This document surveys potential future energy sources that could supply large amounts of carbon emission-free energy to stabilize global climate change. It analyzes options like solar, wind, biomass, nuclear fission, nuclear fusion, fossil fuels with carbon sequestration, hydrogen production and storage, and geoengineering. However, it concludes that currently all these approaches have deficiencies that limit their ability to stabilize the climate and that intensive research is urgently needed to develop technological options that allow both climate stabilization and economic development.
This document summarizes a paper that investigates opportunities for sustainable energy production in Norway using a system dynamics model. The paper finds that developing offshore wind power for the European energy market could help Norway address future declines in oil and gas revenues and create new industries. The system dynamics model accounts for feedback loops and path dependence in the global energy system and finds that policies are needed to shift the dominant feedback loops from fossil fuels to renewable energy sources like wind power to establish a sustainable energy future.
PRESS RELEASE
Potential of Renewable Energy Outlined in Report by the
Intergovernmental Panel on Climate Change
Experts Underline Significant Future Role in Cutting Greenhouse Gas Emissions and
Powering Sustainable Development
Over 160 Scenarios on the Potential of six Renewable Energy Technologies Reviewed by
Global Team of Technological Experts and Scientists
11
th
Session of Working Group III
The Coupled Climate-Energy System: Limiting Global Climatic Disruption by Rev...Larry Smarr
10.07.23
Invited Seminar
National Center for Atmospheric Research (NCAR)
Title: The Coupled Climate-Energy System: Limiting Global Climatic Disruption by Revolutionary Change in the Global Energy System
Boulder, CO
Renewable Energy final paper, Cordell-Hedin-KrahenbuhlPancakes
This document discusses arguments for and against public policy support for renewable energy based on the economic theory of externalities. It summarizes key points regarding external costs of fossil fuels like health impacts and environmental damage. It also outlines challenges for renewable energy scale-up including high upfront capital costs, issues with intermittency, and land use requirements. Examples of policies to address externalities like cap-and-trade programs in California are provided. The importance of accounting for externalities to incentivize a transition to renewable energy is a major theme.
Digital Transformations Over the Next Decade in Energy and the EnvironmentLarry Smarr
11.10.04
The New Science of Management in a Rapidly Changing World
PwC's DiamondExchange
Title: Digital Transformations Over the Next Decade in Energy and the Environment
Tucson, AZ
This report compares nuclear and wind energy as potential options for Texas to invest in as the first step towards transitioning to 100% sustainable energy production by 2050. The report evaluates the two options based on three criteria: environmental impact, economics, and ability for large-scale implementation. With regards to environmental impact, the report finds that wind power produces 87% less CO2 emissions, takes up 48% less land, and consumes 99% less water than nuclear power. For economics, the report finds that wind power facilities cost 20% less to build and run, take 79% less time to develop and construct, and receive much greater investment than nuclear power. Finally, for large-scale implementation potential, the report finds that while
Global Climatic Disruption and its Impact on Victoria and CaliforniaLarry Smarr
The document summarizes the potential impacts of climate change on Victoria, Australia and California, focusing on water resources and wildfires. It outlines that global greenhouse gas emissions continue to rise and discusses the radical changes needed to the world's energy system to prevent global temperature increases exceeding 2 degrees Celsius above pre-industrial levels. Specifically, global CO2 emissions would need to peak before 2015 and achieve near-zero emissions in energy and transport sectors by 2050.
The document discusses renewable energy readiness in Nigeria. It finds that while Nigeria has abundant renewable resources like solar, wind, and hydro, current utilization is still low apart from large hydro projects. Projections show electricity demand rising dramatically by 2030. Meeting this demand will require major investment that the government cannot provide alone. The document recommends encouraging private sector investment and developing renewables on a large scale. Key agencies in Nigeria like REA and NERC are working to promote mini-grids and a supportive regulatory environment to develop renewable energy.
This document summarizes a paper that investigates opportunities for sustainable energy production in Norway using a system dynamics model. The paper finds that developing offshore wind power for the European energy market could help Norway address future declines in oil and gas revenues and create new industries. The system dynamics model accounts for feedback loops and path dependence in the global energy system and finds that policies are needed to shift the dominant feedback loops from fossil fuels to renewable energy sources like wind power to establish a sustainable energy future.
PRESS RELEASE
Potential of Renewable Energy Outlined in Report by the
Intergovernmental Panel on Climate Change
Experts Underline Significant Future Role in Cutting Greenhouse Gas Emissions and
Powering Sustainable Development
Over 160 Scenarios on the Potential of six Renewable Energy Technologies Reviewed by
Global Team of Technological Experts and Scientists
11
th
Session of Working Group III
The Coupled Climate-Energy System: Limiting Global Climatic Disruption by Rev...Larry Smarr
10.07.23
Invited Seminar
National Center for Atmospheric Research (NCAR)
Title: The Coupled Climate-Energy System: Limiting Global Climatic Disruption by Revolutionary Change in the Global Energy System
Boulder, CO
Renewable Energy final paper, Cordell-Hedin-KrahenbuhlPancakes
This document discusses arguments for and against public policy support for renewable energy based on the economic theory of externalities. It summarizes key points regarding external costs of fossil fuels like health impacts and environmental damage. It also outlines challenges for renewable energy scale-up including high upfront capital costs, issues with intermittency, and land use requirements. Examples of policies to address externalities like cap-and-trade programs in California are provided. The importance of accounting for externalities to incentivize a transition to renewable energy is a major theme.
Digital Transformations Over the Next Decade in Energy and the EnvironmentLarry Smarr
11.10.04
The New Science of Management in a Rapidly Changing World
PwC's DiamondExchange
Title: Digital Transformations Over the Next Decade in Energy and the Environment
Tucson, AZ
This report compares nuclear and wind energy as potential options for Texas to invest in as the first step towards transitioning to 100% sustainable energy production by 2050. The report evaluates the two options based on three criteria: environmental impact, economics, and ability for large-scale implementation. With regards to environmental impact, the report finds that wind power produces 87% less CO2 emissions, takes up 48% less land, and consumes 99% less water than nuclear power. For economics, the report finds that wind power facilities cost 20% less to build and run, take 79% less time to develop and construct, and receive much greater investment than nuclear power. Finally, for large-scale implementation potential, the report finds that while
Global Climatic Disruption and its Impact on Victoria and CaliforniaLarry Smarr
The document summarizes the potential impacts of climate change on Victoria, Australia and California, focusing on water resources and wildfires. It outlines that global greenhouse gas emissions continue to rise and discusses the radical changes needed to the world's energy system to prevent global temperature increases exceeding 2 degrees Celsius above pre-industrial levels. Specifically, global CO2 emissions would need to peak before 2015 and achieve near-zero emissions in energy and transport sectors by 2050.
The document discusses renewable energy readiness in Nigeria. It finds that while Nigeria has abundant renewable resources like solar, wind, and hydro, current utilization is still low apart from large hydro projects. Projections show electricity demand rising dramatically by 2030. Meeting this demand will require major investment that the government cannot provide alone. The document recommends encouraging private sector investment and developing renewables on a large scale. Key agencies in Nigeria like REA and NERC are working to promote mini-grids and a supportive regulatory environment to develop renewable energy.
Alternative Electric Power Plant that Environmental Friendliness at Indonesiainventy
Research Inventy : International Journal of Engineering and Science is published by the group of young academic and industrial researchers with 12 Issues per year. It is an online as well as print version open access journal that provides rapid publication (monthly) of articles in all areas of the subject such as: civil, mechanical, chemical, electronic and computer engineering as well as production and information technology. The Journal welcomes the submission of manuscripts that meet the general criteria of significance and scientific excellence. Papers will be published by rapid process within 20 days after acceptance and peer review process takes only 7 days. All articles published in Research Inventy will be peer-reviewed.
This document discusses planning for energy needs in 2030. It notes that global energy supplies are finite, populations and energy demands are growing, and some energy sources contribute to climate change and pollution. The document examines current and projected contributions of various energy sources like oil, coal, natural gas, and nuclear. It also discusses how long current reserves may last given consumption rates. The document proposes that to address these issues, the plan for 2030 should reduce energy demands through efficiency, educate the public, and diversify energy supplies by developing new technologies, utilizing regional strengths for sources like solar and wind, and reducing reliance on imported oil.
The document discusses global and Indian energy scenarios. It provides information on world energy resources including oil, natural gas, coal and uranium reserves. It notes that 87% of global primary energy supply comes from non-renewable sources. It also discusses India's energy consumption and production, noting that India is the third largest coal producer and consumer of electricity. However, per capita energy consumption in India remains low compared to other countries. The document outlines issues with fossil fuel dependence such as climate change, environmental hazards, and accidents. It describes the impacts of climate change such as extreme weather, sea level rise, and species extinction.
This document discusses natural gas, including its uses, top consuming states, and advantages over coal for power generation. It also summarizes the differences between conventional and unconventional natural gas sources like shale gas, where gas is primarily located in the US, and technologies like fracking that have increased shale gas production. While this has economic and security benefits, fracking raises environmental concerns. The document concludes that increased global natural gas production depends on factors like environmental regulations, climate policy, fuel prices, and production costs.
This document provides an overview of a course on sustainable energy that aims to equip teachers to discuss complex issues around energy and climate change. The course covers motivations for changing energy production, including finite fossil fuel resources, energy security concerns, and the environmental impacts of climate change. It outlines sessions that will discuss energy consumption trends, various renewable and non-renewable technology options, and developing balanced future energy plans.
The document discusses a student's independent study project on hydraulic fracturing (fracking) under Professor Gautier. The project aims to scrutinize the fracking industry and examine methane leakage during the extraction process. There has been little research on this issue so far. One reason public awareness is lacking is the dramatic expansion of fracking in the US in recent years. The student summarizes various perspectives on the costs and benefits of fracking from academics and industry reports. Overall, the document expresses concerns that fracking poses serious risks for accelerating climate change due to methane leakage and for displacing cleaner energy alternatives.
The Global Energy Challenges on Role Of Nuclear Energy and Climate ChangeMahfuzur Rahman Titu
The document summarizes the objectives and key topics discussed at the 5th International Conference on Mechanical Engineering and Renewable Energy (ICMERE-2019). The conference focused on studying current global energy consumption and the role of different energy sources like fossil fuels, nuclear power, and renewables. It discussed challenges like meeting increasing demand through low-cost and low-carbon sources. Presentations analyzed energy resources, generation and consumption trends over time for different fuels. The impact of various energy sources on climate change and their economic costs were also evaluated. The conference emphasized the need for sustainable energy solutions to address future challenges.
The document discusses global warming and the greenhouse effect, noting that rising levels of greenhouse gases like carbon dioxide, methane, and nitrous oxide in the atmosphere are enhancing this effect. It provides two graphs showing increasing CO2 levels in the atmosphere since 1960. It then outlines 50 years of international climate policy efforts, and findings from the IPCC and others that greenhouse gas emissions must be reduced to avoid significant warming and sea level rise in the coming decades. It also discusses actions being taken by states, cities, and regions to cut emissions through targets and plans in the absence of federal policy.
The document discusses renewable energy sources and provides an overview of solar energy as one of the mainstream technologies. It explains that solar energy comes from the sun's radiant light energy and can be used to produce heat, light, and electricity through solar power systems. There are two main methods - one uses solar thermal technology to heat water and produce steam to generate electricity, similar to fossil fuel plants, while the other uses large photovoltaic cell arrays to directly convert sunlight into electricity at high voltages and currents. Solar power is a renewable resource as the sun provides energy constantly. Home solar power systems commonly use photovoltaic panels to harness the sun's energy and convert it to electricity.
This report analyzes the long-term outlook for non-fossil energy technologies in 2050 and beyond. Several key points are made:
- Significant reductions in greenhouse gas emissions are needed by 2050 to keep global warming below 2°C. Relying only on energy sector options may not be sufficient in Europe.
- Many renewable technologies like solar, wind, hydropower, and bioenergy have the potential to play a major role in the global energy supply by 2050. Technologies like geothermal and wave energy also show promise.
- Energy storage technologies will be important for integrating variable renewable resources into the grid and providing energy for transportation. However, energy storage is often costly.
- Nuclear
FINAL SUBMITTED PAPER-TRENDS IN RENEWABLE ENERGY RESOURES AND THEIR APPLICATIONSNavneet Agarwal
This document discusses trends in renewable energy resources and their applications, specifically in developing countries. It provides an overview of various renewable resources like hydroelectric, biomass, wind, solar, and geothermal energy. The current dominance of fossil fuels is described along with projections that they will be depleted. Renewable resources are gaining importance due to benefits like energy price stability, reduced air pollution, protecting the climate, and providing unlimited supplies. Recent growth and investments in renewable energy are also discussed. The conclusion emphasizes the environmental and economic benefits of transitioning to renewable sources.
This document discusses renewable energy resources and energy efficiency. It provides an overview of different renewable energy sources like solar, wind, hydroelectric, biomass and geothermal. It also discusses the need to conserve energy and increase energy efficiency to support economic growth while reducing dependence on fossil fuels. The document emphasizes that renewable energy has significant potential to contribute to the economy by providing a stable domestic energy supply and reducing environmental and health impacts. It concludes that widespread efforts are needed to develop renewable energy to meet future energy demand and support sustainable economic development.
This document provides an overview of issues related to coal exports in Australia. It discusses the country's historical reliance on coal exports and the conservative government's vision of Australia as an energy superpower. However, the document notes that climate change poses challenges to this outlook as domestic impacts increase and other countries take steps to reduce emissions. While coal remains highly valuable to Australia's economy, prices have declined and resistance to coal has grown due to environmental and health concerns. The future of Australia's coal export industry is uncertain as these various factors create challenges to the status quo.
Summary_of_Meeting_with_DOE_to_Discuss_Geoengineering_OptionsAlvia Gaskill, Jr.
The document summarizes a meeting between Environmental Reference Materials, Inc. and the U.S. Department of Energy to discuss geoengineering options to prevent climate change. It describes a presentation made by Alvia Gaskill proposing a "Global Albedo Enhancement Project" that would cover up to 4.5 million square miles of deserts in reflective material to increase their albedo and offset the effects of greenhouse gas emissions. Climate modeling suggests this could delay the impacts of climate change until emissions are controlled. The estimated maximum cost to cover 4 million square miles of desert over 60 years is $1-2 trillion. Experts at the meeting questioned the proposal and noted more research is needed but did not rule out further
Climate change-implications-for-the-energy-sector-summary-from-ipcc-ar5-2014-...Hossam Zein
The document summarizes key findings from an IPCC report on the implications of climate change for the energy sector. It finds that climate change presents challenges for energy production and transmission as rising temperatures and extreme weather events affect infrastructure and operations. The energy sector is a major contributor to greenhouse gas emissions, and without mitigation policies emissions are projected to rise significantly by 2050 due to increasing energy demand. To keep warming below 2°C, the share of low-carbon electricity generation will need to triple or quadruple by 2050, and fossil fuel use without carbon capture will need to be phased out by 2100. Significant cuts in emissions can be achieved through measures like improving efficiency, switching fuels, expanding renewables, and carbon capture storage
The document discusses both the pros and cons of technology's impact on the environment. On the pro side, it outlines various renewable energy technologies like hydroelectric, wind, solar and geothermal that can help reduce environmental impact. However, on the con side it notes that climate change poses an existential threat if carbon emissions are not reduced rapidly. Certain existing and potential technologies also risk catastrophic destruction if misused, like nuclear weapons. In conclusion, the effect of technology on the planet remains uncertain, but renewable technologies need further development while curbing climate change and limiting weapons proliferation.
This report summarizes nine unconventional energy resources including coal, coalbed methane, gas hydrates, tight gas sands, shale gas and oil, geothermal, oil sands, oil shale, and uranium. Coal and uranium are expected to supply a significant portion of the world's energy in coming years. Recent developments in technologies like horizontal drilling and hydraulic fracturing have enabled increased production of natural gas from shale and tight sandstones in the United States and other areas of the world. Research on other unconventional resources such as gas hydrates and geothermal energy continues to advance.
The document discusses the constraints on future energy transitions given environmental impacts from past transitions. It notes that past transitions from wood to coal had minimal global environmental impacts due to smaller human populations and less powerful technologies, but future transitions must consider effects on climate change, air pollution, and biodiversity loss. It argues that environmental factors may drive the next transition as a key consideration, rather than just energy quality and cost factors. Sustainable energy sources will be needed to alleviate energy poverty and support development while respecting planetary boundaries.
Letter from Dr. Larry Cathles to Gov. Andrew Cuomo Urging End to Moratorium o...Marcellus Drilling News
The letter urges New York Governor Cuomo to lift the moratorium on unconventional natural gas development for three key reasons: 1) Producing natural gas can reduce global warming by over 40% compared to immediately adopting zero-carbon energy, and substituting natural gas for coal improves health and economic outcomes; 2) Regulating development ensures natural gas poses less risk than economically equivalent activities and provides large economic benefits; 3) Developing natural gas safely can encourage other areas and countries to substitute it for coal, keeping long-term warming to acceptable levels.
How Fear of Nuclear Power is Warming our PlanetPaul H. Carr
The world is presently decommissioning nuclear reactors faster than the increase in wind and solar power (1). Solar energy is only available 26% of the time and wind 33%. Nuclear is 24/7. To make up for the net nuclear decrease, we are increasing our burning of fossil fuels. They are raising carbon dioxide emissions that are warming our planet. This is particularly true in Germany.
Bill Gates is presently funding next generation nuclear power. TerraPower's nuclear pilot plant is being built in China. This traveling wave reactor converts depleted uranium, a byproduct of the nuclear-fission process, into usable fuel.
Thorium molten salt nuclear reactors (MSR), demonstrated at Oak Ridge National Laboratory 1965-1970, consume nearly 100% of their fuel, compared with 3% for older reactors with solid uranium fuel (2). MSRs eliminate the need for Yucca Mountain storage by consuming nuclear waste. Thorium fluoride molten fuel for MSRs is of no weapons value. Thorium fuel is more abundant and cheaper than uranium. MSRs require no expensive containment since they operate close to atmospheric pressure.
REFERENCES: (1) Michael Shellenberger YouTube 2016 TED Talk.
(2) David A. Cornell. “Fracking and the Future of Fuel.” Physics Today, pgs 10 -11. February 2017
This document appears to be an image file as it states that QuickTime and a decompressor are needed to view it. However, as only text of the document was provided, the image or any further details cannot be summarized. The document indicates it is an image but does not provide enough information to summarize the essential contents of the image itself.
Alternative Electric Power Plant that Environmental Friendliness at Indonesiainventy
Research Inventy : International Journal of Engineering and Science is published by the group of young academic and industrial researchers with 12 Issues per year. It is an online as well as print version open access journal that provides rapid publication (monthly) of articles in all areas of the subject such as: civil, mechanical, chemical, electronic and computer engineering as well as production and information technology. The Journal welcomes the submission of manuscripts that meet the general criteria of significance and scientific excellence. Papers will be published by rapid process within 20 days after acceptance and peer review process takes only 7 days. All articles published in Research Inventy will be peer-reviewed.
This document discusses planning for energy needs in 2030. It notes that global energy supplies are finite, populations and energy demands are growing, and some energy sources contribute to climate change and pollution. The document examines current and projected contributions of various energy sources like oil, coal, natural gas, and nuclear. It also discusses how long current reserves may last given consumption rates. The document proposes that to address these issues, the plan for 2030 should reduce energy demands through efficiency, educate the public, and diversify energy supplies by developing new technologies, utilizing regional strengths for sources like solar and wind, and reducing reliance on imported oil.
The document discusses global and Indian energy scenarios. It provides information on world energy resources including oil, natural gas, coal and uranium reserves. It notes that 87% of global primary energy supply comes from non-renewable sources. It also discusses India's energy consumption and production, noting that India is the third largest coal producer and consumer of electricity. However, per capita energy consumption in India remains low compared to other countries. The document outlines issues with fossil fuel dependence such as climate change, environmental hazards, and accidents. It describes the impacts of climate change such as extreme weather, sea level rise, and species extinction.
This document discusses natural gas, including its uses, top consuming states, and advantages over coal for power generation. It also summarizes the differences between conventional and unconventional natural gas sources like shale gas, where gas is primarily located in the US, and technologies like fracking that have increased shale gas production. While this has economic and security benefits, fracking raises environmental concerns. The document concludes that increased global natural gas production depends on factors like environmental regulations, climate policy, fuel prices, and production costs.
This document provides an overview of a course on sustainable energy that aims to equip teachers to discuss complex issues around energy and climate change. The course covers motivations for changing energy production, including finite fossil fuel resources, energy security concerns, and the environmental impacts of climate change. It outlines sessions that will discuss energy consumption trends, various renewable and non-renewable technology options, and developing balanced future energy plans.
The document discusses a student's independent study project on hydraulic fracturing (fracking) under Professor Gautier. The project aims to scrutinize the fracking industry and examine methane leakage during the extraction process. There has been little research on this issue so far. One reason public awareness is lacking is the dramatic expansion of fracking in the US in recent years. The student summarizes various perspectives on the costs and benefits of fracking from academics and industry reports. Overall, the document expresses concerns that fracking poses serious risks for accelerating climate change due to methane leakage and for displacing cleaner energy alternatives.
The Global Energy Challenges on Role Of Nuclear Energy and Climate ChangeMahfuzur Rahman Titu
The document summarizes the objectives and key topics discussed at the 5th International Conference on Mechanical Engineering and Renewable Energy (ICMERE-2019). The conference focused on studying current global energy consumption and the role of different energy sources like fossil fuels, nuclear power, and renewables. It discussed challenges like meeting increasing demand through low-cost and low-carbon sources. Presentations analyzed energy resources, generation and consumption trends over time for different fuels. The impact of various energy sources on climate change and their economic costs were also evaluated. The conference emphasized the need for sustainable energy solutions to address future challenges.
The document discusses global warming and the greenhouse effect, noting that rising levels of greenhouse gases like carbon dioxide, methane, and nitrous oxide in the atmosphere are enhancing this effect. It provides two graphs showing increasing CO2 levels in the atmosphere since 1960. It then outlines 50 years of international climate policy efforts, and findings from the IPCC and others that greenhouse gas emissions must be reduced to avoid significant warming and sea level rise in the coming decades. It also discusses actions being taken by states, cities, and regions to cut emissions through targets and plans in the absence of federal policy.
The document discusses renewable energy sources and provides an overview of solar energy as one of the mainstream technologies. It explains that solar energy comes from the sun's radiant light energy and can be used to produce heat, light, and electricity through solar power systems. There are two main methods - one uses solar thermal technology to heat water and produce steam to generate electricity, similar to fossil fuel plants, while the other uses large photovoltaic cell arrays to directly convert sunlight into electricity at high voltages and currents. Solar power is a renewable resource as the sun provides energy constantly. Home solar power systems commonly use photovoltaic panels to harness the sun's energy and convert it to electricity.
This report analyzes the long-term outlook for non-fossil energy technologies in 2050 and beyond. Several key points are made:
- Significant reductions in greenhouse gas emissions are needed by 2050 to keep global warming below 2°C. Relying only on energy sector options may not be sufficient in Europe.
- Many renewable technologies like solar, wind, hydropower, and bioenergy have the potential to play a major role in the global energy supply by 2050. Technologies like geothermal and wave energy also show promise.
- Energy storage technologies will be important for integrating variable renewable resources into the grid and providing energy for transportation. However, energy storage is often costly.
- Nuclear
FINAL SUBMITTED PAPER-TRENDS IN RENEWABLE ENERGY RESOURES AND THEIR APPLICATIONSNavneet Agarwal
This document discusses trends in renewable energy resources and their applications, specifically in developing countries. It provides an overview of various renewable resources like hydroelectric, biomass, wind, solar, and geothermal energy. The current dominance of fossil fuels is described along with projections that they will be depleted. Renewable resources are gaining importance due to benefits like energy price stability, reduced air pollution, protecting the climate, and providing unlimited supplies. Recent growth and investments in renewable energy are also discussed. The conclusion emphasizes the environmental and economic benefits of transitioning to renewable sources.
This document discusses renewable energy resources and energy efficiency. It provides an overview of different renewable energy sources like solar, wind, hydroelectric, biomass and geothermal. It also discusses the need to conserve energy and increase energy efficiency to support economic growth while reducing dependence on fossil fuels. The document emphasizes that renewable energy has significant potential to contribute to the economy by providing a stable domestic energy supply and reducing environmental and health impacts. It concludes that widespread efforts are needed to develop renewable energy to meet future energy demand and support sustainable economic development.
This document provides an overview of issues related to coal exports in Australia. It discusses the country's historical reliance on coal exports and the conservative government's vision of Australia as an energy superpower. However, the document notes that climate change poses challenges to this outlook as domestic impacts increase and other countries take steps to reduce emissions. While coal remains highly valuable to Australia's economy, prices have declined and resistance to coal has grown due to environmental and health concerns. The future of Australia's coal export industry is uncertain as these various factors create challenges to the status quo.
Summary_of_Meeting_with_DOE_to_Discuss_Geoengineering_OptionsAlvia Gaskill, Jr.
The document summarizes a meeting between Environmental Reference Materials, Inc. and the U.S. Department of Energy to discuss geoengineering options to prevent climate change. It describes a presentation made by Alvia Gaskill proposing a "Global Albedo Enhancement Project" that would cover up to 4.5 million square miles of deserts in reflective material to increase their albedo and offset the effects of greenhouse gas emissions. Climate modeling suggests this could delay the impacts of climate change until emissions are controlled. The estimated maximum cost to cover 4 million square miles of desert over 60 years is $1-2 trillion. Experts at the meeting questioned the proposal and noted more research is needed but did not rule out further
Climate change-implications-for-the-energy-sector-summary-from-ipcc-ar5-2014-...Hossam Zein
The document summarizes key findings from an IPCC report on the implications of climate change for the energy sector. It finds that climate change presents challenges for energy production and transmission as rising temperatures and extreme weather events affect infrastructure and operations. The energy sector is a major contributor to greenhouse gas emissions, and without mitigation policies emissions are projected to rise significantly by 2050 due to increasing energy demand. To keep warming below 2°C, the share of low-carbon electricity generation will need to triple or quadruple by 2050, and fossil fuel use without carbon capture will need to be phased out by 2100. Significant cuts in emissions can be achieved through measures like improving efficiency, switching fuels, expanding renewables, and carbon capture storage
The document discusses both the pros and cons of technology's impact on the environment. On the pro side, it outlines various renewable energy technologies like hydroelectric, wind, solar and geothermal that can help reduce environmental impact. However, on the con side it notes that climate change poses an existential threat if carbon emissions are not reduced rapidly. Certain existing and potential technologies also risk catastrophic destruction if misused, like nuclear weapons. In conclusion, the effect of technology on the planet remains uncertain, but renewable technologies need further development while curbing climate change and limiting weapons proliferation.
This report summarizes nine unconventional energy resources including coal, coalbed methane, gas hydrates, tight gas sands, shale gas and oil, geothermal, oil sands, oil shale, and uranium. Coal and uranium are expected to supply a significant portion of the world's energy in coming years. Recent developments in technologies like horizontal drilling and hydraulic fracturing have enabled increased production of natural gas from shale and tight sandstones in the United States and other areas of the world. Research on other unconventional resources such as gas hydrates and geothermal energy continues to advance.
The document discusses the constraints on future energy transitions given environmental impacts from past transitions. It notes that past transitions from wood to coal had minimal global environmental impacts due to smaller human populations and less powerful technologies, but future transitions must consider effects on climate change, air pollution, and biodiversity loss. It argues that environmental factors may drive the next transition as a key consideration, rather than just energy quality and cost factors. Sustainable energy sources will be needed to alleviate energy poverty and support development while respecting planetary boundaries.
Letter from Dr. Larry Cathles to Gov. Andrew Cuomo Urging End to Moratorium o...Marcellus Drilling News
The letter urges New York Governor Cuomo to lift the moratorium on unconventional natural gas development for three key reasons: 1) Producing natural gas can reduce global warming by over 40% compared to immediately adopting zero-carbon energy, and substituting natural gas for coal improves health and economic outcomes; 2) Regulating development ensures natural gas poses less risk than economically equivalent activities and provides large economic benefits; 3) Developing natural gas safely can encourage other areas and countries to substitute it for coal, keeping long-term warming to acceptable levels.
How Fear of Nuclear Power is Warming our PlanetPaul H. Carr
The world is presently decommissioning nuclear reactors faster than the increase in wind and solar power (1). Solar energy is only available 26% of the time and wind 33%. Nuclear is 24/7. To make up for the net nuclear decrease, we are increasing our burning of fossil fuels. They are raising carbon dioxide emissions that are warming our planet. This is particularly true in Germany.
Bill Gates is presently funding next generation nuclear power. TerraPower's nuclear pilot plant is being built in China. This traveling wave reactor converts depleted uranium, a byproduct of the nuclear-fission process, into usable fuel.
Thorium molten salt nuclear reactors (MSR), demonstrated at Oak Ridge National Laboratory 1965-1970, consume nearly 100% of their fuel, compared with 3% for older reactors with solid uranium fuel (2). MSRs eliminate the need for Yucca Mountain storage by consuming nuclear waste. Thorium fluoride molten fuel for MSRs is of no weapons value. Thorium fuel is more abundant and cheaper than uranium. MSRs require no expensive containment since they operate close to atmospheric pressure.
REFERENCES: (1) Michael Shellenberger YouTube 2016 TED Talk.
(2) David A. Cornell. “Fracking and the Future of Fuel.” Physics Today, pgs 10 -11. February 2017
This document appears to be an image file as it states that QuickTime and a decompressor are needed to view it. However, as only text of the document was provided, the image or any further details cannot be summarized. The document indicates it is an image but does not provide enough information to summarize the essential contents of the image itself.
The Blue Hills is a nature reserve located just south of Boston, Massachusetts. It consists of over 7,000 acres of forested hills and valleys and is a popular spot for hiking and other outdoor activities among residents of the Boston area. The highest point in the reserve is Great Blue Hill at 635 feet, which offers panoramic views of Boston and the surrounding areas on clear days.
This document outlines 10 things end-users should be taught about safe and effective computing. These include rebooting before calling for help, properly reporting computer problems with relevant details, keeping passwords secure without writing them down, constructing strong passwords, practicing safe computing while traveling, preventing data loss through backups, understanding usage policies, exercising care when sending emails, protecting against viruses and malware, and avoiding superstitions that frustrate tech support. The full document provides explanations and examples for each of these 10 topics.
Annotated pictures of egyptian sculpturesamarkhan122
Egyptian art and sculpture spanned from prehistory to the conquest by Greeks and Romans. The earliest Egyptian art dates back to 7000-4500 BC depicting human faces. Sculptures were made of stone or wood in finished blocks worked from all four sides simultaneously rather than by one person. Figures were typically viewed from the front with arms and legs connected to the block rather than free-standing due to fears of breakage. Pharaoh sculptures intended to depict beauty rather than realistic likeness.
This document discusses the vibration of continuous systems such as beams. It shows that a continuous system can be modeled as having an infinite number of masses. The governing differential equation is derived and solved using normal mode analysis. Normal modes and natural frequencies are determined by applying boundary conditions. The total response is the sum of responses from each normal mode, allowing a continuous system to be treated as uncoupled single-degree-of-freedom systems. Examples are given for a simply supported beam under free and forced vibration.
The document summarizes the results of a 3-month marketing campaign on YouTube by Tipp-Ex. It states that the teaser video was viewed over 13 million times across 217 countries, with the top 5 countries being France, US, Germany, UK, and Spain. The campaign engaged over 35 million internet users and grew Tipp-Ex's YouTube channel subscribers to over 41,000. It also received positive press coverage and comments praising its creativity and innovative use of YouTube's interactive capabilities to promote a brand in a memorable way.
Rural Economic Action Plan in Central Oklahoma | 2010reapoklahoma
The purpose of this eReport is to highlight the Rural Economic Action Plan in Central Oklahoma in 2010. REAP is a grant program funded by the Oklahoma Legislature and administered by the Association of Central Oklahoma Governments (ACOG) on behalf of rural communities in Central Oklahoma. Thirty-five REAP grants were awarded in 2010.
This document provides information about the Buzzman advertising agency. It introduces the key members of the management team, including the founder and CEO Georges Mohammed-Cherif, general manager Thomas Granger, and executive director Christelle Delarue. It also summarizes Buzzman's approach, highlighting strategic planning, creative teams, account management, and social media expertise. Examples are given of successful campaigns for clients like Orange, Axe, Tipp-Ex, Microsoft, and Bic that achieved notable results like millions of views and social media engagement.
Malicious software like viruses, spyware, and Trojans can damage your computer and lead to identity theft. To detect malware, check for strange computer behavior like slow performance or unexpected file downloads. Use antivirus software to scan for and remove malware, and keep the software up to date to protect against new threats. Regularly applying operating system and software updates also helps prevent infections.
New discoveries have cleared a path to stopping climate change. Energy researchers now know of technologies that could expand energy abundance while reducing carbon release, such as a system that extracts carbon from fossil fuel plant exhaust using a non-thermal plasma field. This breakthrough technology uses only 5% of the plant's power to drive the carbon extraction process. If retrofitted globally, it could give the world a chance to reduce carbon release while still using coal in places like India and China. The future of energy is bright, and carbon can be reduced using these technologies to halt climate change and benefit future generations.
Mark Jacobson Study in Energy & Environment Science : 145 countries on low co...Energy for One World
Most recent publication at the Royal Society of Chemistry, 9th June 2022: Research study by Mark Jacobson Stanford Team- on switching-over from fossil fuels to renewables.
Globally, 62 trillion USD investment is needed to change-over existing fossil-fuel power based energy infrastructure and architectures to clean renewables.
The document discusses the role of clean energy, specifically nuclear power and energy storage, in addressing climate change and transitioning away from fossil fuels. It argues that nuclear power can play a major role in minimizing climate change by producing little to no greenhouse gas emissions over its lifecycle. Energy storage is also seen as important for integrating renewable energy sources like wind and solar into the electric grid and enabling the transition off fossil fuels, as renewables have variable output that storage could help balance. The document examines both the technical and economic impacts of energy storage and variable renewables on the grid and their potential to replace fossil fuels as costs decline and reliability increases over time.
Prof. Mark Jacobson Research Paper: 100% WWS All-Sector Energy Roadmaps and G...Energy for One World
1. The document presents roadmaps for transitioning 145 countries to 100% renewable wind, water, and solar (WWS) energy by 2035-2050 to address global warming, air pollution, and energy insecurity.
2. Grid stability analyses for 24 regions grouping the 145 countries show the regions can match energy supply and demand with 100% WWS and storage through 2052 while avoiding blackouts.
3. Transitioning to 100% WWS is estimated to greatly reduce global energy costs, create more jobs than lost, and require minimal new land area - making WWS more economical than continuing on a business-as-usual path.
This document discusses the urgent need to address climate change through reducing carbon emissions, especially from information and communication technologies (ICT). It notes that ICT carbon emissions are growing rapidly and will account for 40% of energy use by 2030 if unchecked. Transitioning to renewable energy powered "green" networks and data centers is essential to achieving necessary emissions reductions. The document advocates building smart systems that can adapt to the intermittent availability of renewable power sources like wind and solar.
The document proposes a Global Apollo Program to combat climate change through developing clean energy technologies. It notes that current commitments will not limit global warming to under 2°C, and renewable energy research and development (RD&D) is underfunded. The program proposes coordinating international RD&D efforts and spending 0.02% of GDP annually on priority areas like solar energy, electricity storage, and transmission to drive innovation and reduce costs, with a goal of making renewable energy cheaper than coal by 2020-2025. It aims to build on models like the semiconductor industry roadmap to accelerate progress through international collaboration.
There are many potential solutions that are needed to address global warming by reducing greenhouse gas emissions by at least 80% by mid-century. Some key solutions mentioned include boosting energy efficiency, greening transportation through more fuel-efficient vehicles and alternative fuels, increasing renewable energy sources like solar and wind, phasing out fossil fuel electricity generation especially coal, managing forests and agriculture, exploring nuclear power, developing new low-carbon technologies, and ensuring financial assistance for developing countries to transition to low-carbon development. Adaptation measures will also be needed to address the impacts of climate change that are already occurring.
Low Carbon China - Innovation Beyond Efficiencypolicysolutions
Radical innovation is essential to achieve green growth. This paper presents three case studies of business model innovation: fertilizer, lighting services and end-of-life treatment of tires. It makes the case that a culture of innovation is the basis for a low-carbon economy, which demands that we individually and collectively:
• Aspire to transformational, not incremental change;
• Adopt new behaviors and think differently.
English translation of Mandarin original (in press with the Chinese journal Plant Engineering Consultants)
Journal of Economic Perspectives—Volume 30, Number 1—Winter 20.docxcroysierkathey
Journal of Economic Perspectives—Volume 30, Number 1—Winter 2016—Pages 117–138
F ossil fuels provide substantial economic benefits, but in recent decades, a series of concerns have arisen about their environmental costs. In the United States, for example, the Clean Air Act in 1970 and 1977 addressed concerns
over the emissions of so-called conventional pollutions, notably airborne particulate
matter, by imposing fuel economy standards on vehicles and regulations to reduce
emissions from stationary sources. During the 1980s, concerns mounted about how
the combustion of fossil fuels could lead to acid rain and rising ozone levels. The
Clean Air Act Amendments of 1990 created frameworks to reduce sulfur dioxide
and nitrogen oxide from power plant emissions, as well as from the combustion
of gasoline and diesel fuels in vehicles. However, in many of the world’s largest
cities in the emerging economies around the world, the conventional forms of
air pollution from burning fossil fuels—especially particulates, sulfur oxides,
and nitrogen oxides—are still exacting a heavy toll on human health (Chay and
Will We Ever Stop Using Fossil Fuels?
■ Thomas Covert is Assistant Professor of Microeconomics, Booth School of Business, Univer-
sity of Chicago, Chicago, Illinois. Michael Greenstone is the Milton Friedman Professor in
Economics and the College and Director of the Energy Policy Institute at Chicago, both at the
University of Chicago, Chicago, Illinois. Christopher R. Knittel is William Barton Rogers
Professor of Energy Economics, Sloan School of Management, and Director of the Center for
Energy and Environmental Policy Research, all at the Massachusetts Institute of Technology,
Cambridge, Massachusetts. Greenstone and Knittel are also Research Associates, National
Bureau of Economic Research, Cambridge, Massachusetts. Their email addresses are thomas.
[email protected], [email protected], and [email protected]
† For supplementary materials such as appendices, datasets, and author disclosure statements, see the
article page at
http://dx.doi.org/10.1257/jep.30.1.117 doi=10.1257/jep.30.1.117
Thomas Covert, Michael Greenstone, and
Christopher R. Knittel
j_covert_301.indd 117 1/20/16 6:57 AM
118 Journal of Economic Perspectives
Greenstone 2003; Chen, Ebenstein, Greenstone, and Li 2013; Knittel, Miller, and
Sanders forthcoming).
By the mid-1990s, concerns about the role of fossil fuels in generating emis-
sions of carbon dioxide and other greenhouse gases gained traction. Approximately
65 percent of global greenhouse gas emissions are generated by fossil fuel combus-
tion.1 Of these emissions, coal is responsible for 45 percent, oil for 35 percent, and
natural gas for 20 percent.2 To reduce carbon dioxide emissions by enough to miti-
gate the chance of disruptive climate change in a substantial way, there would seem to
be only two possible options. One is to find ways to capture carbon from the air and
store it. T ...
Journal of Economic Perspectives—Volume 30, Number 1—Winter 20.docxtawnyataylor528
Journal of Economic Perspectives—Volume 30, Number 1—Winter 2016—Pages 117–138
F ossil fuels provide substantial economic benefits, but in recent decades, a series of concerns have arisen about their environmental costs. In the United States, for example, the Clean Air Act in 1970 and 1977 addressed concerns
over the emissions of so-called conventional pollutions, notably airborne particulate
matter, by imposing fuel economy standards on vehicles and regulations to reduce
emissions from stationary sources. During the 1980s, concerns mounted about how
the combustion of fossil fuels could lead to acid rain and rising ozone levels. The
Clean Air Act Amendments of 1990 created frameworks to reduce sulfur dioxide
and nitrogen oxide from power plant emissions, as well as from the combustion
of gasoline and diesel fuels in vehicles. However, in many of the world’s largest
cities in the emerging economies around the world, the conventional forms of
air pollution from burning fossil fuels—especially particulates, sulfur oxides,
and nitrogen oxides—are still exacting a heavy toll on human health (Chay and
Will We Ever Stop Using Fossil Fuels?
■ Thomas Covert is Assistant Professor of Microeconomics, Booth School of Business, Univer-
sity of Chicago, Chicago, Illinois. Michael Greenstone is the Milton Friedman Professor in
Economics and the College and Director of the Energy Policy Institute at Chicago, both at the
University of Chicago, Chicago, Illinois. Christopher R. Knittel is William Barton Rogers
Professor of Energy Economics, Sloan School of Management, and Director of the Center for
Energy and Environmental Policy Research, all at the Massachusetts Institute of Technology,
Cambridge, Massachusetts. Greenstone and Knittel are also Research Associates, National
Bureau of Economic Research, Cambridge, Massachusetts. Their email addresses are thomas.
[email protected], [email protected], and [email protected]
† For supplementary materials such as appendices, datasets, and author disclosure statements, see the
article page at
http://dx.doi.org/10.1257/jep.30.1.117 doi=10.1257/jep.30.1.117
Thomas Covert, Michael Greenstone, and
Christopher R. Knittel
j_covert_301.indd 117 1/20/16 6:57 AM
118 Journal of Economic Perspectives
Greenstone 2003; Chen, Ebenstein, Greenstone, and Li 2013; Knittel, Miller, and
Sanders forthcoming).
By the mid-1990s, concerns about the role of fossil fuels in generating emis-
sions of carbon dioxide and other greenhouse gases gained traction. Approximately
65 percent of global greenhouse gas emissions are generated by fossil fuel combus-
tion.1 Of these emissions, coal is responsible for 45 percent, oil for 35 percent, and
natural gas for 20 percent.2 To reduce carbon dioxide emissions by enough to miti-
gate the chance of disruptive climate change in a substantial way, there would seem to
be only two possible options. One is to find ways to capture carbon from the air and
store it. T ...
The WWF report identifies solutions to meet growing global energy demand through 2050 without exceeding a 2-degree Celsius temperature rise. It finds that existing sustainable energy technologies could meet demand if deployed rapidly and at scale. However, urgent action is needed in the next 5 years to set policies driving this transition, as delays will increase costs and risks. Key solutions identified are improving energy efficiency, stopping deforestation, developing renewable technologies concurrently, building infrastructure for flexible fuels, replacing coal with gas in the near-term, and implementing carbon capture and storage. Global cooperation and leadership are imperative to guide investment towards sustainable options.
New energy sources and energy efficiency to prevent catastrophic global clima...Fernando Alcoforado
Regardless of the various solutions that may be adopted to eliminate or mitigate the causes of global warming, the most important is undoubtedly the adoption of measures to contribute to the elimination or reduction of the consumption of fossil fuels in energy production as well as for their more efficient use in transport, industry, agriculture and urban areas (residential and commercial), given the use and production of energy account for 57% of greenhouse gases emitted by human activity. In this sense, the implementation of a world sustainable energy system is essential.
Cullen reducing energy demand EST 2011morosini1952
Reducing Energy Demand: What Are the Practical Limits?
Jonathan M. Cullen, Julian M. Allwood*, and Edward H. Borgstein
Cite this: Environ. Sci. Technol. 2011, 45, 4, 1711–1718
Publication Date:January 12, 2011
https://doi.org/10.1021/es102641n
Abstract
Concern over the global energy system, whether driven by climate change, national security, or fears of shortage, is being discussed widely and in every arena but with a bias toward energy supply options. While demand reduction is often mentioned in passing, it is rarely a priority for implementation, whether through policy or through the search for innovation. This paper aims to draw attention to the opportunity for major reduction in energy demand, by presenting an analysis of how much of current global energy demand could be avoided. Previous work led to a “map” of global energy use that traces the flow of energy from primary sources (fuels or renewable sources), through fuel refinery, electricity generation, and end-use conversion devices, to passive systems and the delivery of final energy services (transport, illumination, and sustenance). The key passive systems are presented here and analyzed through simple engineering models with scalar equations using data based on current global practice. Physically credible options for change to key design parameters are identified and used to predict the energy savings possible for each system. The result demonstrates that 73% of global energy use could be saved by practically achievable design changes to passive systems. This reduction could be increased by further efficiency improvements in conversion devices. A list of the solutions required to achieve these savings is provided.
This document provides an overview and introduction to the "Canada Energy [R]evolution" scenario report, which analyzes Canada's energy efficiency potential and choices for the transport sector. It discusses the need to shift toward renewable energy sources and implement energy efficiency measures to mitigate climate change impacts from greenhouse gas emissions. The scenario examines how Canada can achieve at least a 25% reduction in emissions by 2020 and deeper cuts by 2050 through ambitious development of renewable energy and a transition away from fossil fuels in the energy sector. It presents the energy [r]evolution scenario as a practical blueprint for maintaining economic growth while significantly reducing emissions.
The document discusses the monumental challenge of transitioning to a hydrogen economy from the current fossil fuel economy. It outlines the numerous technological, economic, and social barriers that are impeding this transition, including issues with hydrogen production, storage, distribution, infrastructure, and public acceptance. Overcoming these barriers to make hydrogen a viable and widespread energy alternative will be an enormous undertaking requiring significant advances and coordination across many areas.
A sustainable energy system is required globally to avoid catastrophic environmental impacts from continued reliance on non-renewable energy sources like fossil fuels. Currently 88% of global energy comes from sources like oil, coal and gas, emitting large amounts of carbon dioxide and other greenhouse gases. This overdependence on fossil fuels is the main driver of climate change through global warming. A transition is needed to an energy system based on renewable sources like hydropower, biomass, solar and wind power in order to minimize global warming and avoid future environmental disasters. This will require quadrupling renewable energy production and reducing oil and coal usage by half and 90% respectively by 2030 with renewable sources making up 70% of global energy.
Climate Change and COP23: self-deceptions and sluggish coordinationjournal ijrtem
ABSTRACT : Recent Carribean~Florida events, where warm ocean water provided energy for the hurricane Irma, make us all turn to the UN, and its UNFCCC, in order to find whether the international community is able and willing to engage in large scale activities to halt global warming. Two aspects must be examined: (1) Is there now overwhelming empirical evidence for global warming theory; (2) Can the states of world put together an effective response to rising greenhouse gases?If not, we face the Stephen Hawking threat of enormous damages, global warming becoming irreversible. KEYWORDS: GHG, GWT, CO2, methane, collective action, international governance, UNFCCC: Goal I, Goal II, Goal III.
The document discusses opportunities for transitioning to a low-carbon economy through innovation. It notes that traditional energy efficiency solutions are insufficient and that moving to low-carbon energy sources requires decoupling energy consumption from greenhouse gas emissions. Information and communication technologies can play an important role by helping address issues with renewable energy sources and enabling reliable services even when renewable power availability fluctuates. The document advocates developing zero-carbon strategies using renewable energy to allow continued growth without increasing emissions.
1. R E V I E W : E N G I N E E R I N G
Advanced Technology Paths to Global Climate
Stability: Energy for a Greenhouse Planet
Martin I. Hoffert,1
* Ken Caldeira,3
Gregory Benford,4
David R. Criswell,5
Christopher Green,6
Howard Herzog,7
Atul K. Jain,8
Haroon S. Kheshgi,9
Klaus S. Lackner,10
John S. Lewis,12
H. Douglas Lightfoot,13
Wallace Manheimer,14
John C. Mankins,15
Michael E. Mauel,11
L. John Perkins,3
Michael E. Schlesinger,8
Tyler Volk,2
Tom M. L. Wigley16
Stabilizing the carbon dioxide–induced component of climate change is an energy
problem. Establishment of a course toward such stabilization will require the devel-
opment within the coming decades of primary energy sources that do not emit carbon
dioxide to the atmosphere, in addition to efforts to reduce end-use energy demand.
Mid-century primary power requirements that are free of carbon dioxide emissions
could be several times what we now derive from fossil fuels (ϳ1013
watts), even with
improvements in energy efficiency. Here we survey possible future energy sources,
evaluated for their capability to supply massive amounts of carbon emission–free
energy and for their potential for large-scale commercialization. Possible candidates
for primary energy sources include terrestrial solar and wind energy, solar power
satellites, biomass, nuclear fission, nuclear fusion, fission-fusion hybrids, and fossil
fuels from which carbon has been sequestered. Non–primary power technologies that
could contribute to climate stabilization include efficiency improvements, hydrogen
production, storage and transport, superconducting global electric grids, and geoengi-
neering. All of these approaches currently have severe deficiencies that limit their
ability to stabilize global climate. We conclude that a broad range of intensive
research and development is urgently needed to produce technological options that
can allow both climate stabilization and economic development.
M
ore than a century ago, Arrhenius
put forth the idea that CO2 from fos-
sil fuel burning could raise the infra-
red opacity of the atmosphere enough to
warm Earth (1). In the 20th century, the
human population quadrupled and primary
power consumption increased 16-fold (2).
The fossil fuel greenhouse theory has become
more credible as observations accumulate
and as we better understand the links between
fossil fuel burning, climate change, and en-
vironmental impacts (3). Atmospheric CO2
has increased from ϳ275 to ϳ370 parts per
million (ppm). Unchecked, it will pass 550
ppm this century. Climate models and paleo-
climate data indicate that 550 ppm, if sus-
tained, could eventually produce global
warming comparable in magnitude but oppo-
site in sign to the global cooling of the last Ice
Age (4).
The United Nations Framework Conven-
tion on Climate Change aims to stabilize
greenhouse gas concentrations at levels that
avoid “dangerous anthropogenic interference
with the climate system (5).” Atmospheric
CO2 stabilization targets as low as 450 ppm
could be needed to forestall coral reef bleach-
ing, thermohaline circulation shutdown, and
sea level rise from disintegration of the West
Antarctic Ice Sheet (6). Wigley and col-
leagues developed emission scenarios to sta-
bilize atmospheric CO2 at 350, 450, 550, 650,
or 750 ppm (7). They minimized early emis-
sion controls by initially following a busi-
ness-as-usual scenario that combines eco-
nomic growth of 2 to 3% yearϪ1
with a
sustained decline of 1% yearϪ1
in energy
intensity (energy use per gross domestic
product). Much larger cuts than those called
for in the Kyoto Protocol are needed later,
because the levels at which CO2 stabilize
depend approximately on total emissions.
Targets of cutting to 450 ppm, and certain-
ly 350 ppm, could require Herculean
effort. Even holding at 550 ppm is a major
challenge.
Primary power consumption today is ϳ12
TW, of which 85% is fossil-fueled. Stabiliza-
tion at 550, 450, and 350 ppm CO2 by Wigley
et al. scenarios require emission-free power
by mid-century of 15, 25, and Ͼ30 TW,
respectively (8). Attaining this goal is not
easy. CO2 is a combustion product vital to
how civilization is powered; it cannot be
regulated away. CO2 stabilization could pre-
vent developing nations from basing their
energy supply on fossil fuels (9). Hansen et
al. call for reductions in methane and black
soot, which also cause warming (10). Such
reductions are desirable but do not address
fossil fuel greenhouse warming. The Kyoto
Protocol calls for greenhouse gas emission
reductions by developed nations that are 5%
below 1990 levels by 2008 to 2012. Paradox-
ically, Kyoto is too weak and too strong: Too
strong because its initial cuts are perceived as
an economic burden by some (the United
States withdrew for this stated reason); too
weak because much greater emission reduc-
tions will be needed, and we lack the tech-
nology to make them.
Arguably, the most effective way to re-
duce CO2 emissions with economic growth
and equity is to develop revolutionary chang-
es in the technology of energy production,
distribution, storage, and conversion (8). The
need to intensify research on such technolo-
gies now is by no means universally appre-
ciated. Present U.S. policy emphasizes do-
mestic oil production, not energy technology
research (11). Misperceptions of technologi-
cal readiness also appear in the latest “Sum-
mary for Policymakers” by the “Mitigation”
Working Group of the Intergovernmental
Panel on Climate Change (IPCC): “. . .
known technological options could achieve a
broad range of atmospheric CO2 stabilization
levels, such as 550 ppm, 450 ppm or below
over the next 100 years or more. . . . Known
technological options refer to technologies
that exist in operation or pilot plant stage
today. It does not include any new technolo-
gies that will require drastic technological
breakthroughs. . . .” (12)
This statement does not recognize the
CO2 emission–free power requirements im-
plied by the IPCC’s own reports (3, 8) and is
not supported by our assessment. Energy
1
Department of Physics, 2
Department of Biology,
New York University, New York, NY 10003, USA.
3
Lawrence Livermore National Laboratory, Livermore,
CA 94550, USA. 4
Department of Physics and Astron-
omy, University of California, Irvine, CA 92697, USA.
5
Institute of Space Systems Operations, University of
Houston, Houston, TX 77204, USA. 6
Department of
Economics, McGill University, Montreal, Quebec H3A
2T7, Canada. 7
MIT Laboratory for Energy and the
Environment, Cambridge, MA 02139, USA. 8
Depart-
ment of Atmospheric Sciences, University of Illinois at
Urbana-Champaign, Urbana, IL 61801, USA. 9
Exxon-
Mobil Research and Engineering Company, Annan-
dale, NJ 08801, USA. 10
Department of Earth and
Environmental Engineering, 11
Department of Applied
Physics and Applied Mathematics, Columbia Univer-
sity, New York, NY 10027, USA. 12
Lunar and Planetary
Laboratory, University of Arizona, Tucson, AZ 85721,
USA. 13
Centre for Climate and Global Change Re-
search, McGill University, Montreal, Quebec H3A 2K6,
Canada. 14
Plasma Physics Division, Naval Research
Laboratory, Washington, DC 20375, USA. 15
NASA
Headquarters, Washington, DC 20546, USA. 16
Na-
tional Center for Atmospheric Research, Boulder, CO
80307, USA.
*To whom correspondence should be addressed. E-
mail: marty.hoffert@nyu.edu
S C I E N C E ’ S C O M P A S S ● R E V I E W
www.sciencemag.org SCIENCE VOL 298 1 NOVEMBER 2002 981
2. sources that can produce 100 to 300% of
present world power consumption without
greenhouse emissions do not exist operation-
ally or as pilot plants.
Can we produce enough emission-free
power in time? Here we assess the potential
of a broad range of technologies aimed at
meeting this goal.
Improving Efficiency
Efficiency is the ratio of usable energy output
to energy input. Primary energy in metastable
chemical and nuclear bonds includes fossil
fuels, fission fuels, and fusion fuels. “Renew-
ables” are primary energy in natural fluxes
(solar photons, wind, water, and heat flows).
Energy conversion always involves dissipa-
tive losses, losses that in many cases engi-
neers have already expended considerable ef-
fort to reduce. Opportunities still exist to
improve efficiency in power generation and
end-use sectors: transportation, manufactur-
ing, electricity, and (indoor) climate condi-
tioning (13).
The efficiencies of mature technologies
are well characterized (14, 15). Most efficient
are large electric generators (98 to 99% effi-
cient) and motors (90 to 97%). These are
followed by rotating heat engines that are
limited by the second law of thermodynam-
ics: gas and steam turbines (35 to 50%) and
diesel (30 to 35%) and internal combustion
(15 to 25%) engines. Electrolyte and elec-
trode materials and catalysts limit electro-
chemical fuel cells (50 to 55% now; 70%
eventually). Fuel cells may replace heat en-
gines but will likely run on hydrogen. A
seamless transition would use H2 extracted
from gasoline or methanol in reformers (75 to
80%). Renewable energy converters include
photovoltaic (PV) cells (commercial arrays,
about 15 to 20%; theoretical peak for single
bandgap crystalline cells, Ϸ24%; higher for
multiband cells, lower for more cost-effective
amorphous thin films) and wind turbines
(commercial units, about 30 to 40%; theoret-
ical “Betz limit,” Ϸ59%). High-pressure so-
dium vapor (15 to 20%), fluorescent (10 to
12%), and incandescent (2 to 5%) illumina-
tion generate more heat than light. Photosyn-
thesis has a very low sunlight-to-chemical
energy efficiency, limited by chlorophyll ab-
sorption bands (most productive ecosystems
are about 1 to 2% efficient; theoretical peak
independent of cell or ecosystem is Ϸ8%).
How much can energy efficiency im-
prove? In a given technology class, efficiency
normally starts low, grows for decades to
centuries, and levels off at some fraction of
its theoretical peak (16). It took 300 years to
develop fuel cells from 1%-efficient steam
engines. The earliest gas turbines could bare-
ly turn their compressors. The development
of fusion could be similar: The best experi-
ments are close to balancing power to ignite
the plasma; power is carried off by fusion-
generated neutrons, but no net power output
has occurred yet. Fossil and nuclear fuels are
much closer to their limits (Figs. 1A and 4A).
Steam-cycle efficiencies (39 to 50%, includ-
ing combined cycles and cogeneration) and
overall primary energy–to-electricity effi-
ciency (30 to 36%, including transmission
losses) yield the nominal thermal-to-electric
power conversion: 3 kW (thermal) Ϸ 1 kWe
(electrical). Impressive reductions in waste
heat have been accomplished with compact
fluorescents, low emissivity windows, and
cogeneration (17). More efficient automotive
power conversion is possible (18, 19). Emis-
sions depend on vehicle mass, driving
patterns, and aerodynamic drag, as well as
well-to-wheels efficiency [(torque ϫ angular
velocity at wheels)/(fossil fuel power in)].
Power trains are typically 18 to 23% efficient
for internal combustion (IC), 21 to 27% for
battery-electric (35 to 40%, central power
plant; 80 to 85%, charge-discharge cycles; 80
to 85%, motor), 30 to 35% for IC-electric
hybrid (higher efficiency from electric power
recovery of otherwise lost mechanical ener-
gy), and 30 to 37% for fuel cell–electric (75
to 80%, reformer; 50 to 55%, fuel cell; 80 to
85%, motor).
Lifestyles also affect emissions. Ultra fu-
el-efficient cars are available today that can
travel up to 29 km literϪ1
[68 miles per
gallon (mpg) U.S. Environmental Protection
Agency highway driving cycle (EPA hwy)].
But consumer demand for sport utility vehi-
cles (SUVs) has driven the fuel economy of
the U.S. car and light truck fleet to a 21-year
low of 8.5 km literϪ1
(20 mpg EPA hwy)
steam
Steam
Turbine
water
condensate
Condensor
Generator
electricity
out
Pump
High-pressure Boiler
fossil fuel in
air (O2)
CO2 up the stack
or sequestered
CO2 out
CO2
to cooling
tower or cold
river water
and/or
cogeneration
cooling water
return flow
A
B
fossil
fuel
sequestered CO2
CO2
farm residue
or marine
biomass sunk
to deep ocean
ocean release
of CO2/CaCO3
mixture or
liquid CO2
CO2
CO2
electricity
& H2 magnesium carbonate bricks
central
power plants
biomass
fuel
Coal
mines
Gas & Oil
fields
Deep coal beds,
subterranean
aquifers
Carbon sequestration rates to produce
10 TW CO2-emission-free from fossil fuels
Fossil
fuel
Gas
Oil
Coal
Energy content
[TW-yr]
Carbon content
[GTC]
(Efuel/C)
[TW-yr/GtC]
(E/C)
[TW-yr/GtC]
Sequestration
rate [GtC/yr]
1200
1200
4800
570
750
3690
2.1
1.6
1.3
1.9 - 1.6
1.4 - 1.2
1.2 - 1.0
5 - 6
7 - 8
9 - 10
Fig. 1. (A) Fossil fuel electricity from steam turbine cycles. (B) Collecting CO2 from central plants
and air capture, followed by subterranean, ocean, and/or solid carbonate sequestration, could foster
emission-free electricity and hydrogen production, but huge processing and sequestration rates are
needed (5 to 10 GtC yearϪ1
to produce 10 TW emission-free assuming energy penalties of 10 to
25%).
S C I E N C E ’ S C O M P A S S
1 NOVEMBER 2002 VOL 298 SCIENCE www.sciencemag.org982
3. (19). Even with SUVs, doubling (or more)
efficiency is quite feasible. Unfortunately, the
effects of such efficiency could be over-
whelmed if China and India follow the U.S.
path from bicycles and mass transit to cars.
(Asia already accounts for Ͼ80% of petro-
leum consumption growth.) As a result, car-
bon-neutral fuels or CO2 “air capture” may
be the best alternatives to develop.
Decarbonization and Sequestration
Reducing the amount of carbon emitted per unit
of primary energy is called decarbonization.
The long-term trend has been from coal to oil to
gas, with each fuel emitting progressively less
CO2 per joule of heat (20). Continuation of the
trend would lead to use of H2, a carbon-neutral
fuel, but H2 does not exist in geological reser-
voirs. Processes requiring energy are needed for
its synthesis. The energy can come from fossil
fuel feedstocks. H2 is produced today by steam-
reforming natural gas (2H2O ϩ CH4 3 4H2 ϩ
CO2). Energy can be transferred to H2 with an
efficiency of about 72% from gas, 76% from
oil, and 55 to 60% from coal (21). Per unit of
heat generated, more CO2 is produced by mak-
ing H2 from fossil fuel than by burning the
fossil fuel directly. Emission-free H2 manufac-
tured by water electrolysis that is powered by
renewable or nuclear sources is not yet cost
effective.
Thus, the decarbonization of fuels alone
will not mitigate global warming. The under-
lying problem is providing 10 to 30 TW
emission-free in 50 years. Continuing the
trend to lower carbon fuels requires disposing
of excess carbon because the trend opposes
the relative abundance of fossil resources—
high-carbon coal being most abundant, fol-
lowed by oil and gas (22, 23). One vision of
“clean” coal incorporates CO2 capture and
sequestration: Coal and/or biomass and waste
materials are gasified in an oxygen-blown
gasifier, and the product is cleaned of sulfur
and reacted with steam to form H2 and CO2.
After heat extraction, the CO2 is sequestered
and the H2 used for transportation or electric-
ity generation (24). Decarbonization is thus
intimately linked to sequestration (25). Se-
questration reservoirs include oceans, trees,
soils, depleted natural gas and oil fields, deep
saline aquifers, coal seams, and solid mineral
carbonates (Fig. 1B). The main advantage of
sequestration is its compatibility with exist-
ing fossil fuel infrastructures, including CO2
injections for enhanced recovery from exist-
ing oil and gas fields and capture of CO2
from power plant flue gases.
Recovery of fossil fuel CO2 emitted from
decentralized sources (like cars) may be
needed. The simplest air capture is foresta-
tion. Tree and soil sequestration does not
require combustion product separation or
more fuel, but the capacity to absorb CO2 is
limited. Uptake occurs during growth of or-
ganic matter (CH2O), when the net photosyn-
thesis-respiration reaction is to the right: h
ϩ CO2 ϩ H2O 3 CH2O ϩ O2. Historical
CO2 data and models imply a temperate for-
est carbon sink today of 1 to 3 billion tons of
carbon (GtC) yearϪ1
(3), but some models
show forests reversing from sinks to sources
later this century as global warming increases
soil respiration (26). The exchange time of
CO2 with trees is ϳ7 years. Turnover of iron
fertilization–enhanced plankton uptake (27)
can be similarly fast if organic detritus oxi-
dizes near the surface. Biological sequestra-
tion approaches to longer term storage in-
clude sealing undecayed trees underground
(28) and sinking agricultural residues to the
deep ocean (29). Air capture by aqueous cal-
cium hydroxide [Ca(OH)2] in shallow pools,
with CO2 recovery by heating CaCO3 in a
retort to produce CaO and CO2, has also been
proposed (30). This reaction (calcination) is a
key step in making cement from limestone,
but breaking the Ca–CO2 bond requires sub-
stantial energy.
Also being explored is longer term CO2
sequestration in the deep sea (31). For a given
emission scenario, ocean injections can sub-
stantially decrease peak atmospheric CO2
levels, although all cases eventually diffuse
some CO2 back to the atmosphere (32). Back-
diffusion and pH impacts of ocean CO2 dis-
posal could be diminished by accelerating
carbonate mineral weathering that would oth-
erwise slowly neutralize the oceanic acidity
produced by fossil fuel CO2 (33, 34). A
far-reaching removal scheme is reacting CO2
with the mineral serpentine to sequester car-
bon as a solid in magnesium carbonate
“bricks” by vastly accelerating silicate rock
weathering reactions, which remove atmo-
spheric CO2 over geologic time scales (35).
Thus, carbon sequestration could be a valu-
able bridge to renewable and/or nuclear
energy. However, if other emission-free pri-
mary power sources of 10 to 30 TW are
unavailable by mid-century, then enormous
sequestration rates could be needed to stabi-
lize atmospheric CO2 (Fig. 1B). Substantial
research investments are needed now to make
this technology available in time.
Renewables
Renewable energy technologies include bio-
mass, solar thermal and photovoltaic, wind,
N2 (liquid)
N2 (gas)
to superconducting
electric power grid
electric
power
conditioning
liquid nitrogen
chiller
to hydrogen
pipelines and
storage
H2
H2O
O2
electrolyzerphotovoltaic
arrays
wind farms
Renewable
electricity and
hydrogen
A
B
Icosahedron: An
equilateral-triangle-
faced solid that
reduces map projection
errors
Antarctica
Europe
Asia
Africa
South
America
North
America
Oceania
Buckminster Fuller's Global Electrical Grid
Fig. 2. (A) Mass-produced widely distributed PV arrays and wind turbines making electrolytic H2 or
electricity may eventually generate 10 to 30 TW emission-free. (B) The global grid proposed by R.
Buckminster Fuller with modern computerized load management and high-temperature supercon-
ducting (HTS) cables could transmit electricity from day to night locations and foster low-loss
distribution from remote, episodic, or dangerous power sources. (The resistivity of HTS wires
vanishes below the 77 K boiling point of nitrogen available from air.)
S C I E N C E ’ S C O M P A S S
www.sciencemag.org SCIENCE VOL 298 1 NOVEMBER 2002 983
4. hydropower, ocean thermal, geothermal, and
tidal (36). With the exception of firewood
and hydroelectricity (close to saturation),
these are collectively Ͻ1% of global power.
All renewables suffer from low areal power
densities. Biomass plantations can produce
carbon-neutral fuels for power plants or
transportation, but photosynthesis has too
low a power density (ϳ0.6 W mϪ2
) for bio-
fuels to contribute significantly to climate
stabilization (14, 37). (10 TW from biomass
requires Ͼ10% of Earth’s land surface, com-
parable to all of human agriculture.) PV and
wind energy (ϳ15 We mϪ2
) need less land,
but other materials can be limiting. For solar
energy, U.S. energy consumption may re-
quire a PV array covering a square ϳ160 km
on each side (26,000 km2
) (38). The electri-
cal equivalent of 10 TW (3.3 TWe) requires a
surface array ϳ470 km on a side (220,000
km2
). However, all the PV cells shipped from
1982 to 1998 would only cover ϳ3 km2
(39).
A massive (but not insurmountable) scale-up
is required to get 10 to 30 TW equivalent.
More cost-effective PV panels and wind
turbines are expected as mass production drives
economies of scale. But renewables are inter-
mittent dispersed sources unsuited to baseload
without transmission, storage, and power con-
ditioning. Wind power is often available only
from remote or offshore locations. Meeting lo-
cal demand with PV arrays today requires
pumped-storage or battery-electric backup sys-
tems of comparable or greater capacity (40).
“Balance-of-system” infrastructures could
evolve from natural gas fuel cells if reformer H2
is replaced by H2 from PV or wind electrolysis
(Fig. 2A). Reversible electrolyzer and fuel cells
offer higher current (and power) per electrode
area than batteries, ϳ20 kWe mϪ2
for proton
exchange membrane (PEM) cells (21). PEM
cells need platinum catalysts, Ͼ 5 ϫ 10Ϫ3
kg Pt
mϪ2
(41) (a 10-TW hydrogen flow rate could
require 30 times as much as today’s annual
world platinum production). Advanced electri-
cal grids would also foster renewables. Even if
PV and wind turbine manufacturing rates in-
creased as required, existing grids could not
manage the loads. Present hub-and-spoke net-
works were designed for central power plants,
ones that are close to users. Such networks need
to be reengineered. Spanning the world electri-
cally evokes Buckminster Fuller’s global grid
(Fig. 2B). Even before the discovery of high-
temperature superconductivity (42), Fuller en-
visioned electricity wheeled between day and
night hemispheres and pole-to-pole (43).
Worldwide deregulation and the free trade of
electricity could have buyers and sellers estab-
lishing a supply-demand equilibrium to yield a
worldwide market price for grid-provided
electricity.
Space solar power (SSP) (Fig. 3, A and B)
exploits the unique attributes of space to
power Earth (44, 45). Solar flux is ϳ8 times
higher in space than the long-term surface
average on spinning, cloudy Earth. If theoret-
ical microwave transmission efficiencies (50
to 60%) can be realized, 75 to 100 We could
be available at Earth’s surface per m2
of PV
array in space, Յ1/4 the area of surface PV
arrays of comparable power. In the 1970s, the
National Aeronautics and Space Administra-
tion (NASA) and the U.S. Department of
Energy (DOE) studied an SSP design with a
PV array the size of Manhattan in geostation-
ary orbit [(GEO) 35,800 km above the equa-
tor] that beamed power to a 10-km by 13-km
surface rectenna with 5 GWe output. [10 TW
equivalent (3.3 TWe) requires 660 SSP units.]
Other architectures, smaller satellites, and
newer technologies were explored in the
NASA “Fresh Look Study” (46). Alternative
locations are 200- to 10,000-km altitude sat-
ellite constellations (47), the Moon (48, 49),
and the Earth-Sun L2 Lagrange exterior point
[one of five libration points corotating with
the Earth-Sun system (Fig. 3C)] (50). Poten-
tially important for CO2 emission reduction is
a demonstration proposed by Japan’s Institute
of Space and Aeronautical Science to beam
solar energy to developing nations a few
degrees from the equator from a satellite in
low equatorial orbit (51). Papua New Guinea,
Indonesia, Ecuador, and Colombia on the
Pacific Rim, and Malaysia, Brazil, Tanzania,
and the Maldives have agreed to participate
in such experiments (52). A major challenge
is reducing or externalizing high launch
Solar power
satellite
phased-array
transmitting
antenna
Dt
Dr
sun-tracking
PV arrays in
orbit
to grid and local
power consumers
power
regulation
microwave
power beam
DC out
pilot
beam
rectenna
(rectifying
antenna)
B
Generation of power on the Moon,
transmission to Earth by microwave beams
•Assembled mainly from lunar materials
Generation of power in-orbit,
transmission to Earth by microwave
Transmission of power from
one point to another
•Assembled entirely from terrestrial materials
or
•Assembled partly or mainly from lunar materials
power
source
orbiting solar
arrays with
microwave
transmitters
solar
arrays
on Moon
power
consumer
solar reflectors
in lunar orbit
Earth-orbiting
microwave
reflectors
orbiting microwave
reflector
Sun
Sun
A
x
x
x
L3
L1
L2
L5L4
~ 0.01 AU
2% of sunlight
diffracted to
bypass Earth
10 µm thick Fresnel
lens near L1
aerosol
scatters in
the atmosphere
EARTH
SUN
parasol screen
or lens
1 AU ഠ
150 x 106 km
Earth--Sun
Lagrange
points
C
Fig. 3. Capturing and controlling sun power in space. (A) The power relay satellite, solar power
satellite (SPS), and lunar power system all exploit unique attributes of space (high solar flux, lines
of sight, lunar materials, shallow gravitational potential well of the Moon). (B) An SPS in a low Earth
orbit can be smaller and cheaper than one in geostationary orbit because it does not spread its
beam as much; but it does not appear fixed in the sky and has a shorter duty cycle (the fraction
of time power is received at a given surface site). (C) Space-based geoengineering. The Lagrange
interior point L1 provides an opportunity for radiative forcing to oppose global warming. A
2000-km-diameter parasol near L1 could deflect 2% of incident sunlight, as could aerosols with
engineered optical properties injected in the stratosphere.
S C I E N C E ’ S C O M P A S S
1 NOVEMBER 2002 VOL 298 SCIENCE www.sciencemag.org984
5. costs. With adequate research investments,
SSP could perhaps be demonstrated in 15 to
20 years and deliver electricity to global mar-
kets by the latter half of the century (53, 54).
Fission and Fusion
Nuclear electricity today is fueled by 235
U.
Bombarding natural U with neutrons of a few
eV splits the nucleus, releasing a few hundred
million eV (235
U ϩ n 3 fission products ϩ
2.43n ϩ 202 MeV) (55). The 235
U isotope,
0.72% of natural U, is often enriched to 2 to
3% to make reactor fuel rods. The existing
ϳ500 nuclear power plants are variants of
235
U thermal reactors (56, 57): the light water
reactor [(LWR) in both pressurized and boil-
ing versions]; heavy water (CANDU) reactor;
graphite-moderated, water-cooled (RBMK)
reactors, like Chernobyl; and gas-cooled
graphite reactors. LWRs (85% of today’s re-
actors) are based largely on Hyman Rick-
over’s water-cooled submarine reactor (58).
Loss-of-coolant accidents [Three Mile Island
(TMI) and Chernobyl] may be avoidable in
the future with “passively safe” reactors (Fig.
4A). Available reactor technology can pro-
vide CO2 emission–free electric power,
though it poses well-known problems of
waste disposal and weapons proliferation.
The main problem with fission for climate
stabilization is fuel. Sailor et al. (58) propose
a scenario with 235
U reactors producing ϳ10
TW by 2050. How long before such reactors
run out of fuel? Current estimates of U in
proven reserves and (ultimately recoverable)
resources are 3.4 and 17 million metric tons,
respectively (22) [Ores with 500 to 2000
parts per million by weight (ppmw) U are
considered recoverable (59)]. This represents
60 to 300 TW-year of primary energy (60).
At 10 TW, this would only last 6 to 30
years—hardly a basis for energy policy. Re-
coverable U may be underestimated. Still,
with 30- to 40-year reactor lifetimes, it would
be imprudent (at best) to initiate fission scale-
up without knowing whether there is enough
fuel. What about the seas? Japanese research-
ers have harvested dissolved U with organic
adsorbents from flowing seawater (61).
Oceans have 3.2 ϫ 10Ϫ6
kg dissolved U mϪ3
(62)— a 235
U energy density of 1.8 MJ mϪ3
.
Multiplying by the oceans’ huge volume
(1.37 ϫ 1018
m3
) gives 4.4 billion metric tons
U and 80,000 TW-year in 235
U. Runoff and
outflow to the sea from all the world’s rivers
is 1.2 ϫ 106
m3
sϪ1
(63). Even with 100%
235
U extraction, the flow rate needed to make
reactor fuel at the 10 TW rate is five times as
much as this outflow (64). Getting 10 TW
primary power from 235
U in crustal ores or
seawater extraction may not be impossible,
but it would be a big stretch.
Despite enormous hurdles, the most
promising long-term nuclear power source is
still fusion (65). Steady progress has been
made toward “breakeven” with tokamak (a
toroidal near-vacuum chamber) magnetic
confinement [Q § (neutron or charged parti-
cle energy out)/(energy input to heat plas-
ma) ϭ 1] (Fig. 4B). The focus has been on
the deuterium-tritium (D-T) reaction (3
4
He ϩ n ϩ 17.7 MeV). Breakeven requires
that the “plasma triple product” satisfy the
Lawson criteria: n ϫ ϫ kT Ϸ 1 ϫ 1021
mϪ3
s keV for the D-T reaction, where n is number
density; , confinement time; T, temperature;
and k, Boltzmann’s constant (66, 67). Best
results from Princeton (Tokamak Fusion Test
Reactor) and Europe (Joint European Torus)
are within a factor of two (68). Higher Qs are
needed for power reactors: Neutrons pene-
trating the “first wall” would be absorbed by
molten lithium, and excess heat would be
transferred to turbogenerators. Tritium (12.3-
year half-life) would also be bred in the
lithium blanket (n ϩ 6
Li 3 4
He ϩ T ϩ 4.8
MeV). D in the sea is virtually unlimited
whether utilized in the D-T reaction or the
harder-to-ignite D-D reactions (3 3
He ϩ
n ϩ 3.2 MeV and 3 T ϩ p ϩ 4.0 MeV). If
D-T reactors were operational, lithium bred
to T could generate 16,000 TW-year (69),
twice the thermal energy in fossil fuels. The
D-3
He reaction (3 4
He ϩ p ϩ 18.3 MeV) is
of interest because it yields charged particles
directly convertible to electricity (70). Stud-
ies of D-3
He and D-D burning in inertial
confinement fusion targets suggest that cen-
tral D-T ignitors can spark these reactions.
steam
generator
Fig. 4. (A) The conventional LWR employs water as both coolant and working fluid (left). The
helium-cooled, graphite-moderated, pebble-bed, modular nuclear fission reactor is theoretically
immune to loss-of-coolant meltdowns like TMI and Chernobyl (right). (B) The most successful path
to fusion has been confining a D-T plasma (in purple) with complex magnetic fields in a tokamak.
Breakeven occurs when the plasma triple product (number density ϫ confinement time ϫ
temperature) attains a critical value. Recent tokamak performance improvements were capped by
near-breakeven [data sources in (68)]. Experimental work on advanced fusion fuel cycles and
simpler magnetic confinement schemes like the levitated dipole experiment (LDX ) shown are
recommended.
S C I E N C E ’ S C O M P A S S
www.sciencemag.org SCIENCE VOL 298 1 NOVEMBER 2002 985
6. Ignition of D-T–fueled inertial targets and
associated energy gains of Q Ն 10 may be
realized in the National Ignition Facility
within the next decade. Experiments are un-
der way to test dipole confinement by a su-
perconducting magnet levitated in a vacuum
chamber (71), a possible D-3
He reactor pro-
totype. Rare on Earth, 3
He may someday be
cost-effective to mine from the Moon (72). It
is even more abundant in gas-giant planetary
atmospheres (73). Seawater D and outer plan-
et 3
He could power civilization longer than
any source other than the Sun.
How close, really, are we to using fusion?
Devices with a larger size or a larger mag-
netic field strength are required for net power
generation. Until recently, the fusion commu-
nity was promoting the International Thermo-
nuclear Experimental Reactor (ITER) to test
engineering feasibility. Enthusiasm for ITER
waned because of the uncertainty in raising
the nearly $10 billion needed for construc-
tion. The U.S. halted ITER sponsorship in
1998, but there is renewed interest among
U.S. fusion scientists to build a smaller-sized,
higher-field, nonsuperconducting experiment
or to rejoin participation in a half-sized, re-
designed ITER physics experiment. A “burn-
ing plasma experiment” could produce net
fusion power at an affordable scale and could
allow detailed observation of confined plas-
ma during self-heating by hot alpha particles.
The Fusion Energy Sciences Act of 2001
calls on DOE to “develop a plan for United
States construction of a magnetic fusion
burning plasma experiment for the purpose of
accelerating scientific understanding of fu-
sion plasmas (74).” This experiment is a
critical step to the realization of practical
fusion energy. Demonstrating net electric
power production from a self-sustaining fu-
sion reactor would be a breakthrough of over-
whelming importance but cannot be relied on
to aid CO2 stabilization by mid-century.
The conclusion from our 235
U fuel analy-
sis is that breeder reactors are needed for
fission to significantly displace CO2 emis-
sions by 2050. Innovative breeder technolo-
gies include fusion-fission and accelerator-
fission hybrids. Fissionable 239
Pu and/or
233
U can be made from 238
U and 232
Th (75).
Commercial breeding is illegal today in the
United States because of concerns over waste
and proliferation (France, Germany, and Ja-
pan have also abandoned their breeding pro-
grams). Breeding could be more acceptable
with safer fuel cycles and transmutation of
high-level wastes to benign products (76). Th
is the more desirable feedstock: It is three
times more abundant than U and 233
U is
harder to separate and divert to weapons than
plutonium. One idea to speed up breeding of
233
U is to use tokamak-derived fusion-fission
hybrids (68, 77). D-T fusion yields a 3.4-
MeV alpha particle and a 14-MeV neutron.
The neutron would be used to breed 233
U
from Th in the fusion blanket. Each fusion
neutron would breed about one 233
U and one
T. Like 235
U, 233
U generates about 200 MeV
when it fissions. Fission is energy rich and
neutron poor, whereas fusion is energy poor
and neutron rich. A single fusion breeder
could support perhaps 10 satellite burners,
whereas a fission breeder supports perhaps
one. A related concept is the particle accel-
erator-fission hybrid breeder (56): Thirty
3-MeV neutrons result from each 1000-MeV
proton accelerated into molten lead; upon
injection to a subcritical reactor, these could
increase reactivity enough to breed 233
U from
Th, provide electricity, and power the accel-
erator efficiently (ϳ10% of the output). The
radiotoxicity of hybrid breeder reactors over
time is expected to be substantially below
LWRs.
These ideas appear important enough to
pursue experimentally, but both fission and
fusion are unlikely to play significant roles in
climate stabilization without aggressive re-
search and, in the case of fission, without the
resolution of outstanding issues of high-level
waste disposal and weapons proliferation.
Geoengineering
No discussion of global warming mitigation
is complete without mentioning “geoengi-
neering” (78, 79), also called climate engi-
neering or planetary engineering on Earth and
terraforming on other planets (80). Geoengi-
neering in the climate change context refers
mainly to altering the planetary radiation bal-
ance to affect climate and uses technologies
to compensate for the inadvertent global
warming produced by fossil fuel CO2 and
other greenhouse gases. An early idea was to
put layers of reflective sulfate aerosol in the
upper atmosphere to counteract greenhouse
warming (81). Variations on the sunblocking
theme include injecting sub-micrometer dust
to the stratosphere in shells fired by naval
guns, increasing cloud cover by seeding, and
shadowing Earth by objects in space (82).
Perhaps most ambitious is a proposed 2000-
km-diameter mirror of 10-m glass fabricat-
ed from lunar materials at the L1 (83) La-
grange point of the Sun-Earth system (84)
(Fig. 3C). The mirror’s surface would look
like a permanent sunspot, would deflect 2%
of solar flux, and would roughly compensate
for the radiative forcing of a CO2 doubling.
Climate model runs indicate that the spatial
pattern of climate would resemble that with-
out fossil fuel CO2 (84). Engineering the
optical properties of aerosols injected to the
stratosphere to produce a variety of climatic
effects has also been proposed (85). Our as-
sessment reveals major challenges to stabiliz-
ing the fossil fuel greenhouse with energy
technology transformations. It is only prudent
to pursue geoengineering research as an in-
surance policy should global warming im-
pacts prove worse than anticipated and other
measures fail or prove too costly. Of course,
large-scale geophysical interventions are in-
herently risky and need to be approached
with caution.
Concluding Remarks
Even as evidence for global warming accu-
mulates, the dependence of civilization on the
oxidation of coal, oil, and gas for energy
makes an appropriate response difficult. The
disparity between what is needed and what
can be done without great compromise may
become more acute as the global economy
grows and as larger reductions in CO2-emit-
ting energy relative to growing total energy
demand are required. Energy is critical to
global prosperity and equity.
If Earth continues to warm, people may
turn to advanced technologies for solutions.
Combating global warming by radical re-
structuring of the global energy system could
be the technology challenge of the century.
We have identified a portfolio of promising
technologies here—some radical departures
from our present fossil fuel system. Many
concepts will fail, and staying the course will
require leadership. Stabilizing climate is not
easy. At the very least, it requires political
will, targeted research and development, and
international cooperation. Most of all, it re-
quires the recognition that, although regula-
tion can play a role, the fossil fuel greenhouse
effect is an energy problem that cannot be
simply regulated away.
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1.42 TW-year; natural gas includes liquids, excludes
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for support in this work.
S C I E N C E ’ S C O M P A S S
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