Local biomass feedstocks availability for fueling ethanol production

Crop Production/Industries, Resource /Energy Economics and Policy,

Micro-algae cultivation for biofuels: Cost, energy balance, environmental impacts and future prospects

AbstractMicro-algae have received considerable interest as a potential feedstock for producing sustainable transport fuels (biofuels). The perceived benefits provide the underpinning rationale for much of the public support directed towards micro-algae research. Here we examine three aspects of micro-algae production that will ultimately determine the future economic viability and environmental sustainability: the energy and carbon balance, environmental impacts and production cost. This analysis combines systematic review and meta-analysis with insights gained from expert workshops.We find that achieving a positive energy balance will require technological advances and highly optimised production systems. Aspects that will need to be addressed in a viable commercial system include: energy required for pumping, the embodied energy required for construction, the embodied energy in fertilizer, and the energy required for drying and de-watering. The conceptual and often incomplete nature of algae production systems investigated within the existing literature, together with limited sources of primary data for process and scale-up assumptions, highlights future uncertainties around micro-algae biofuel production. Environmental impacts from water management, carbon dioxide handling, and nutrient supply could constrain system design and implementation options. Cost estimates need to be improved and this will require empirical data on the performance of systems designed specifically to produce biofuels. Significant (>50%) cost reductions may be achieved if CO2, nutrients and water can be obtained at low cost. This is a very demanding requirement, however, and it could dramatically restrict the number of production locations available

Sustainable seabed mining: guidelines and a new concept for Atlantis II Deep

The feasibility of exploiting seabed resources is subject to the engineering solutions, and economic prospects. Due to rising metal prices, predicted mineral scarcities and unequal allocations of resources in the world, vast research programmes on the exploration and exploitation of seabed minerals are presented in 1970s. Very few studies have been published after the 1980s, when predictions were not fulfilled. The attention grew back in the last decade with marine mineral mining being in research and commercial focus again and the first seabed mining license for massive sulphides being granted in Papua New Guinea’s Exclusive Economic Zone.Research on seabed exploitation and seabed mining is a complex transdisciplinary field that demands for further attention and development. Since the field links engineering, economics, environmental, legal and supply chain research, it demands for research from a systems point of view. This implies the application of a holistic sustainability framework of to analyse the feasibility of engineering systems. The research at hand aims to close this gap by developing such a framework and providing a review of seabed resources. Based on this review it identifies a significant potential for massive sulphides in inactive hydrothermal vents and sediments to solve global resource scarcities. The research aims to provide background on seabed exploitation and to apply a holistic systems engineering approach to develop general guidelines for sustainable seabed mining of polymetallic sulphides and a new concept and solutions for the Atlantis II Deep deposit in the Red Sea.The research methodology will start with acquiring a broader academic and industrial view on sustainable seabed mining through an online survey and expert interviews on seabed mining. In addition, the Nautilus Minerals case is reviewed for lessons learned and identification of challenges. Thereafter, a new concept for Atlantis II Deep is developed that based on a site specific assessment.The research undertaken in this study provides a new perspective regarding sustainable seabed mining. The main contributions of this research are the development of extensive guidelines for key issues in sustainable seabed mining as well as a new concept for seabed mining involving engineering systems, environmental risk mitigation, economic feasibility, logistics and legal aspects

The 2002 Farm Bill: Revitalizing the Farm Economy Through Renewable Energy Development

2002 Policy Report.Reduced profit margins and low commodity prices have forced many to leave farming in the past decade, or rely increasingly on off-farm income, while more attractive opportunities in less volatile industries have deterred many young people from entering the farming profession. Currently, less than half of American farmers list farming as their primary source of income and the average American farmer is now 54.3 years old. The agricultural economy has always been volatile when compared to other industries due to (1) the inability of farmers to readily change production levels, (2) a fixed demand for food regardless of price, and (3) the unpredictability of climate events. But many uniquely modern challenges face U.S. agriculture as well, such as competition from foreign producers in an increasingly global economy, the proliferation of large-scale industrial agriculture, and the rising cost of energy inputs. Naturally, the economic hardships within the agricultural sector have had repercussions throughout Rural America. U.S. agriculture is at a crossroads. The decisions that shape this Farm Bill will determine the course of the agricultural sector for years to come. Although many challenges lie ahead, many new opportunities present themselves as well. Our fossil fuel-based economy, which heats our homes, powers our automobiles, and provides us with an array of products, is ultimately unsustainable in the long-term. But a new sustainable economy is slowly emerging, an economy which will rely increasingly on renewable sources of energy such as wind, solar, geothermal, and biomass. Farmers can be at the forefront of this revolution; utilizing the commodities they grow, and even the waste streams they now must dispose of, in innovative new ways to produce power, transportation fuels, and a new generation of biobased products and chemicals. Linking agriculture and renewable energy is key to diversifying our energy market, protecting our environment, and revitalizing rural America ñ truly a ìwin-win-winî opportunity that is good for American farmers and good for the country

Agricultural/Renewable Contributions to U.S. Electricity Usage

Resource /Energy Economics and Policy,

Catch Shares in Action: Peruvian Anchoveta Northern-Central Stock Individual Vessel Quota Program

The Peruvian Anchoveta Northern-Central Stock Individual Vessel Quota Program is a catch share program that manages the largest volume fishery in the world. The goals of the program were focused on the economic improvement of the fishery through reduction of fleet capacity and lengthening of the fishing season. Additional biological and social goals were identified and seen as vital to ensure program success. Key design elements include restrictions on transferability to help limit consolidation and an industrysponsored social fund to assist with crew retirement and labor transition. To reflect the short-lived nature of anchoveta, management is structured into two fishing seasons per year. Each year, a five million metric ton reserve of anchoveta biomass is set aside to promote long term stock health

Models for an Ecosystem Approach to Fisheries

This document is one outcome from a workshop held in Gizo in October 2010 attended by 82 representatives from government, NGO's private sector, and communities. The target audience for the document is primarily organizations planning to work with coastal communities of Solomon Islands to implement Community-Based Resource Management (CBRM). It is however also envisaged that the document will serve as a reference for communities to better understand what to expect from their partners and also for donors, to be informed about agreed approaches amongst Solomon Islands stakeholders. This document does not attempt to summarize all the outcomes of the workshop; rather it focuses on the Solomon Islands Coral Triangle Initiative (CTI) National Plan of Action (NPoA): Theme 1: Support and implementation of CBRM and specifically, the scaling up of CBRM in Solomon Islands. Most of the principles given in this document are derived from experiences in coastal communities and ecosystems as, until relatively recently, these have received most attention in Solomon Islands resource management. It is recognized however that the majority of these principles will be applicable to both coastal and terrestrial initiatives. This document synthesizes information provided by stakeholders at the October 2010 workshop and covers some basic principles of engagement and implementation that have been learned over more than twenty years of activities by the stakeholder partners in Solomon Islands. The document updates and expands on a summary of guiding principles for CBRM which was originally prepared by the Solomon Islands Locally Managed Marine Area Network (SILMMA) in 2007

Plan for promoting the demonstrated systems and technologies for further development – D6.4

This report is the output of the task 6.4 to approach a Plan for promoting the  demonstrated systems and technologies for further deployment. The goal of this task was divided into four specific objectives: 1. To assess the role of the demonstrated new or improved machinery for the sustainable and reliable supply of forest biomass to the facilities, with special focus on cost reduction and/or additional biomass supply that can be achieved by the demonstrated innovative technology; 2. To make proposals to promote the innovation and subsequent technology transfer and to present suggestions on how the inventions that have been developed in this project can overcome the obstacles encountered and reach commercialization; 3. To develop scenarios for the potential markets of lignocellulosic forestry residues for biorefineries and energy use; 4. To perform a risk assessment to estimate the side‐effects of not putting interesting inventions into practice. In the first part, there is a summary of the assessment of the machinery demonstrated in the framework of the INFRES project. Some of the main advantages of the innovations are the cost reduction in comparison with conventional systems, in addition to improved productivity and increased supply. Besides this, a couple of innovations showed fuel savings compared to previous supply chains. Moreover, other improvements have been observed, but without a quantitative assessment. Finally, as a conclusion, certain innovations are successful only when they are used in the conditions they were designed for. In the second part, a plan for overcoming the previously identified barriers was elaborated, and the plan was then submitted for assessment by several experts. The application of the most important measures to overcome the barriers that manufacturers face when developing an innovation is mainly in the hands of the manufacturers themselves, and partly in the hands of policy makers who may contribute through the development of appropriate financing instruments or compensations for high‐risk investments in SME’s. In the case of measures proposed to overcome the barriers that manufacturers face during the implementation or use phase, the application of the measures is in the hands of a balanced mix of the main stakeholders, including forest companies and manufacturers. It means that both have to work, sometimes together, to overcome the detected barriers. In the third part, any of the future scenarios anticipates an increase in woody biomass demand. The growth of the biorefinery sector will change the landscape of the forest biomass requirements by 2030. Indeed, feedstocks such as forest residues and stumps can be easily used by this sector. Besides this, the increase and improvement of the machinery used in the forest biomass supply chains, together with the optimization of the whole chains, take some time. As a consequence, it is a challenge for Europe to reach high enough competitiveness and innovation levels so as to cover the demand needs in the best way, with its own resources, seeking a positive impact on all EU regions and on European machinery manufacturers. Finally, the fourth part concludes that if technological and logistical innovations are not implemented in forest biomass supply chains, then energy and environmental targets in the EU will not be reached. Sustainability and cost efficiency gains in the biomass supply chains will not be achieved either. The introduction of innovative solutions as those presented by INFRES will be made possible by implementing the measures that were identified in the third part for overcoming the barriers in the development, implementation and use phases of the innovations.201

Agriculture's Role in Greenhouse Gas Mitigation

Examines technical, economic, and policy trends. Explores efforts to encourage farmers to adopt new agricultural practices that reduce agricultural greenhouse gas emissions. Reviews biofuel options, and related policy implications

GHG emissions of green coffee production : toward a standard methodology for carbon footprinting : report

In this project, the scope for product specific rules for carbon footprinting of (green) coffee is investigated and a proposal is drafted for further work toward actual definition and implementation of such a standard