Introduction to materials for advanced energy systems

This first of its kind text enables today's students to understand current and future energy challenges, to acquire skills for selecting and using materials and manufacturing processes in the design of energy systems, and to develop a cross-functional approach to materials, mechanics, electronics and processes of energy production. While taking economic and regulatory aspects into account, this textbook provides a comprehensive introduction to the range of materials used for advanced energy systems, including fossil, nuclear, solar, bio, wind, geothermal, ocean and hydropower, hydrogen, and nuclear, as well as thermal energy storage and electrochemical storage in fuel cells. A separate chapter is devoted to emerging energy harvesting systems. Integrated coverage includes the application of scientific and engineering principles to materials that enable different types of energy systems. Properties, performance, modeling, fabrication, characterization and application of structural, functional and hybrid materials are described for each energy system. Readers will appreciate the complex relationships among materials selection, optimizing design, and component operating conditions in each energy system. Research and development trends of novel emerging materials for future hybrid energy systems are also considered. Each chapter is basically a self-contained unit, easily enabling instructors to adapt the book for coursework. This textbook is suitable for students in science and engineering who seek to obtain a comprehensive understanding of different energy processes, and how materials enable energy harvesting, conversion, and storage. In setting forth the latest advances and new frontiers of research, the text also serves as a comprehensive reference on energy materials for experienced materials scientists, engineers, and physicists. Includes pedagogical features such as in-depth side bars, worked-out and end-of- chapter exercises, and many references to further reading Provides comprehensive coverage of materials-based solutions for major and emerging energy systems Brings together diverse subject matter by integrating theory with engaging insights

Preface 1 Materials based solutions to advanced energy systems Abstract 1.1 Advanced energy technology and contemporary issues 1.1.1 Challenges and concerns 1.1.2 The role of the advanced materials 1.1.3 Solutions for future energy systems 1.2 Fundamentals of energy systems 1.2.1 Energy and service 1.2.2 Energy process characterization 1.2.2.1 The laws of thermodynamics 1.2.2.2 Macroscopic and microscopic energy systems 1.2.2.3 Entropy and enthalpy 1.2.2.4 Chemical kinetics 1.2.2.5 Energy availability 1.2.3 Energy calculations and accounting 1.2.3.1 Energy efficiency 1.2.3.2 Heating values 1.2.4 General energy devices 1.2.4.1 Conversion devices 1.2.4.2 Energy storage 1.2.4.3 Systems engineering 1.2.4.4 Electricity 1.2.5 Sustainable energy 1.3 Materials development for advanced energy systems 1.3.1 Functional surface technologies 1.3.2 Materials integration in sustainable energy systems 1.3.3 Higher-performance materials 1.3.4 Sustainable manufacturing of materials 1.3.5 Materials and process development acceleration tools 1.4 Summary Reference Exercises 2 Fundamentals of materials used in energy systems Abstract 2.1 Structures of solids 2.1.1 Atomic structures 2.1.2 Crystal structures 2.1.2.1 Structures for elements 2.1.2.2 Structures for compounds 2.1.2.3 Solid solutions 2.1.3 Crystal diffraction 2.1.3.1 Phase difference and Bragg's law 2.1.3.2 Scattering 2.1.3.3 Reciprocal space 2.1.3.4 Wave vector representation 2.1.4 Defects in solids 2.1.4.1 Point defects 2.1.4.2 Line defects 2.1.4.2.1 Edge dislocations 2.1.4.2.2 Screw dislocations 2.1.4.2.3 Burger's vector and burger circuit 2.1.4.2.4 Dislocation motion 2.1.4.3 Planar defects 2.1.4.3.1 Grain boundaries 2.1.4.3.2 Twin boundaries 2.1.4.4 Three-dimensional defects 2.1.5 Diffusion in solids 2.1.5.1 Atomic theory 2.1.5.2 Random walk 2.1.5.3 Other mass transport mechanisms 2.1.5.3.1 Permeability versus diffusion 2.1.5.3.2 Convection versus diffusion 2.1.5.4 Mathematics of diffusion 2.1.5.4.1 Steady state diffusion 2.1.5.4.2 Non-steady state diffusion 2.1.6 Electronic structure of solids 2.1.6.1 Waves and electrons 2.1.6.1.2 Representation of waves 2.1.6.1.2 Matter waves 2.1.6.1.3 Superposition 2.1.6.1.4 Electron waves 2.1.6.2 Quantum mechanics 2.1.6.3 Electron energy band representations 2.1.6.4 Real energy band structures 2.1.6.5 Other aspects of electron energy band structure 2.2 Phase equilibria 2.2.1 The Gibbs phase rule 2.2.1.1 The phase rule on equilibrium among phases< 2.2.1.2 Applications of the phase rule 2.2.1.3 Construction of phase diagrams 2.2.1.4 The tie line principle 2.2.1.5 The lever rule 2.2.2 Nucleation and growth of phases 2.2.2.1 Thermodynamics of phase transformations 2.2.2.2 Nucleation 2.3 Mechanical properties 2.3.1 Elasticity relationships 2.3.1.1 Ture versus engineering strain 2.3.1.2 Nature of elasticity and Young's Modulus 2.3.1.3 Hook's law 2.3.1.4 Poisson's ratio 2.3.1.5 Normal forces 2.3.2 Plasticity observations 2.3.3 Role of dislocation in deformation of crystalline materials 2.3.4 Deformation of noncrystalline materials 2.3.4.1 Thermal behavior of amorphous solids 2.3.4.2 Time-dependent deformation of amorphous materials 2.3.4.3 Models for network 2.3.4.4 Elastomers 2.4 Electronic properties of materials 2.4.1 Occupation of electronic states 2.4.1.1 Density of states function 2.4.1.2 The Fermi-Dirac distribution function 2.4.1.3 Occupancy of electronic states 2.4.2 Position of the Fermi energy 2.4.3 Electronic properties of metals 2.4.3.1 Free electron theory for electrical conduction 2.4.3.2 Quantum theory of electronic conduction 2.4.3.3 Superconductivity 2.4.4 Semiconductors 2.4.4.1 Intrinsic semiconductors 2.4.4.2 Extrinsic semiconductors 2.4.4.3 Semiconductor measurements 2.4.5 Electrical behavior of organic materials 2.4.6 Junctions and devices and the nanoscale 2.4.6.1 Junctions 2.4.6.1.1 Metal-metal junctions 2.4.6.1.2 Metal-semiconductor junctions 2.4.6.1.3 Semiconductor-semiconductor PN junctions 2.4.6.2 Selected devices 2.4.6.2.1 Passive devices 2.4.6.2.2 Active devices 2.4.6.3 Nanostructures and nanodevices 2.4.6.3.1 Heterojunction nanostructures 2.4.6.3.2 2-D and 3-D nanostructures 2.5 Computational modeling of materials 2.5.1 The challenge of complexity 2.5.2 Materials design with predictive capability 2.5.3 Materials modeling approaches 2.6 Advanced experimental techniques for materials characterization 2.6.1 Dynamic mechanical spectroscopy 2.6.2 Nanoindentation 2.6.3 Light microscopy 2.6.4 Electron microscopy 2.6.5 Atom probe tomography 2.6.6 Advanced X-ray characterization 2.6.7 Neutron scattering 2.7 Integrated materials process control 2.7.1 Process control and its constituents 2.7.1.1 Sensing techniques 2.7.1.2 Input parameters for combustion control 2.7.2 Diagnostic techniques 2.3.2.1 Optical diagnostics 2.3.2.2 Solid-state sensors 2.8 Summary Reference Exercises 3 Advanced materials enable energy production from fossil fuels Abstract 3.1 Materials technology status and challenges in fossil energy systems 3.1.1 Boilers 3.1.2 Steam turbines 3.1.3 Gas turbines 3.1.4 Gasifiers 3.1.5 CO2 capture and storage 3.1.6 Perspectives 3.2 Materials for ultra-supercritical applications 3.2.1 High temperature alloys 3.2.2 Advanced refractory materials for slagging gasifiers 3.2.3 Breakthrough materials 3.3 Coatings and protection materials for steam system 3.3.1 High temperature and high pressure coatings 3.3.2 Oxygen ion selective ceramic membranes for carbon capture 3.4 Materials for deep oil and gas well drilling and construction 3.4.1 High stress and corrosion resistant propping agents 3.4.2 Erosion- and corrosion-resistant coatings 3.4.3 Wear resistant coatings 3.4.4 High strength and corrosion resistant alloys for use in well casings and deep well drill pipe 3.5 Materials for sensing in harsh environments References Exercises 4 Materials-based solutions to solar energy system Abstract 4.1 Solar energy technologies 4.1.1 Photovoltaic technologies 4.1.1.1 Residential photovoltaic 4.1.1.2 Utility-scale flat-plate thin film photovoltaic 4.1.1.3 Utility-scale photovoltaic concentrators 4.1.2 Solar thermal technologies 4.1.2.1 Unglazed collectors 4.1.2.2 Glazed collectors 4.1.2.3 Parabolic trough 4.1.2.4 Vacuum tube collectors 4.1.2.5 Linear Fresnel lens reflectors 4.1.2.6 Solar Stirling engine 4.2 Photovoltaic materials and devices 4.2.1 Crystalline silicon PV cells 4.2.1.1 Mono-crystal silicon PVs 4.2.1.2 Polycrystalline silicon PVs 4.2.1.3 Emitter wrap-through cells 4.2.2 Thin-film PV cells 4.2.2.1 Amorphous Silicon Cells 4.2.2.1.1 Amorphous-Si, double or triple junctions 4.2.2.1.2 Tandem amorphous-Si and multi-crystalline-Si 4.2.2.2 Ultra-thin silicon wafers 4.2.2.3 Cadmium telluride and cadmium sulphide 4.2.2.4 Copper indium selenide and copper indium gallium selenide 4.2.3 Compound semiconductor PV cells 4.2.3.1 Space PV cells 4.2.3.2 Light absorbing dyes 4.2.3.3 Organic and polymer PV 4.2.3.4 Flexible plastic organic transparent cells 4.2.4 Nanotechnology for PV cell fabrication 4.2.4.1 Silicon nanowires 4.2.4.2 Carbon nanotubes 4.2.4.3 Graphene-based solar cells 4.2.4.4 Quantum dots 4.2.4.5 Hot carrier solar cell 4.2.4.6 Nanoscale surfaces reduce reflection and increase capture of the full spectrum of sunlight 4.2.5 Hybrid solar cells 4.2.5.1 Hybrid organic-metal PVs 4.2.5.2 Hybrid organic-organic PVs 4.2.6 Inexpensive plastic solar cells or panels that are mounted on curved surfaces 4.3 Advanced materials for solar thermal collectors 4.3.1 Desirable features of solar thermal collector materials 4.3.1.1 Transparent cover 4.3.1.2 Insulation 4.3.1.3 Evacuated-tube collectors 4.3.2 Polymer materials in solar thermal collectors 4.3.3 Corrosion resistant materials in contact with molten salts 4.4 Reflecting materials for solar cookers 4.5 Optical materials for absorbers 4.5.1 Metals 4.5.2 Selective coatings 4.5.2.1 Intrinsic absorption coatings 4.5.2.2 Semiconductor-metal tandems 4.5.2.3 Multilayer absorbers 4.5.2.4 Metal-dielectric composite coatings 4.5.2.5 Surface texturing 4.5.2.6 Selectively solar-transmitting coating on a blackbody-like absorber 4.5.3 Heat pipes 4.5.4 Metamaterial solar absorbers 4.5.4.1 Metal-dielectric nanocomposites with tailored plasmonic response 4.5.4.2 Light weight broadband nanocomposite perfect absorbers 4.3.4.3 Prospects and future trends 4.6 Thermal energy storage materials 4.6.1 Sensible thermal energy storage 4.6.2 Underground thermal energy storage 4.6.3 Phase change materials 4.6.4 Thermal energy storage via chemical reactions Reference Exercises 5 Advanced materials enable renewable geothermal energy capture and generation Abstract 5.1 Geothermal technologies 5.1.1 Geothermal resources for geothermal energy development 5.1.2 Geothermal electricity 5.1.3 Enhanced geothermal systems and other advanced geothermal technologies 5.1.4 Direct use of geothermal energy 5.2 Hard materials for downhole rock drilling 5.3 Advanced cements for geothermal wells 5.4 Geothermal heat pumps 5.4.1 Pumping materials 5.4.2 Pumping technology 5.4.3 Heat pump applications 5.5 Materials for transmission pipelines and distribution netorks 5.6 Materials for heat exchange systems 5.6.1 Heat exchange fluids 5.6.2 Heat exchanger coatings 5.6.3 Polymer heat exchangers 5.6.4 Heat convector materials 5.6.5 Refrigeration materials for cooling systems 5.7 Corrosion protection and material selection for geothermal systems Reference Exercises 6 Advanced materials enable renewable wind energy capture and generation Abstract 6.1 Wind resources 6.1.1 Wind quality 6.1.2 Variation of wind speed with elevation 6.1.3 Air density 6.1.4 Wind forecasting 6.1.5 Offshore wind 6.1.6 Maximum wind turbine efficiency: The Betz ratio 6.2 Materials requirements of wind machinery and generating systems 6.2.1 Driven components 6.2.1.1 Shafts 6.2.1.2 Bearings 6.2.1.3 Couplings 6.2.1.4 Gear boxes 6.2.1.5 Generators 6.2.2 Tower 6.2.2.1 Tower structure 6.2.2.2 Tower flange 6.2.2.3 Power electronics 6.2.3 Rotor 6.2.3.1 Blade 6.2.3.2 Blade extender 6.2.3.3 Hub 6.2.3.4 Pitch drive 6.2.4 Nacelle 6.2.4.1 Case 6.2.4.2 Frame 6.2.4.3 Anemometer 6.2.4.4 Brakes 6.2.4.5 Controller 6.2.4.6 Convertor 6.2.4.7 Cooling system 6.2.4.8 Sensors 6.2.4.9 Yaw drive 6.2.5 Balance-of-station subsystems 6.2.6 System design challenges 6.3 Wind turbine types and structures 6.3.1 Horizontal-axis wind turbines 6.3.2 Vertical-axis wind turbines 6.3.3 Upwind wind turbines and downwind wind turbines 6.3.4 Darrieus turbines 6.3.5 Savonius turbines 6.3.6 Giant Multi-megawatt turbines 6.4 General materials used in wind turbines 6.4.1 Cast iron and steel 6.4.2 Composite materials 6.4.3 Rare earth elements in magnet 6.4.4 Copper 6.4.5 Reinforced concrete 6.5 Light weight composite materials for wind turbine blades 6.5.1 Reinforcement 6.5.2 Matrix 6.6 Smart and stealth wind turbine blade materials 6.7 Permanent-magnet generators for wind turbine applications 6.8 Future prospects Reference Exercises 7 Advanced materials for ocean energy and hydropower 7.1 Materials requirements for ocean energy technologies 7.1.1 Tidal power 7.1.2 Ocean current 7.1.3 Wave energy 7.1.4 Ocean thermal energy 7.1.5 Salinity gradient 7.2 Advanced materials and devices for ocean energy 7.2.1 Structure & prime mover 7.2.2 Foundations & moorings 7.2.3 Power take off 7.2.4 Control 7.2.5 Installation 7.2.6 Connection 7.2.7 Operations & maintenance 7.3 Wave energy converters 7.3.1 Types of WEC 7.4 Tidal energy converters 7.4.1. Types of TEC 7.4.2. Further Permutations 7.5 Arrays 7.6 Challenges faced by the ocean energy 7.6.1 Predictability 7.6.2 Manufacturability 7.6.3 Installability 7.6.4 Operability 7.6.5 Survivability 7.6.6 Reliability 7.6.7 Affordability 7.7 Materials requirements for hydropower system 7.7.1 Retaining structure materials for dams and dikes 7.7.2 Structural materials and surface coatings for turbines runners, draft tubes and penstocks Reference Exercises 8 Biomass for bioenergy 8.1 Materials requirements for biomass technologies 8.1.1 Biomass for power and heat 8.1.2 Biogas 8.1.3 Biofuels 8.1.4 Biorefineries 8.2 Corrosion resistant materials for biofuels 8.2.1 Metal and its alloys 8.2.2 Elastomers 8.3 Nanocatalysts for conversion of biomass to biofuel 8.3.1 Nanocatalysts for biomass gasification 8.3.2 Nanocatalysts for biomass liquefaction 8.4 Coal-to-liquid fuels 8.4.1 Basic chemistry 8.4.2 CTL technology options 8.5 Materials for combustion processes 8.6 Materials for capturing CO2 for using as a nutrient to cultivate alga 8.7 Materials for water filtration and desalination Reference Exercises 9 Hydrogen and fuel cells 9.1 Introduction 9.2 Hydrogen generation technology 9.2.1 Steam methane reforming 9.2.2 Electrolysis 9.3 Hydrogen conversion and storage technology 9.3.1 Fuel cells 9.3.2 Hydrogen gas turbines 9.3.3 Compressed hydrogen gas 9.3.4 Liquid hydrogen storage in tanks 9.3.5 Physisorption of hydrogen and its storage in solid structures 9.4 Materials-based hydrogen storage 9.4.1 Nanoconfined hydrogen storage materials 9.4.2 Complex hydrides 9.4.3 Reversible hydrides 9.4.4 Hydrogen storage in carbonaceous materials 9.4.5 Hydrogen storage in zeolites and glass microspheres 9.4.6 Hydrogen storage in organic frameworks 9.4.7 Hydrogen Storage in Polymers 9.4.8 Hydrogen storage in formic acid 9.5 Fuel cell materials 9.5.1 Anode Materials 9.5.2 Cathode Materials 9.5.3 Electrolytes 9.5.4 Catalysts (Catalysts for the oxygen reduction reaction) 9.5.5 Sputtering Targets 9.5.6 Current Collectors (Higher-temperature proton conducting materials) 9.5.7 Support Materials (Low-cost materials resistant to hydrogen-assisted cracking and embrittlement) 9.6 Applications of fuel cells 9.6.1 Alkaline Fuel Cells 9.6.2 Proton Exchange Membrane Fuel Cells 9.6.3 Direct Methanol Fuel Cells 9.6.4 Phosphoric Acid Fuel Cells 9.6.5 Molten Carbonate Fuel Cells 9.6.6 Solid Oxide Fuel Cells 9.6.7 Solid oxide fuel cells 9.6.8 Polymer electrolyte membrane fuel cells Reference Exercises 10 Role of materials to advanced nuclear energy Abstract 10.1 Fission and fusion technologies 10.1.1 Nuclear reactors 10.1.2 Nuclear power fuel resources (fuel cycle) 10.1.3 Fusion energy 10.1.3.1 Magnetic fusion energy 10.1.3.2 Inertial fusion energy 10.2 Materials selection criteria 10.2.1 General considerations 10.2.2 General mechanical properties 10.2.2.1 Fabricability 10.2.2.2 Dimension stability 10.2.2.3 Corrosion resistance 10.2.2.4 Heat transfer properties 10.2.3 Special considerations 10.2.3.1 Neutronic properties 10.2.3.2 Susceptibility to induced radioactivity 10.2.3.3 Radiation stability 10.3 Materials for reactor components 10.3.1 Structure and fuel cladding materials 10.3.1.1 Advanced radiation resistant structural materials 10.3.1.1.1 Ultrahigh strength alloys 10.3.1.1.1 Ultrahigh toughness ceramic composites 10.3.1.2 Advanced refractory, ceramic, graphitic or coated materials 10.3.1.3 Corrosion and damage resistant materials 10.3.1.4 Pressure vessel steel 10.3.1.4.1 Corrosion resistant nickel base alloys 10.3.1.4.2 Dimensionally stable zirconium fuel cladding 10.3.1.5 Ultra high temperature resistance structural materials 10.3.2 Moderators and reflectors 10.3.3 Control materials 10.3.4 Coolants 10.3.5 Shielding materials 10.4 Nuclear fuels 10.4.1 Metallic fuels 10.4.2 Ceramic fuels 10.5 Cladding materials ^ Zirconium-based cladding 3-14 10.5.2 Iron-based cladding 3-19 10.5.3 Advanced gas-cooled reactor cladding 3-19 10.6 Low energy nuclear reactions in condensed matter 10.7 Advanced computational materials performance modeling References Exercises 11. Emerging materials for energy harvesting 11. 1 Introduction 11.2 Thermoelectric Materials 11.2.1 Characterizations of thermoelectric Materials 11.2.2 Structures Oxides and Silicides Half-Heusler compounds Skutterudite Materials Clatherate Materials 11.2.3 Properties Thermal Conductivity Fermi Surface Morphology 11.2.4 Nano-materials 11.2.5 Applications 11.3 Piezoelectric Materials 11.3.1 Fundamentals of piezoelectricity 11.3.2 Equivalent circuit of a piezoelectric harvester 11.3.4 Advances of piezoelectric materials Ceramics Single crystals Polymers Composites 11.3.5 Energy harvesting piezoelectric devices 11.3.6 Applications 11.4 Pyroelectric materials 11.4.1 The pyroelectric effect 11.4.2 Types of pyroelectric materials 11.4.3 Pyroelectric cycles for energy harvesting 11.4.4 Pyroelectric harvesting devices 11.4.5 Applications 11.5 Magnetic Induction system 11.5.1 Architecture and Operational Mechanism 11.5.2 Magnet-through-coil Induction 11.5.2.1 Geometry 11.5.2.2 Magnetic flux Generated by the Bar Magnet 11.5.2.3 Coil Inductance and Resistance 11.5.2.4 Voltage and Power Generation 11.5.3 Magnet-across-coils Induction 11.5.3.1 Geometry 11.5.3.2 Magnetic Field Generated by the Magnets 11.5.3.3 Magnetic Field Generated by Coil Current 11.5.3.4 Coil Self-Inductance, Mutual Inductance, and Resistance 11.5.3.5 Voltage and Power Generation 11.5.4 Magnetic materials 11.5.5 Magnetic devices 11.5.6 Applications 11.6 Mechanoelectric energy harvesting materials References Exercises 12 Perspectives and future trends 12.1 Sustainability 12.1.1 Efficient use of energy-intensive materials 12.1.2 Retention of strategic materials 12.1.3 Extraction technologies to recycle strategic materials 12.1.4 Green manufacturing and energy production processes 12.1.5 Mitigation of negative impacts of energy technology and economic growth 12.2 Metamaterials and nanomaterials for energy systems 12.3 Artificial photosynthesis 12.4 Structural power composites 12.5 Future energy storage materials 12.6 Hybrid Alternative Energy Systems 12.6.1 Combining alternative energy components 12.6.2 Uses for hybrid energy systems 12.6.3 Solar and wind power combinations 12.6.4 Pumped-storage and wind generated hydroelectricity 12.6.5 Harvesting zero-point energy from the vacuum 12.6.6 Combined energy harvesting techniques Reference Exercises