Alternative Energy: Difference between revisions
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The technologies that form alternative energy vary immensity in [http://www.energy.gov/energysources/ type], innovation cycles, maturity and technoeconomic readiness. | The technologies that form alternative energy vary immensity in [http://www.energy.gov/energysources/ type], innovation cycles, maturity and technoeconomic readiness. | ||
"In sum, technological alternatives to fossil fuels do exist or can be realized. But few are technically or economically ready for deployment on the huge scale needed to make a dent in the demand for fossil fuels. Some are operating on a limited commercial scale, while others now exist only in the laboratory. To cite a few examples of what we can see today, solar photovoltaics are still too expensive, carbon capture and sequestration require prototyping and validation at a huge scale, batteries must realize further materials and cost advances, and fuel cells for transport applications face years of experimentation. Aside from the major research needed to keep rolling out advances for these technologies to cut costs and improve effi ciencies, there is a need for ongoing research to seek breakthroughs, especially if we decide we need to go beyond stabilizing the carbon dioxide concentration in the atmosphere at current levels by midcentury." (pg 5) (Weiss and Bonvillian 2009) | "In sum, technological alternatives to fossil fuels do exist or can be realized. But few are technically or economically ready for deployment on the huge scale needed to make a dent in the demand for fossil fuels. Some are operating on a limited commercial scale, while others now exist only in the laboratory. To cite a few examples of what we can see today, solar photovoltaics are still too expensive, carbon capture and sequestration require prototyping and validation at a huge scale, batteries must realize further materials and cost advances, and fuel cells for transport applications face years of experimentation. Aside from the major research needed to keep rolling out advances for these technologies to cut costs and improve effi ciencies, there is a need for ongoing research to seek breakthroughs, especially if we decide we need to go beyond stabilizing the carbon dioxide concentration in the atmosphere at current levels by midcentury." (pg 5) (Weiss and Bonvillian 2009) | ||
"Taken together, these technologies will still require massive investment, involving extensive collaboration between business, government, and universities" (pg 6) (Weiss and Bonvillian 2009) | |||
The main actors in this sector are government agencies, universities, and [https://cyber.law.harvard.edu/commonsbasedresearch/Bibliography_on_Industry_Profile Alternative Energy Companies]. Venture capitalists, nonprofit organizations, environmental advocates, and attorneys all play important supporting roles. | The main actors in this sector are government agencies, universities, and [https://cyber.law.harvard.edu/commonsbasedresearch/Bibliography_on_Industry_Profile Alternative Energy Companies]. Venture capitalists, nonprofit organizations, environmental advocates, and attorneys all play important supporting roles. |
Revision as of 13:11, 16 April 2009
Field definition
The alternative energy sector is defined by technology that produces energy while causing less environmental damage than traditional means of energy production, such as fossil fuels. Its importance is not only environmental, but also geopolitical. The goal of energy security - a deeper politicized issue - can be understood by the USA objectives of reducing the dependency on foreign sources of fossil fuels and controlling prices, and achieving a diversity of energy supplies.
The technologies that form alternative energy vary immensity in type, innovation cycles, maturity and technoeconomic readiness.
"In sum, technological alternatives to fossil fuels do exist or can be realized. But few are technically or economically ready for deployment on the huge scale needed to make a dent in the demand for fossil fuels. Some are operating on a limited commercial scale, while others now exist only in the laboratory. To cite a few examples of what we can see today, solar photovoltaics are still too expensive, carbon capture and sequestration require prototyping and validation at a huge scale, batteries must realize further materials and cost advances, and fuel cells for transport applications face years of experimentation. Aside from the major research needed to keep rolling out advances for these technologies to cut costs and improve effi ciencies, there is a need for ongoing research to seek breakthroughs, especially if we decide we need to go beyond stabilizing the carbon dioxide concentration in the atmosphere at current levels by midcentury." (pg 5) (Weiss and Bonvillian 2009)
"Taken together, these technologies will still require massive investment, involving extensive collaboration between business, government, and universities" (pg 6) (Weiss and Bonvillian 2009)
The main actors in this sector are government agencies, universities, and Alternative Energy Companies. Venture capitalists, nonprofit organizations, environmental advocates, and attorneys all play important supporting roles.
Conferences and State Task Forces provide important collaboration opportunities. Identification of challenges and opportunities for projects may be established at these meetings and collaboration continues through email contact and conference calls.
Government agencies and universities appear to be more eager to participate in data sharing than energy companies who are less consistent in sharing their data. While there may be differences between the main actors when it comes to data and research sharing, collaboration on policy appears to be strong from all the actors in this sector.
An example of industry collaboration can be seen in the “Iowa Alliance for Wind Innovation and Novel Development” which is a partnership between “state and local governments, the community colleges, universities, the private sector, associations and community organizations, and the federal government.”
The information above is largely the result of impressions of the alternative energy sector collected through research and experience.
Study of the field
Analysis of the field with basis on Field Research Methodology
- Overview of Economics of Intellectual Property in AE
- Give an overall picture of the AE field
- Outputs and Products of the field: data, narratives and tools produced by the AE field
- Legal tools available for and in use by the actors of AE field: IP in AE
- competitive advantages in AE
- IP Profile of Biggest for-profit companies in AE
- IP Profile of non-profit companies in AE
- IP Profile of Universities working in AE
- IP Profile of Associations in AE
- Commons based cases in AE
Bibliographies Addressing Research Outline
Bibliography for Item 1 in AE
Bibliography for Item 2 in AE
Bibliography for Item 3 in AE
Bibliography for Item 4 in AE
Bibliography for Item 5 in AE
Bibliography for Item 6 in AE
Bibliography for Item 7 in AE
Bibliography for Item 8 in AE
Bibliography for Item 9 in AE
Bibliography for Item 10 in AE
Resources
Special Case Studies in AE
Under this section we will explore possible special case studies that will be later trasformed in papers under AE Field Intellectual Property Profile.
- http://www2.dupont.com/Energy_and_Utilities/en_US/
- http://www2.dupont.com/Open_Science/en_US/global_energy.html
Links in AE
Blogs and news from the AE field
Interviews
Possible candidates for interviews: