This book contains papers presented at the Engineering Foundation Conference on mineral matter in fuels held on November 2-7, 1997 in Kona, Hawaii. The conference is one of a continuing series that was initiated by the CEGB Mar- wood Engineering Laboratories in 1963. The conference was to be eventually organised by the Engineering Foundation as the need for multi-disciplinary work related to c- trolling ash effects in combustors became apparent. The conference covers both the science and the applications. The papers also present case histories, particularly for current fuel technologies, developments in advanced technologies for power generation and mathematical modelling of these processes. Developments since 1963 have been slow, but steady, due to the complexity of the chemical and physical processes involved. However, the research presented here displays great improvement in our understanding of the mechanisms by which mineral matter will influence fuel use. Steve Benson from EERC presented a review and current status of issues related to ash deposition in coal combustion and gasification. The application of new analytical tools, which have been detailed in the previous conferences, is presented. These include CCSEM, as well as new techniques for char- terising sintering of ash, such as TMA, image analysis, X-ray diffraction crystallography and thermal analysis. The new analytical techniques were extended to encompass widely differing fuels such as biomass. Ole H Larsen from ELSAM Denmark presented a review of these advanced techniques.

As an increasing number of professionals and graduate students enter the field of solid-based power generation, they all require an command of process and equipment, as well as the theory behind it all. However, their informational needs and understanding differ based on their experience and the task at hand.

Solid Fuels Combustion and Gasification: Modeling, Simulation, and Equipment Operations, Second Edition explores evolving solid fuel combustion and gasification techniques that are leading to much lower sulfur and nitrogen oxide emissions. It also shows how to increase the efficiency of processes dealing with materials such as coal, biomass, solid residues, etc. Many of the successes of these methods are the result of process optimization resulting from mathematical modeling and simulation. This book introduces and explores these techniques, taking a moderate approach that is neither too narrow nor too basic, making it useful to graduate students, engineers, and professionals.

It illustrates the modeling and constructive and operational aspects of equipment used in combustion and gasification of solid fuels. It was written based on the idea that developing models and computer simulators is the optimal method to acquire real and testable understanding of a subject in the area of processing.

Model complexity is extended only as far as needed to achieve a reasonable representation of the equipment described in the book, and the author provides specific and carefully selected case studies that:

• Cover many industrial processes involving combustion or gasification of solid fuels
• Provide easy-to-follow examples on how to set simplifying assumptions regarding the operation of real industrial equipment
• Enable relatively quick introduction of fundamental equations without the need for unnecessarily complex treatments

The main strategy of the book is to teach by example, and the basic methods illustrated here can be used for modeling a wide range of processes and equipment commonly found in industry. It is a carefully constructed volume which presents essential concepts that minimize the need for other texts, and it can also be used as an introduction to more complex models.

Lignocellulosic biomass conversion to fuel is the only sustainable way to meet the current and future energy demands, at least in displacing a substantial amount of liquid transportation fuel, and curb detrimental effects of greenhouse gas emissions. Various routes and processes to convert lignocellulosic biomass to fuels, chemicals, and bio-based materials have been developed in the last couple of decades. This book contains eleven chapters that intend to provide readers with updates on these various processes and routes to produce fuels and chemicals using lignocellulosic biomass. In addition, it covers the past and current developments on biomass logistics, analytical tools applied to characterise lignocellulosic biomass, environmental aspects and engine performance of various fuels, as well as techno-economical aspects of lignocellulosic biomass refinery. The following list summarises the topics covered in this book: The past and current developments on biomass valorisation in biochemical platforms; Developments in thermochemical conversion of biomass to fuels and chemicals including gasification, pyrolysis, and hydrothermal treatment; Heterogeneous catalysts application in low to high temperature conversion of biomass to fuels and chemicals; Pathways of lignin valorisation to fuels and chemicals; Production methods and the physicochemical properties of nanocelluloses; The environmental impacts and engine performances of various bio-fuels; Biomass logistics and their impact on bioenergy applications; Anaerobic conversion of biomass to biogas and impacts of co-digestion on biogas yields and quality.

This title includes a number of Open Access chapters. The practice of converting corn to ethanol is controversial, with debates currently being raged in both public policy and science. While biofuels from corn have important implications in alleviating some of the global energy crisis, critics argue that it takes away from vital agricultural products needed to feed the world's growing population. The current volume maintains there is a third way, a method of producing biofuel that only uses biomass that is left behind after all agricultural and nutritional products have been harvested from corn. This biomass is referred to as corn stover. The book serves as an important introduction to this method of producing biofuels from agricultural waste. Edited by a professor from the State University of New York, Geneseo, this reference is important not only for research scientists, but for students and public policy makers who wish to learn more about this alternative method of producing ethanol from corn. The sections found in Fuel Production from Non-Food Biomass: Corn Stover describe the following topics: An overview of why corn stover is a good alternative use of power The technology that makes this process possible on various scales Considerations for policy formation, including economic, land-use, and environmental arguments for and against using corn stover as a biofuel Although controversy still exists about the use of corn stover-with some critics saying that it will cause food shortages, particularly for developing nations-the research in this book focuses on using corn's already existing, non-food biomass and argues that food and biofuel could potentially be produced from the same fields.

This title includes a number of Open Access chapters. As the world's energy hunger grows ever larger, fossil fuel reserves are diminishing-and concerns about climate change remind us that our love affair with fossil fuels cannot continue much longer. This has inspired intense research into sustainable energy sources. Biofuels seemed initially promising, but the world soon realized that food-based biofuel has its own dangers. Second-generation biofuels, however, use biomass from crops' inedible parts-such as the stalks and leaves of sugarcane-offering a far more practical, sustainable, and commercially viable solution. In this book, researchers from around the world review some of the most important and timely topics related to using sugarcane feedstock for biofuel. After a basic overview, topics such as these are included: Pretreatment methods The use of various microbial technologies, including bacteria and yeast, to enhance biofuel production Environmental impacts Economic feasibility The viability of electricity being produced side by side with biofuel Essential reading for graduate students and research scientists investigating second-generation biofuels, this book is also recommended for environmentalists, environmental engineers, and microbiologists.

In this book, the authors present current research in the study of bioenergy systems and their biological sources and environmental impact. Topics discussed include the assessment of sustainability of bioenergy systems; soil loss as a forgotten aspect of biofuel production; effective biocatalysts for lignocellulosic biofuel by a proteomics study of fungal secretome; enhancing the interface between agricultural production, and tree biomass/bioenergy systems to improve farm-scale productivity in Western Australia; hydrogen and ethanol comparison as fuels for internal combustion engines; and hydrogen production by mixed cultures.

Municipal solid waste (MSW) is a domestic energy resource with the potential to provide a significant amount of energy to meet U.S. liquid fuel requirements. MSW is defined as household waste, commercial solid waste, non-hazardous sludge, conditionally exempt, small quantity hazardous waste and industrial solid waste. This book examines the potential use of MSW to make synthesis gas (syngas) suitable for production of liquid fuels; the expected process scale required for favorable economics; the availability of MSW in quantities sufficient to meet process scale requirements and state-of-the-art MSW gasification technology.

Explore a thorough and up to date overview of the current knowledge, developments and outstanding challenges in turbulent combustion and application. The balance among various renewable and combustion technologies are surveyed, and numerical and experimental tools are discussed along with recent advances. Covers combustion of gaseous, liquid and solid fuels and subsonic and supersonic flows. This detailed insight into the turbulence-combustion coupling with turbulence and other physical aspects, shared by a number of the world leading experts in the field, makes this an excellent reference for graduate students, researchers and practitioners in the field.

As solid state chemistry becomes increasingly important, organometallic chemistry will play a key role in addressing complex structures and developing novel interface chemistry. In a collection of reviews, leading chemists Focus on X-ray diffraction, MAssbauer spectroscopy and solid-state NMR in an overview of state-of-the-art structure analysis techniques and chemical applications in the solid state. Solid State Organometallic Chemistry
* Summarizes the progress that has been made in physical models and physical measurements of organometallics in the solid state.
* Critically analyses X-ray diffraction techniques in advanced and single crystal structure determination.
* Discusses the potentials of MAssbauer spectroscopy, solid state NMR and X-ray spectroscopy in structural analysis.
* Includes ab initio calculations on bonding in transition metal complexes.
This book will be invaluable to organometallic and solid state chemists and will also be of interest to physicists as well as polymer and materials scientists.

The book reports on the results of the BrenaRo Winterschool 2011, held on November 21-22 in Aachen, Germany. The different chapters cover a number of aspects of the topic of energy generation, with a particular focus on energy generation from biomass. They presents new findings concerning engine development, process engineering, and biological and chemical conversion of biomass to fuels, and highlight the importance of an interdisciplinary approach, combining chemistry, biology and engineering research, to the use of renewable energy sources. All in all, this book provides readers with a snapshot of the state-of-the-art in renewable energy conversion, and gives an overview of the ongoing work in this field in Germany.

The goal of coal mining is to economically remove coal from the ground. Coal is valued for its energy content, and since the 1880s is widely used to generate electricity. The most economical method of coal extraction from coal seams depends on the depth and quality of the seams, and the geology and environmental factors. This book presents current research from across the globe in the study of coal extraction, including production of ashless coal by using a solvent extraction technique; the Hotelling model of optimal non-renewable resource extraction; coal extraction with a carbon disulfide/N-Methyl-2-pyrrolidinone mixed solvent; and extraction of inorganic species of coal.

Fuel ethanol production has increased steadily in the U.S. since the 1980's, when it was given impetus by the need to reduce energy dependence on foreign supplies. The momentum has continued as production costs have fallen, and as the U.S. Clean Air Act has specified a percentage of renewable fuels to be mixed with gasoline. New technologies that may further increase cost savings include co-product development, such as recovery of high-value food supplements, and cellulosic conversion. Though improvements in processing and technology are important, however, the fluctuating rise of inputs such as corn, the cost of energy alternatives, and environmental developments play larger roles in the fortunes of the industry. This book examines the use of ethanol as fuel, as well as its other applications in different parts of the world. This book also addresses a policy initiative by the Federal Administration to apply United States Department of Energy (DOE) research to broadening the country's domestic production of economic, flexible, and secure sources of energy fuels. This book consists of public documents which have been located, gathered, combined, reformatted, and enhanced with a subject index, selectively edited and bound to provide easy access.

This book discusses the current development of the study on coal combustion, which mainly involves devolatilization, volatiles combustion, char combustion and the formation of pollutants. Regarding the devolatilization of coal, it is well-known that devolatilization has a significant impact on the other processes during coal combustion. The process of char combustion is of central importance in practical pulverized applications. However, the mechanism of char combustion has not yet been completely understood due to the existence of many factors such as the thermal annealing of char, the pore structure, inherent mineral content in char and the fragmentation of the char particle. This book also presents a detailed discussion on the intrinsic reactivity and thermal annealing of char, as well as the comparison of different char combustion models.

Coal use today is responsible for large, and mostly avoidable, damages to human health and our water and land. Coal use in the future, along with other fossil fuels, threatens to wreak havoc in the earth's climate system. This book looks at "clean coal" technologies such as coal gasification and carbon capture. Coal gasification, when done in conjunction with carbon capture and storage (CCS) is one technology option that offers our nation an attractive approach to utilise our indigenous fossil energy resources in a more efficient and environmentally sound manner for producing clean, affordable power from coal with dramatically reduced carbon emissions. Coal gasification with CCS can also reduce the carbon impact of using coal to produce ultra-clean fuels for the transportation sector, substitute natural gas (SNG) to heat our homes and fuel our industrial sector, fertilisers to ensure an abundant food supply, and chemicals that play an integral part in our every day lives. Another coal gasification concept explored in this book that could further reduce carbon dioxide (CO2) emission is co-feeding coal and biomass into gasifiers to produce electricity or conventional transportation fuels. In addition to these technologies, this book also describes ways at improving or optimising the performance of coal-fired power plants, in addition to tools that can be used and are available to cut global warming emissions. This book consists of public domain documents which have been located, gathered, combined, reformatted, and enhanced with a subject index, selectively edited and bound to provide easy access.

The principle fuel used as a petrol substitute for road transport vehicles is bioethanol. Bioethanol fuel is mainly produced by the sugar fermentation process, although it can also be manufactured by the chemical process of reacting ethylene with steam. The main sources of sugar required to produce ethanol come from fuel or energy crops. These crops are grown specifically for energy use and include corn, maize and wheat crops, waste straw, willow and popular trees, sawdust, reed canary grass, cord grasses, Jerusalem artichoke, myscanthus and sorghum plants. Ethanol or ethyl alcohol (C2H5OH) is a clear colourless liquid, it is biodegradable, low in toxicity and causes little environmental pollution if spilt. Ethanol burns to produce carbon dioxide and water. Ethanol is a high octane fuel and has replaced lead as an octane enhancer in petrol. By blending ethanol with gasoline we can also oxygenate the fuel mixture so it burns more completely and reduces polluting emissions. This new and important book gathers the latest research from around the globe in this promising field.

Energy from solar radiation, fixated by self-assembling plant structures, creates biomass that is converted to energy carriers fit for application in today's and tomorrow's energy-generating equipment. The central theme of this book is the development of the current largest renewable energy source for efficient applications in modern and developing society-biomass. The book is presented in an easy-to-understand manner for non-experts, nevertheless revealing the true challenges of this extremely broad area. Through this book, passionate pioneers and (ex-)EU officials tell the interesting history of the use of biomass by mankind in general and how the future of its modern use was shaped by active support of the European Union. The book mainly emphasizes specific technologies, both biological and thermo-chemical, from simple to extremely complex. Recognized experts explain these technologies in a clear way along with their future prospects. Climb on the shoulders of all 35 authors of the book and look into the close and distant future where interaction with other renewable sources will occur, and discover a renewable energy future in which an important role will be played by the oldest one-bioenergy.

Advanced Coal Combustion - Advanced Energy Conversion Systems

This Brief provides a concise review of the potential use of microalgae for biofuel production. The following topics are highlighted: the advantages of microalgae over conventional biofuel-producing crops; technological processes for energy production using microalgae; microalgal biomass production systems, production rates and costs; algae cultivation strategies and main culture parameters; biomass harvesting technologies and cell disruption; CO2 sequestration; life cycle analysis; and algal biorefinery strategies. The conclusions section discusses the contribution of the technologies described to environmental sustainability and future prospects.

Propellants contain considerable chemical energy that can be used in rocket propulsion. Bringing together information on both the theoretical and practical aspects of solid rocket propellants for the first time, this book will find a unique place on the readers' shelf providing the overall picture of solid rocket propulsion technology. Aimed at students, engineers and researchers in the area, the authors have applied their wealth of knowledge regarding formulation, processing and evaluation to provide an up to date and clear text on the subject.

Biohydrogen: For Future Engine Fuel Demands covers the production, purification, storage, pipeline transport, usage, and safety of biohydrogen. Hydrogen promises to be the most significant fuel source of the future, due to its global availability and the fact that water is its only by-product. Biofuels such as bioethanol, biodiesel, bio-oil, and biohydrogen are produced using technologies for thermochemically and biologically converting biomass. Hydrogen fuel production technologies can make use of either non-renewable sources, or renewable sources such as wind, solar, and biorenewable resources.

Biohydrogen: For Future Engine Fuel Demands reviews all of the modern biomass-based transportation fuels, including bioethanol, biodiesel, biogas, biohydrogen, and fuel cells. The book also discusses issues of biohydrogen economy, policy and environmental impact. Biohydrogen looks set to be the fuel of choice in the future, replacing both fossil fuels and biorenewable liquid fuels.

Advances in Bioenergy, Volume Four, is part of a new series that provides both principles and recent developments in various kinds of bioenergy technologies, including feedstock development, conversion technologies, energy and economics, and environmental analysis. Chapters in this new release include Bio-polycarbonate, Advances of gasification for biomass, Cellulase for bioenergy, Butanol production by Clostridium, Bioethanol, an old and new story, and more. The series uniquely provides the fundamentals of these technologies, along with reviews that will be invaluable for students.

Coal and Peat Fires: A Global Perspective, Volume Five: Case Studies - Advances in Field and Laboratory Research, the companion to volumes 1-4, includes the latest research findings about coal and peat fires in the United States, China, India, France, Spain, Poland, and Ireland. Included are chapters about the discovery of microarthropods at two mine fires, the oldest recorded uses of burning coal, the effects of combustion and coal waste on a riverine system, remote sensing analysis of coal fires, gas explosion and spontaneous combustion experiments, and phases associated with the by-products of combustion. This essential reference, along with volumes 1-4, includes a companion website with an interactive world map of coal and peat fires, a collection of slide presentations, research data, and videos: https://www.elsevier.com/books-and-journals/book-companion/9780128498859

Coal-Fired Electricity and Emissions Control: Efficiency and Effectiveness discusses the relationship between efficiency and emissions management, providing methods for reducing emissions in newer and older plants as coal-fired powered plants are facing increasing new emission control standards. The book presents the environmental forces driving technology development for coal-fired electricity generation, then covers other topics, such as cyclone firing, supercritical boilers, fabric filter technology, acid gas control technology and clean coal technologies. The book relates efficiency and environmental considerations, particularly from a technology development perspective.

Solid Fuels and Heavy Hydrocarbon Liquids: Thermal Characterisation and Analysis, Second Edition integrates the developments that have taken place since publication of the first edition in 2006. This updated material includes new insights that help unify the thermochemical reactions of biomass and coal, as well as new developments in analytical techniques, including new applications in size exclusion chromatography, several mass spectrometric techniques, and new applications of nuclear magnetic spectroscopy to the characterization of heavy hydrocarbon liquids The topics covered are essential for the energy and fuels research community, including academics, students, and research engineers working in the power, oil and gas, and renewable energy industries.

Concern over the effects of airborne pollution, green house gases, and the impact of global warming has become a worldwide issue that transcends international boundaries, politics, and social responsibility. The 2nd Edition of Coal Energy Systems: Clean Coal Technology describes a new generation of energy processes that sharply reduce air emissions and other pollutants from coal-burning power plants. Coal is the dirtiest of all fossil fuels. When burned, it produces emissions that contribute to global warming, create acid rain, and pollute water. With all of the interest and research surrounding nuclear energy, hydropower, and biofuels, many think that coal is finally on its way out. However, coal generates half of the electricity in the United States and throughout the world today. It will likely continue to do so as long as it's cheap and plentiful [Source: Energy Information Administration]. Coal provides stability in price and availability, will continue to be a major source of electricity generation, will be the major source of hydrogen for the coming hydrogen economy, and has the potential to become an important source of liquid fuels. Conservation and renewable/sustainable energy are important in the overall energy picture, but will play a lesser role in helping us satisfy our energy demands today. Dramatically updated to meet the needs of an ever changing energy market, Coal Energy Systems, 2nd Edition is a single source covering policy and the engineering involved in implementing that policy. The book addresses many coal-related subjects of interest ranging from the chemistry of coal and the future engineering anatomy of a coal fired plant to the cutting edge clean coal technologies being researched and utilized today. A 50% update over the first edition, this new book contains new chapters on processes such as CO2 capture and sequestration, Integrated Gasification Combined Cycle (IGCC) systems, Pulverized-Coal Power Plants and Carbon Emission Trading. Existing materials on worldwide coal distribution and quantities, technical and policy issues regarding the use of coal, technologies used and under development for utilizing coal to produce heat, electricity, and chemicals with low environmental impact, vision for utilizing coal well into the 21st century, and the security coal presents.