für Bodenorganismen

Goal and Scope

In the German Federal Soil Protection and Contaminated Sites Ordinance there are no ecotoxicological trigger values for the protection of soil as a habitat for soil organisms. The objective of this study was to derive preliminary trigger values for the habitat function of soils. This was done by collecting data on the impact of priority pollutants on soil organisms and plants followed by the parallel use of the Factorial Application Method (FAME) and Distribution Based Extrapolation (DIBAEX) and a final verification of the plausibility of the calculated trigger values by means of an ecotoxicological test battery.

Methods

Data on the effects of pollutants on soil organisms and plants were recorded in a specific data base (Soil Value). Subsequently, we derived so-called ‘working trigger values’ using the extrapolation methods FAME (factorial application method) and DIBAEX (distribution based extrapolation). In the second phase of the project, we verified experimentally the plausibility of these values by means of an ecotoxicological test battery. Test substrate was a sandy soil with low sorption capacity and organic carbon content which was mixed with fresh pollutants (e.g. heavy metal salts) and polluted soil material from contaminated sites (aged contamination), respectively. Organisms tested were microorganisms, plants, earthworms, springtails and nematodes.

Results and Conclusions

We calculated working trigger values for 12 pollutants based on 900 datasets compiled in he data base. The laboratory investigations showed the freshly added contaminants to be less strongly adsorbed to the soil than those added by the use of contaminated soil material. Nevertheless, aged contaminations displayed often the same inhibitive effects as the freshly added chemicals. The results achieved in the second phase of the project were also recorded in the Soil-Value database. Based on the new data set, final trigger values were derived for the experimentally tested substances.

Outlook

The procedure described in this contribution exemplarily for copper can be used for the derivation of recommended trigger values for the pathway soil ? soil organisms. Besides copper, preliminary trigger values were derived for zinc, mercury, lead and HCH.