Minderung von Treibhausgas-Emissionen der Landwirtschaft

von Buttlar, Christine, Freitag, Thomas, Rebbe, Falk, Zorn, Stefan

26 March 2015

In dem Bericht werden der Treibhausgas (THG)-Ausstoß der sächsischen Landwirtschaft, die bisher erbrachten Klimaschutzleistungen und die Minderungspotenziale bis zum Jahr 2020 dargestellt. Für den gewählten Bilanzkreis hat die sächsische Landwirtschaft ca. 7,6 % zum THG-Ausstoß in Sachsen beigetragen. Im Vergleich zum Jahr 2000 konnte der THG-Ausstoß um ca. 5 % vermindert werden. Bis zum Jahr 2020 könnte ein THG-Minderungspotenzial von weiteren etwa 5 % erschlossen werden. Die Veröffentlichung richtet sich vorrangig an Fachleute aus der Landwirtschaft, aber auch an die Verbraucher, die ebenfalls einen Beitrag zur Minderung des THG-Ausstoßes leisten können.

air, emission, pollutants, agriculture

info:eu-repo/classification/ddc/577.273

ddc:577.273

Road transportation impact on Ghana's future energy and environment

Faah, George

24 July 2009

This research work explored the environmental and socio-economic benefits derived, if some proportion of daily passenger trips made using private cars in Ghana could be shifted to the use of public transport. The research applied the computer software COPERT III in estimating road transport Greenhouse gas (GHG) emissions and fuel consumption in Ghana for the base year 2005 and forecast years 2010 and 2020. The research reveals that if no major change occur in policies or economic determinants in meeting road transport and energy in Ghana, then the 2005 total emissions value is expected to rise by 36% in 2010 and over double in 2020 i.e. from 4.6 to 6.25 in 2010 and to 9.77 Mt CO2e in 2020. However, if just 10% of daily passenger trips using private cars can be shifted towards the use of public transport, then the end results in reduction in emissions could earn Ghana about $USD 6.6million/year under the Kyoto Protocol CDM initiative. The research also demonstrated that with a further 10% daily passenger trip shift, the outcome could be more promising, increasing to $USD 13million/year.

Treibhausgase

Pendlerverkehr

Ghana

Kyoto Protocol CDM Initiative

COPERT III®

Straßenverkehr

Pendler

Öffentlicher Verkehr

Umweltfaktor

Pendelwanderung

Treibhausgas

ddc:330

rvk:QR 850

rvk:QT 200

rvk:QT

rvk:800

Road transportation impact on Ghana's future energy and environment

Faah, George

24 July 2009

This research work explored the environmental and socio-economic benefits derived, if some proportion of daily passenger trips made using private cars in Ghana could be shifted to the use of public transport. The research applied the computer software COPERT III in estimating road transport Greenhouse gas (GHG) emissions and fuel consumption in Ghana for the base year 2005 and forecast years 2010 and 2020. The research reveals that if no major change occur in policies or economic determinants in meeting road transport and energy in Ghana, then the 2005 total emissions value is expected to rise by 36% in 2010 and over double in 2020 i.e. from 4.6 to 6.25 in 2010 and to 9.77 Mt CO2e in 2020. However, if just 10% of daily passenger trips using private cars can be shifted towards the use of public transport, then the end results in reduction in emissions could earn Ghana about $USD 6.6million/year under the Kyoto Protocol CDM initiative. The research also demonstrated that with a further 10% daily passenger trip shift, the outcome could be more promising, increasing to $USD 13million/year.

info:eu-repo/classification/ddc/330

ddc:330

Systems assessment of biofuels: Modelling of future cost and greenhouse gas abatement competitiveness between biofuels for transport on the case of Germany

Millinger, Markus

20 February 2019

Biofuels are a renewable alternative for reducing the climate impact of transport. Due to the versatility of biomass and complexity of economics and impacts, biofuels are part of a complex system, which is here analysed from a systems perspective. Several models are developed in order to assess the competitiveness of various crop based biofuel options as part of a system, using different economic and environmental functional units. The scope is set to Germany until 2050. The capital and feedstock costs were revised to higher levels compared to common assumptions. The different functional units result in different merit orders for the biofuel options. Currently used biofuels, rape seed based biodiesel and starch crop based bioethanol, were found not to be competitive when considering differentiated and increasing feedstock costs. Advanced liquid fuels were only competitive at extreme assumptions, contrary to common expectations. Instead, sugar beet based ethanol dominated for most of the time span when comparing energetic cost, whereas Synthetic Natural Gas (SNG) was competitive on a greenhouse gas abatement (GHG) cost basis, especially at a rapid decarbonisation of the power mix. With a land use GHG abatement functional unit, silage maize based biomethane was the best, with SNG converging only at very high renewables shares of the background systems. Switching from current practise to higher yielding biofuel options can treble the abatement per land area for the present day, and potentially increase it by a factor five in the future. A focus on GHG abatement per area of arable land results in the land passenger transport sector to be of the highest priority due to the suitability of higher yielding biofuel options, followed by land goods transport, shipping and finally aviation. If gaseous fuels are not possible to introduce on a large scale, sectors where liquefied gaseous fuels are suitable become the priority, i.e. goods transport and shipping. The current practise of applying admixture quotas to sub-sectors of land transport renders a significantly lower climate benefit compared to an overall optimal usage, and a large societal transition is required before aviation biofuels become the climate optimal biomass usage. The direct importance of land use has thus far not received enough attention in terms of the economics of biofuels from dedicated crops, as well as for the greenhouse gas emissions policy. Biofuels produced from arable land can provide a strong GHG benefit if an expansion of arable land is hindered through redirecting land use, which requires a holistic policy approach.:Abstract ix Acknowledgments xi List of Publications xiii List of Acronyms xv I Introductory chapters 1 1 Background 3 1.1 Biofuels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 1.2 Technological Change and Modelling . . . . . . . . . . . . . . . . . . . . . . 6 1.3 Aim and objectives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 2 Methodology 9 2.1 Systems modelling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 2.2 Model description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 3 Results and discussion 17 3.1 Biofuel techno-economic potential and competitiveness . . . . . . . . . . . . 17 3.2 Discussion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 3.2.1 Resource base . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 3.2.2 Biomass climate benefit in other sectors . . . . . . . . . . . . . . . . 20 3.2.3 Other renewable fuel options . . . . . . . . . . . . . . . . . . . . . . 21 3.2.4 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 3.2.5 Applicability of results to other regions . . . . . . . . . . . . . . . . 22 4 Conclusions 25 4.1 Future research . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Bibliography 29 Contribution to Appended Papers 33 Curriculum Vitae 35 CONTENTS II Appended papers 37 1 Competitiveness of advanced and conventional biofuels: Results from least-cost modelling of biofuel competition in Germany 39 2 Biomass price developments inhibit biofuel investments and research in Germany: The crucial future role of high yields 51 3 Relative greenhouse gas abatement cost competitiveness of biofuels in Germany 63 4 Climate optimal deployment of biofuels from crops in Germany 85 / Biokraftstoffe sind eine erneuerbare Alternative zur Verringerung der Klimaauswirkungen des Verkehrs. Aufgrund der Vielseitigkeit der Biomasse und der Komplexität der Ökonomie und der Auswirkungen sind Biokraftstoffe Teil eines komplexen Systems, das hier aus einer Systemperspektive analysiert wird. Es werden mehrere Modelle entwickelt, um die Wettbewerbsfähigkeit verschiedener biogener Biokraftstoffoptionen als Teil eines Systems unter Verwendung verschiedener wirtschaftlicher und ökologischer Funktionseinheiten zu bewerten. Der Umfang ist auf Deutschland bis 2050 festgelegt. Die Kapital- und Rohstoffkosten wurden im Vergleich zu herkömmlichen Annahmen auf ein höheres Niveau angepasst. Die verschiedenen Funktionseinheiten führen zu unterschiedlichen Merit Order für die Biokraftstoffoptionen. Die derzeit verwendeten Biokraftstoffe, Raps-Saatgut-Biodiesel und Stärkepflanzen-Bioethanol, erwiesen sich als nicht wettbewerbsfähig, wenn man differenzierte und steigende Rohstoffkosten in Betracht zieht. Fortschrittliche flüssige Kraftstoffe waren nur unter extremen Annahmen wettbewerbsfähig, entgegen den üblichen Erwartungen. Stattdessen dominierte Ethanol auf Zuckerrübenbasis für einen Großteil der Zeitspanne beim Vergleich der Energiekosten, während synthetisches Erdgas (SNG) auf der Basis der Treibhausgasvermeidungskosten wettbewerbsfähig war, insbesondere bei einer schnellen Dekarbonisierung des Strommixes. Mit einer Funktionseinheit zur Reduzierung der Treibhausgasemissionen war Silagemais-basiertes Biomethan die beste Option, wobei SNG bei sehr hohen Anteilen an erneuerbaren Energien der Hintergrundsysteme konvergierte. Der Wechsel von der derzeitigen Praxis zu ertragreicheren Biokraftstoffoptionen kann die Verringerung pro Landfläche für die Gegenwart verdreifachen und in Zukunft möglicherweise um den Faktor fünf erhöhen. Die Fokussierung auf die Reduzierung von Treibhausgasen pro Ackerfläche führt dazu, dass der Landpersonenverkehr aufgrund der Eignung ertragreicherer Biokraftstoffoptionen, gefolgt von Landverkehr, Schifffahrt und schließlich Luftfahrt, höchste Priorität genießt. Wenn es nicht möglich ist, gasförmige Kraftstoffe in großem Maßstab einzuführen, werden Sektoren, in denen verflüssigte gasförmige Kraftstoffe geeignet sind, zur Priorität, d.h. Güterverkehr und Schifffahrt. Die aktuelle Praxis der Anwendung von Beimischungsquoten für Teilbereiche des Landverkehrs führt zu einem deutlich geringeren Klimanutzen im Vergleich zu einer insgesamt optimalen Nutzung, und es ist ein großer gesellschaftlicher Wandel erforderlich, bevor Biokraftstoffe aus der Luftfahrt zur klimaoptimalen Biomassenutzung werden. Die direkte Bedeutung der Landnutzung hat bisher nicht genügend Beachtung gefunden, sowohl in Bezug auf die Wirtschaftlichkeit von Biokraftstoffen aus Sonderkulturen als auch in Bezug auf die Treibhausgasemissionen. Biokraftstoffe, die von Anbaubiomasse hergestellt werden, können einen starken Treibhausgasvorteil bieten, wenn eine Ausweitung der Ackerfläche durch eine Neuausrichtung der Landnutzung behindert wird, was einen ganzheitlichen politischen Ansatz erfordert.:Abstract ix Acknowledgments xi List of Publications xiii List of Acronyms xv I Introductory chapters 1 1 Background 3 1.1 Biofuels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 1.2 Technological Change and Modelling . . . . . . . . . . . . . . . . . . . . . . 6 1.3 Aim and objectives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 2 Methodology 9 2.1 Systems modelling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 2.2 Model description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 3 Results and discussion 17 3.1 Biofuel techno-economic potential and competitiveness . . . . . . . . . . . . 17 3.2 Discussion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 3.2.1 Resource base . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 3.2.2 Biomass climate benefit in other sectors . . . . . . . . . . . . . . . . 20 3.2.3 Other renewable fuel options . . . . . . . . . . . . . . . . . . . . . . 21 3.2.4 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 3.2.5 Applicability of results to other regions . . . . . . . . . . . . . . . . 22 4 Conclusions 25 4.1 Future research . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Bibliography 29 Contribution to Appended Papers 33 Curriculum Vitae 35 CONTENTS II Appended papers 37 1 Competitiveness of advanced and conventional biofuels: Results from least-cost modelling of biofuel competition in Germany 39 2 Biomass price developments inhibit biofuel investments and research in Germany: The crucial future role of high yields 51 3 Relative greenhouse gas abatement cost competitiveness of biofuels in Germany 63 4 Climate optimal deployment of biofuels from crops in Germany 85

info:eu-repo/classification/ddc/330

ddc:330

Numerical model for estimating greenhouse gas emissions from pulp and paper industrial wastewater treatment systems in Vietnam

Dang, Xuan Hien, Nguyen, Thi Van Anh, Nguyen, Duc Toan, Dang, Thanh Son

05 February 2019

At present, it is difficult and costly to measure directly greenhouse gas (GHG) emissions from the wastewater treatment system. Application of model will reduce measurement cost and quickly obtain the forecast data set of GHG emissions. This study developed a mathematical model for both steady and dynamic states to calculate GHG (CO2, CH4, and N2O) emissions from wastewater treatment systems for industrial paper processing. These models are constructed based on mass balance equations of species, including substrate balance equations, biomass balance equations for reactors of treatment systems, stoichiometric coefficiences of species in biochemical reactions and biological processes. The obtained equations were solved based on algorithm of Runge-Kutta and the model was programmed by MATLAB. Results of applying the model to calculate GHG emissions from the paper industrial wastewater treatment system at Bai Bang and Tan Mai plants are as follows: total GHG emissions and emission factor are 3,070.3 kgCO2-eq/day, 0.38 kgCO2- eq/m3, respectively for Bai Bang plant (8,000 m3/day) and 7,413.6 kgCO2-eq/day, 0.74 kgCO2- eq/m3, respectively for Tan Mai plant (10,000 m3/day). The research evaluated a number of influencing factors, such as temperature, flow rate of influent, and substrate concentrations, to GHG emissions at the Tan Mai paper plant. / Hiện nay, việc đo đạc trực tiếp phát thải khí nhà kính (KNK) từ hệ thống xử lý nước thải còn khó khăn và tốn kém. Việc áp dụng mô hình sẽ giảm được chi phí đo đạc và nhanh chóng có được bộ số liệu dự báo một cách tương đối về phát thải KNK. Nghiên cứu đã thiết lập được mô hình toán ở trạng thái ổn định và trạng thái không ổn định để tính toán phát thải khí nhà kính (CO2, CH4, N2O) từ hệ thống xử lý nước thải sản xuất giấy. Các mô hình này dựa trên các phương trình cân bằng chất của các cấu tử bao gồm các phương trình cân bằng cơ chất, các phương trình cân bằng sinh khối trong các bể phản ứng và các hệ số tỷ lượng của các chất tham gia các phản ứng sinh hóa. Các phương trình được giải bằng thuật toán Runge-Kutta và mô hình được lập trình trên ngôn ngữ MATLAB. Mô hình được áp dụng tính toán phát thải khí nhà kính từ hệ thống xử lý nước thải tại nhà máy giấy Bãi Bằng và nhà máy giấy Tân Mai, được kết quả như sau: tổng phát thải khí nhà kính (KNK) và hệ số phát thải là 3.070,3 kg CO2-tđ/ngày, 0,38 kg CO2-tđ/m3 tại Nhà máy giấy Bãi Bằng (8.000 m3/ngày) và 7.413,6 kg CO2-tđ/ngày, 0,74 kg CO2-tđ/m3 nhà máy giấy Tân Mai (10.000 m3/ngày). Nghiên cứu đã đánh giá được một số các yếu tố ảnh hưởng như nhiệt độ, lưu lượng nước thải và nồng độ cơ chất dòng vào đến sự phát thải KNK tại nhà máy giấy Tân Mai.

info:eu-repo/classification/ddc/363.7

ddc:363.7

The effect of turning frequency on methane generation during composting of anaerobic digestion material: Research article

Nguyen, Thanh Phong, Cuhls, Carsten

24 August 2017

Methane (CH4) is included in the direct greenhouse gases listed in the Kyoto protocol. The composting of anaerobic digestion (henceforth AD) material is a source of CH4. CH4 is the major contributor to overall CO2 emissions. Therefore, it is important to know the formation of this gas from different stages and substrates of the composting process. This study investigated CH4, CO2 and O2 profiles in two open-windrows in composting plants treating AD material. One composting windrow was turned one a week; whereas another was turned twice a week using a special windrow turner. To assess the gaseous formation in the composting windrows, CH4, CO2 and O2 volume concentrations were measured at different depths. Active aeration has been considered as a method to reduce CH4 generation during composting. However, our results showed that frequent turned windrow generated more CH4 than less turned windrow. The highest CH4 concentrations were found at a depth of 1 m, and were 45% and 37% for 2 times a week turned windrow and 1 time a week turned windrow respectively. Gas concentrations of CH4, O2 and CO2 in both windrows differed. Concentrations of CO2 and CH4 increased with depth, whereas concentration of O2 decreased from the surface to the lowest point. The O2 and CO2 are important factors in determining whether the windrows are anaerobic or aerobic. / Khí mê tan (CH4) là một trong những khí nhà kính được liệt kê trong nghị định thư Kyoto. Quá trình ủ phân compost từ các chất thải của hầm ủ biogas là nguồn phát sinh loại khí này. Khí mê tan đóng góp chủ yếu trong tổng lượng khí nhà kính phát thải vào khí quyển. Do đó, những hiểu biết về quá trình hình thành loại khí này trong các giai đoạn khác nhau của quá trình ủ phân compost từ chất thải hầm ủ biogas là rất quan trọng. Nghiên cứu này tìm hiểu sự phát thải khí CH4, CO2 và O2 trong 2 luống ủ ngoài trời tại các nhà máy xử lý rác thải hữu cơ bằng phương pháp kỵ khí. Luống ủ 1 được đảo trộn một lần một tuần trong khi luống ủ số 2 được đảo trộn 2 lần 1 tuần. Để đo đạc lượng khí phát thải từ các luống ủ phân compost, nồng độ các khí CH4, CO2 và O2 được đo ở các độ sâu khác nhau. Việc cung cấp khí oxy được coi như là một biện pháp để làm giảm sự hình thành khí mê tan. Tuy nhiên, kết quả đo đạc của chúng tôi chứng minh rằng việc đảo trộn thường xuyên phát thải nhiều khí mê tan hơn ít đảo trộn. Nồng độ khí mê tan cao nhất 45% và 37% đo được ở khoảng cách 1m từ bề mặt đối với luống ủ đảo trộn hai lần và một lần. Nồng độ các khí CH4, CO2 và O2 khác nhau ở hai luống trong thí nghiệm. Nồng độ khí CH4 và CO2 tăng theo độ sâu, trong khi O2 giảm theo độ sâu. Nồng độ khí CO2 và O2 đóng vai trò quyết định luống ủ được cung cấp đủ oxy cho quá trình phân hủy hiếu khí hay không.

info:eu-repo/classification/ddc/363

ddc:363

Life cycle assessment of feedstock recycling processes

Keller, Florian

06 February 2024

This study examines the ecological impact of exemplary processes for the feedstock recycling of waste fractions. It is shown that the material process efficiency of gasification and pyrolysis has a low impact on the greenhouse gas balance in the short term, but that high product yields are necessary in the long term to avoid an increasing climate impact. In a systemic context, different process routes of syngas and pyrolysis oil utilization are compared, and their efficiency and quantitative potential for greenhouse gas reduction compared to electricity-based alternatives of process direct heating of conventional processes and electrolysis-based process chains are classified. It is shown that direct utilization options with few process steps are ecologically more efficient. Feedstock recycling shows a similar reduction potential to direct heating, while the use of electrolysis-based process chains is inefficient but necessary to achieve systemic climate neutrality.:1. Introduction and outline 1 2. Life cycle assessment methodology 5 2.1. Previous LCA investigation on feedstock recycling 7 2.2. Assessment scope 9 2.3. Attributional vs. consequential LCI modelling 11 2.4. Inventory modelling consistency 12 2.5. Prospective technology assessment 13 2.6. Conclusions for the applied methodology 14 3. Process description and modelling 16 3.1. Feedstock recycling technologies 18 3.1.1. Gasification 18 3.1.2. Syngas conditioning and purification 23 3.1.3. Pyrolysis 29 3.1.4. Pyrolysis oil hydroprocessing 32 3.2. Chemical production technologies 34 3.2.1. Steam cracking 35 3.2.2. Catalytic reforming 37 3.2.3. Olefin and BTX recovery 38 3.2.4. Conventional syngas production 41 3.2.5. Methanol and methanol-based synthesis 43 3.2.6. Ammonia synthesis 48 3.3. Electric power integration options 49 3.4. Conventional waste treatment processes 53 3.4.1. Mechanical biological treatment and material recovery 54 3.4.2. Waste incineration 57 3.5. Utility processes and process chain balancing 59 3.6. Electricity and heat supply modelling 65 4. Individual assessment of feedstock recycling processes 68 4.1. Goal and scope definition 68 4.2. Life cycle inventory 68 4.3. Impact assessment 72 4.4. Interpretation 80 5. System-based assessment of feedstock recycling processes 82 5.1. Goal and scope definition 82 5.2. Life cycle inventory 86 5.2.1. Utility, background system inventory and system integration 88 5.2.2. Assessment scenario definition and parameter variation 90 5.3. Impact assessment 93 5.3.1. Framework Status Quo (FSQ) 93 5.3.2. Framework Energy Integration (FEI) 99 5.4. Interpretation 106 6. Summary and conclusion 109 6.1. Results 110 6.2. Recommendations and outlook 111 References 113 Supplementary Material 136

info:eu-repo/classification/ddc/660

ddc:660

Pyrolyse

Vergasung

Synthesegas

Öl

Verfahrenstechnik

Minderung

Treibhausgas

Is short rotation forestry biomass sustainable?

Zurba, Kamal

27 October 2016

Despite the negative effects of fossil fuels on the environment, these remain as the primary contributors to the energy sector. In order to mitigate global warming risks, many countries aim at reducing greenhouse gas emissions. Bioenergy crops are being used as a substitute for fossil fuels and short rotation forestry is a prime example. In order to examine the sustainability of energy crops for fuel, typical European short rotation forestry (SRF) biomass, willow (Salix spp.) and poplar (Populus spp.) are examined and compared to rapeseed (Brassica napus L.) in respect to various aspects of soil respiration and combustion heat obtained from the extracted products per hectare. Various approaches are used to look at an As-contaminated site not only in the field but also in a soil-column experiment that examines the fate of trace elements in SRF soils, and in an analysis using MICMAC to describe the driving factors for SRF crop production. Based on the cause-effect chain, the impacts of land-use change and occupation on ecosystem quality are assessed when land-use is changed from degraded land (grassland) to willow and poplar SRF. A manual opaque dynamic closed chamber system (SEMACH-FG) was utilized to measure CO2 emissions at a willow/poplar short rotation forest in Krummenhennersdorf, Germany during the years 2013 and 2014, and at a rapeseed site in 2014. Short rotation forest soils showed higher CO2 emission rates during the growing season than the dormant season – with a CO2 release of 5.62±1.81 m-2 s-1 for willows and 5.08±1.37 µmol CO2 m-2 s-1 for poplars in the growing season. However, during the dormant season the soil sites with willow emitted 2.54±0.81 µmol CO2 m-2 s-1 and with poplar 2.07±0.56 µmol CO2 m-2 s-1. The highest emission rates for the studied plantations were observed in July for both years 2013 and 2014, during which the highest air and soil temperatures were recorded. Correlations between soil emission of CO2 and some meteorological parameters and leaf characteristics were investigated for the years 2013 and 2014. For example, for the willow clone (Jorr) and poplar clone (Max 3), high correlations were found for each between their soil emission of CO2 and both soil temperature and moisture content. Fitted models can explain about 77 and 75% of the results for Jorr and Max 3 clones, respectively. Moreover, a model of leaf area (LA) can explain about 68.6% of soil CO2 emission for H275. Estimated models can be used as a gap-filling method, when field data is not available. The ratio between soil respiration and the combustion heat calculated from the extracted products per hectare was evaluated and compared for the study’s willow, poplar and rapeseed crops. The results show that poplar and willow SRF has a very low ratio of 183 kg CO2 GJ 1 compared to rapeseed, 738 kg CO2 GJ 1. The soil-column experiment showed that by continuing the SRF plantation at the As-contaminated site, remediation would need only about 3% of the time needed if the site was left as a fallow field. In order to understand the complex willow and poplar short rotation forestry production system, 50 key variables were identified and prioritized to describe the system as a step to enhance the success of such potentially sustainable projects. The MICMAC approach was used in order to find the direct and the indirect relationships between those parameters and to classify them into different clusters depending on their driving force and interdependency. From this, it can be summarized that in order to enhance the success of a SRF system, decision makers should be focussing on: ensuring a developed wood-fuel market, increasing farmers’ experience/training, improving subsidy regulations and recommending a proper harvesting year cycle. Finally, the impacts of land-use change and occupation on the ecosystem quality were assessed. Results show that establishing SRF plantations on degraded lands improved the ecosystem structural quality (ESQ) by about 43% and ecosystem functional quality (EFQ) by about 12%. Based on overall results, poplar and willow SRF biomass can be recommended as renewable and sustainable sources for bioenergy.

Kurzumtriebsplantage

Biomasse

Nachhaltigkeit

Bodenbeatmung

Treibhausgase

Landnutzungsänderung

Ökosystem

Short rotation forestry

biomass

sustainability

soil respiration

greenhouse gases

land use change

ecosystem

ddc:333.7

Plantage

Biomasse

Treibhausgas

Waldökosystem

Landnutzung

Agrarökosystem

Schnellwuchsplantage

Kurzumtrieb

Nutzungsänderung

Aerationszone

Bodenluft

Nachhaltigkeit

Treibhausgas-Emissionen in der deutschen Landwirtschaft / Herkunft und technische Minderungsmaßnahmen unter besonderer Berücksichtigung von Biogas / Green house gas emissions in German agriculture / Sources and technical reduction capacities under special consideration of biogas

Wegener, Jens-Karl

25 January 2007

No description available.

630 Landwirtschaft

Veterinärmedizin

Agricultural Sciences

Treibhausgas-Emissionen

Landwirtschaft

Biogas

Biomasse

Potenzial

Quellen

Senken

Brennstoffzelle

Direkteinspeisung

Blockheizkraftwerk

Green house gas

agriculture

biogas

biomass

potential

sources

sinks

fuel-cell

direct gas feeding

block heat and power plant

48.00

YA 000: Land- und Forstwirtschaft

Gutes Klima – ein schmaler Grat zwischen Fakten und Interpretationen

Arnold, Marlen Gabriele

16 June 2020

Satire erlaubt alles – so die Aussage einiger Comedians und Freunde des gepflegten Spöttelns. Doch wenn politisches Kabarett dazu beiträgt, Falschinformationen und Fehlinterpretationen zu verbreiten – darf Satire dann immer noch alles? Trägt nicht auch das politische Kabarett Verantwortung für eine adäquate Faktendarstellung anstelle einseitiger Politisierung? Satire blendet leider auch einige Fakten und Wirkbezüge in der Klimadebatte und den wissenschaftlichen Erkenntnissen aus. Dass diese Blindheit und Ignoranz nicht zwingend zuträglich für eine gesellschaftliche Entwicklung und die Aufgeklärtheit einer Gesellschaft sind, liegt auf der Hand – aller Freiheit politischer Satire zum Trotz. Auch wenn zu viel Informationen und Wissen, und erst recht ambigue und widersprüchliche Daten, zu Verwirrungen und häufig nicht zur Irritation der eigenen (festgefahrenen) Weltbilder führen können, soll dieser Beitrag die Vielfalt der Daten und Interpretationsspielräume aufzeigen und zu mehr factfulness in der Klimadiskussion motivieren. / Satire allows everything - so the statement of some comedians and friends of the cultivated mockery. But if political cabaret contributes to spreading misinformation and misinterpretations - is satire still allowed to do everything? Doesn't political cabaret also bear responsibility for an adequate presentation of facts instead of one-sided politicization? Unfortunately, satire also ignores some facts and causal relations in the climate debate and scientific knowledge. It is obvious that this blindness and ignorance is not necessarily conducive to social development and the enlightenment of a society - despite all the freedom of political satire. Even if too much information and knowledge, and even more so ambiguous and contradictory data, can lead to confusion and often not to the irritation of one's own (deadlocked) world views, this contribution is intended to show the diversity of data and scope for interpretation and motivate more factfulness in the climate debate.

info:eu-repo/classification/ddc/658

ddc:658