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1. | EXECUTIVE SUMMARY |
1.1. | Alternative fuel scope |
1.2. | Energy consumption by sector |
1.3. | Routes to decarbonisation |
1.4. | Biofuel generations |
1.5. | Biofuel incentives |
1.6. | US Renewable identification numbers |
1.7. | Challenges for biofuel |
1.8. | Renewable diesel capacity distribution |
1.9. | Future renewable diesel capacity distribution |
1.10. | Renewable diesel market regional growth |
1.11. | Renewable diesel forecast |
1.12. | Advanced biofuels technology overview |
1.13. | Biofuel technology overview |
1.14. | Fast pyrolysis and gasification-FT project examples |
1.15. | Introduction to biojet and sustainable aviation fuel |
1.16. | Bio-jet/SAF process pathways |
1.17. | Announcements during 2020 |
1.18. | Sustainable aviation fuel incentives |
1.19. | SAF demand forecast, billion litres |
1.20. | SAF demand forecast, billion $ |
1.21. | Concluding remarks on SAF |
1.22. | Green ammonia development stage |
1.23. | Green ammonia project volumes |
1.24. | Ammonia shipping project list |
1.25. | e-fuel production pathway overview |
1.26. | e-fuels |
1.27. | Routes to e-fuel production |
1.28. | e-fuel players |
1.29. | e-fuel capacity announcements |
1.30. | Applications for e-fuels |
1.31. | Comparing low-carbon solutions |
1.32. | Non-fossil alternative fuel development stages |
1.33. | Comparing alternative fuels |
1.34. | Comparing alternative fuels - SWOT |
1.35. | Biofuel supply chain |
1.36. | E-fuel supply chain |
1.37. | Low carbon sustainability trade-offs |
2. | INTRODUCTION |
2.1. | Global emissions driving temperature increase |
2.2. | Energy consumption by sector |
2.3. | Energy consumption in transportation |
2.4. | Transport emissions |
2.5. | Energy consumption in industry |
2.6. | Industrial energy requirements |
2.7. | Residential energy consumption |
2.8. | Residential heating demand - UK example |
2.9. | Routes to decarbonisation |
2.10. | Green credentials of decarbonisation options |
3. | OVERVIEW OF BIOFUELS |
3.1.1. | Role of biofuels |
3.1.2. | Biofuel cycle |
3.1.3. | Biofuel generations |
3.1.4. | Defining advanced and renewable fuels |
3.1.5. | Biofuel incentives |
3.1.6. | US Renewable identification numbers |
3.1.7. | US RIN prices 2020 |
3.1.8. | Drivers of US growth in renewable diesel |
3.1.9. | EU biofuel targets |
3.1.10. | EU biofuel sustainability |
3.1.11. | Challenges for biofuel |
3.1.12. | Current state of biofuels - USA |
3.1.13. | Current state of biofuels - Europe |
3.1.14. | Current state of biofuels - Brazil |
3.1.15. | Current state of biofuels - China, Indonesia |
3.1.16. | Opportunity and threat for on-road transport |
3.1.17. | 1st generation bioethanol |
3.1.18. | Conventional biodiesel |
3.2. | Advanced biofuels |
3.2.1. | 2nd generation biofuel production processes |
3.2.2. | Biofuel production process developments |
3.2.3. | Biofuel technology overview |
3.2.4. | Gasification-FT project examples |
3.2.5. | Fast pyrolysis and hydrothermal gasification project examples |
3.2.6. | Gasification to Fischer-Tropsch projects |
3.2.7. | Redrock Biofuels |
3.2.8. | Velocys |
3.2.9. | Fulcrum Bioenergy |
3.2.10. | Silva Green Fuel |
3.2.11. | Bio2Oil |
3.2.12. | Gevo |
3.2.13. | Introduction to biogas |
3.2.14. | Algae based biofuels |
3.3. | Renewable diesel market |
3.3.1. | Renewable diesel introduction |
3.3.2. | Biodiesel and bio-jet fuel |
3.3.3. | Bio- and renewable diesel production |
3.3.4. | Renewable diesel production |
3.3.5. | Renewable diesel market expansion |
3.3.6. | Renewable diesel market regional growth |
3.3.7. | Renewable diesel market regional shares |
3.3.8. | Renewable diesel market expansion - hydroprocessing |
3.3.9. | Renewable diesel capacity distribution |
3.3.10. | Future renewable diesel capacity distribution |
3.3.11. | Eni SpA - Honeywell |
3.3.12. | Neste |
3.3.13. | Neste case study |
3.3.14. | Renewable diesel forecast |
3.3.15. | Renewable diesel forecast - UCO availability |
3.3.16. | Opportunity for renewable diesel |
3.4. | Sustainable aviation fuels market |
3.5. | Energy consumption in aviation |
3.6. | Bio-jet and sustainable aviation fuels |
3.7. | Biofuels key to aviation decarbonisation |
3.8. | Aviation fuel demand |
3.9. | Impact of covid-19 |
3.10. | Announcements during 2020 |
3.11. | CO2 reduction measures |
3.12. | CORSIA |
3.13. | SAF certification process |
3.14. | Introduction to biojet and sustainable aviation fuel |
3.15. | Jet fuel composition |
3.16. | Biodiesel and bio-jet fuel |
3.17. | Overview of bio-jet fuel production pathways |
3.18. | Overview of bio-jet fuel feedstocks and production |
3.19. | bio-jet/SAF process pathways |
3.20. | SAF from P2X |
3.21. | Sustainable aviation fuel incentives |
3.22. | Commercial initiatives |
3.23. | Covid-19 vs Green Recovery |
3.24. | SAF market |
3.25. | Sustainable aviation fuel offtake agreements |
3.26. | Production capacity by process pathway |
3.27. | SAF production growth by process |
3.28. | Price |
3.29. | SAF production cost |
3.30. | Concluding remarks on SAF |
3.31. | Jet fuel demand extrapolation and capacity |
3.32. | SAF demand forecast, billion litres |
3.33. | SAF demand forecast- billion $ |
4. | ELECTRO-FUELS (E-FUELS) |
4.1. | Introduction to e-fuels |
4.2. | Point source CO2 capture |
4.3. | What is Direct Air Capture (DAC)? |
4.4. | Methods of DAC |
4.5. | Challenges associated with DAC technology |
4.6. | Electro-fuel production technology |
4.7. | e-fuel production pathway overview |
4.8. | Types of e-fuel |
4.9. | Routes to e-fuel production |
4.10. | e-fuel production technologies |
4.11. | Routes to e-fuel production |
4.12. | Introduction to fuel cells |
4.13. | Fuel cell and electrolyser overview |
4.14. | Electrolysis for power-to-X |
4.15. | Electrolyser basics |
4.16. | Electrolyser overview |
4.17. | Introduction to solid oxide electrolysers |
4.18. | Materials for solid-oxide electrolysers and fuel cells |
4.19. | Interest in SOECs |
4.20. | SOEC syngas production |
4.21. | Sunfire Fuel Cells Gmbh Power-to-liquid |
4.22. | Flexible SOEC operation? |
4.23. | Haldor Topsoe |
4.24. | Electrolyser degradation |
4.25. | Solid oxide electrolyser cell players |
4.26. | Room-temperature electrochemical CO2 reduction |
4.27. | Electrochemical CO2 reduction products |
4.28. | E-fuel players and market overview |
4.29. | Nordic Blue Crude |
4.30. | Synhelion solar fuel |
4.31. | Prometheus fuels |
4.32. | Prometheus fuels process |
4.33. | Carbon Engineering |
4.34. | Carbon Recycling International |
4.35. | Opus 12 |
4.36. | Opus 12 technology |
4.37. | Caphenia |
4.38. | Lectrolyst |
4.39. | Copernicus P2X and MefCO2 projects |
4.40. | Siemens - Evonik P2X pilot |
4.41. | Audi synthetic fuel |
4.42. | SAF from P2X |
4.43. | e-fuel players |
4.44. | e-fuel capacity announcements |
4.45. | Electrolyser/fuel cell manufacturers |
4.46. | Applications for e-fuels |
4.47. | e-fuel applications remarks |
4.48. | Evaluating the role of e-fuels |
5. | GREEN AMMONIA |
5.1. | Introduction to hydrogen and ammonia |
5.2. | Ammonia production |
5.3. | Reverse ammonia fuel cell |
5.4. | Hydrogen or ammonia economy |
5.5. | Green ammonia |
5.6. | Efficiency of using ammonia |
5.7. | Ammonia as energy storage |
5.8. | Ammonia as a combustion fuel |
5.9. | Ammonia fuelled gas turbine |
5.10. | Co-firing ammonia in Japan |
5.11. | Ammonia for fuel cells |
5.12. | Direct ammonia fuel cells |
5.13. | Ammonia projects and outlook |
5.14. | FREA ammonia demonstration plant |
5.15. | Siemens' green ammonia demonstrator |
5.16. | ThyssenKrupp/H2U green ammonia demonstrator |
5.17. | Nel alkaline electrolyser cost reduction |
5.18. | Green ammonia nitrate |
5.19. | Green ammonia project volumes |
5.20. | Green ammonia projects |
5.21. | Large-scale green ammonia production |
5.22. | Green ammonia development stage |
5.23. | Evaluating the role of ammonia |
5.24. | Evaluating ammonia |
5.25. | Alternative fuel comparisons |
6. | GREEN AMMONIA FOR SHIPPING |
6.1. | Role of alternative fuels in transport |
6.2. | Zero emission shipping |
6.3. | Why green ammonia for maritime? |
6.4. | Ammonia in the news |
6.5. | Shipping emissions: the problem |
6.6. | Introduction to marine emissions regulation |
6.7. | SOx reductions more important than NOx |
6.8. | CO2 target for shipping |
6.9. | CO2 in shipping forecast |
6.10. | Timeline of regulatory developments |
6.11. | Maritime electrification |
6.12. | Why batteries can help |
6.13. | Fuel cost savings and ROI |
6.14. | Roadblocks to maritime electrification |
6.15. | Equinor-Eidesvik Offshore ammonia fuel cell vessel |
6.16. | Ammonia for shipping |
6.17. | MAN Energy Solutions 2-stroke engine |
6.18. | IHI corporation - LNG fuelled tugboat |
6.19. | Ammonia shipping project list |
6.20. | LNG in shipping |
6.21. | Environmental benefit of LNG |
6.22. | Hydrogen, ammonia or bio-LNG |
6.23. | Ammonia or bio-LNG for shipping |
7. | CONSIDERING SUSTAINABILITY |
7.1. | Underlying Drivers for Electric Vehicles |
7.2. | Sustainability of biofuels |
7.3. | Emissions from land use change |
7.4. | Fuel carbon intensity comparison per MJ |
7.5. | Fuel carbon intensity comparisons per km |
7.6. | Land use emissions from biofuel generations |
7.7. | Biofuel carbon emissions |
7.8. | Carbon emissions from electric vehicles |
7.9. | Sustainability of Li-ion materials |
7.10. | Low carbon sustainability trade-offs |
7.11. | Comparing low-carbon solutions |
슬라이드 | 271 |
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전망 | 2031 |
ISBN | 9781913899332 |