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2011 World Materials Summit addresses energy, sustainability, and water

http://www.mrs.org/2011wms

Published online by Cambridge University Press:  17 February 2012

Abstract

Type
News
Copyright
Copyright © Materials Research Society 2012

The 2011 World Materials Summit, held on October 9–12, 2011, at the L’Enfant Plaza Hotel in Washington, DC, provided a forum for top decision makers and energy experts from around the world to focus on the materials research needs for the growing energy economy. Organized jointly by the Materials Research Society (MRS), the European MRS (E-MRS), and the Chinese MRS (C-MRS), the goal of the Summit was to explore how the different regions of the world can work together on the critical issue of clean energy, including its relation to environmental sustainability and water. The participants considered the area of materials research as well as advocacy, economics, outreach, and education. The Summit was chaired by Gabriel Crean of the Commissariat à l’Energie Atomique (CEA) (Europe), David Ginley of the National Renewable Energy Laboratory (USA), Yafang Han of the Beijing Institute of Aeronautical Materials (China), and Alan Hurd of Los Alamos National Laboratory (USA).

The 2011 World Materials Summit was chaired by (left to right): Alan Hurd (Los Alamos National Laboratory; Santa Fe Institute), Gabriel Crean (Commissariat à làEnergie Atomique), Yafang Han (Beijing Institute of Aeronautical Materials), and David Ginley (National Renewable Energy Laboratory).

Realizing that the concerns are long-term and that young players will ultimately be the ones who are going to need to solve the energy challenges, the chairs of this year’s Summit inaugurated a Student Congress, a program for graduate students and postdoctoral scholars in fields directly related to energy and environmental science, engineering, and/or policy. The top 45 candidates coming from 18 countries were selected on a competitive basis to participate in the Student Congress. The participants were invited to a day of tutorials to help them get up to speed with their more seasoned colleagues.

They then joined their colleagues for a day of overview presentations followed by a day of breakout sessions by topic. Participants of the Summit utilized these breakout discussions in order to assess and document global research and innovation needs, develop policies, and outline the future of advanced energy materials. The four-day effort culminated in a 2011 World Materials Summit Declaration delineating materials directions related to global access to clean energy and water in a sustainable way.

Political landscape

The Summit opened with keynote addresses by prominent representatives of the United States, Europe, China, and Mexico. They presented government policy and activity regarding materials for energy.

Steven Koonin, Undersecretary for Science at the U.S. Department of Energy, summarized DOE’s inaugural Quadrennial Technology Review, which is intended to provide a systematic method to review the Department’s research and development (R&D) portfolio. The report defines six key strategies. Under the “transport” sector, DOE will devote its greatest effort to electrification of the vehicle fleet, including an increase in vehicle efficiency and deployment of alternative hydrocarbon fuels. In the “stationary” heat and power sector, the report finds that the Department should increase emphasis on efficiency and understanding the grid. DOE should also support R&D toward increasing building and industrial efficiency and toward deployment of clean energy. The report was released last September and can be accessed at www.energy.gov/QTR.

Summit co-chair Gabriel Crean, Vice President of Technology for CEA, France, gave the audience a European perspective on energy and sustainability. The European Commission has established “Key Enabling Technologies (KETs)” on which to focus scientific research. In materials research, the six KETs are advanced materials, nanotechnology, micro- and nano-electronics, photonics, biotechnology, and advanced manufacturing. “KETs are essential to the development and manufacture of advanced products,” Crean said. The final report by the high-level expert group on Key Enabling Technologies was released last June and is available on the European Commission website at ec.europa.eu.

Sergio Alcocer, Undersecretary for Energy Planning and Technology Development for Mexico, gave a broad overview of his country’s energy sector. Under the Ministry of Energy there are two government-owned companies—PEMEX and CFE—three national energy research institutes, and four commissions. Alcocer reported some turmoil in Mexico over decisions to relax rules governing state-owned companies to increase investment capabilities. With this reform Mexico will be able to produce 3.3 million barrels of oil per day by 2024; without reform, this will be 2.2 million barrels per day. Alcocer also addressed researching nanotechnology in solar energy. He said Mexico’s long-term strategy in energy focuses on energy security, efficiency, and sustainability. He further said that within Mexico’s strategic partnership with the United States and Canada such topics become areas of opportunity for strengthening collaboration and establishing long-term, visionary, synergistic efforts in the region.

Dujin Wang of the Chinese Academy of Sciences (speaking on behalf of Xianhong Wang), made reference to the challenges in reducing the amount of CO2 emissions, then spoke not of China’s governmental policy initiatives, but of the more technical aspect of CO2 as a feedstock for polymers. The most studied polymer in this field, according to Wang, is poly(propylene carbonate) (PPC). PPC is transparent, biodegradable, and a good oxygen barrier, but it has a low glass-transition temperature. Wang covered the evolution of this “ecopolymer” from a laboratory curiosity to industry activity in China.

Smart grid

Among the objectives of the Summit is to secure and develop a worldwide smart grid. In a plenary presentation, Paul Waide, director of European Energy Practice at Navigant Consulting, said that some of the main problems of today’s grid are that electricity transfer is one way, transmission and distribution losses are as high as 15%, and metering is not sophisticated, which leaves consumers confused about the costs of electricity. The solution will be a smart grid that uses digital technology to monitor and manage the generation and transmission of electricity from all sources (traditional and renewable) in order to meet the varying electrical demands of end users as efficiently as possible, according to Waide.

During a breakout session, a subgroup of the attendees determined that some of the regional smart-grid roadmaps may be deployable in the 2025–2050 time frame, but that worldwide development will need more time. The main materials challenges to establishing sustainable power grids reside in developing new energy storage materials, new methods of transmitting electricity efficiently over long distances, and control systems and smart materials for grid communications and control. The needs of longer term cable materials research include high-temperature superconductors, smart materials to mitigate natural risks, and heat- and flame-resistant polymers.

According to the group, many regional areas have roadmaps but broader international collaboration is needed to accelerate the developments in this field. Furthermore, the materials community needs to be made an integral partner in the discussion of smart-grid development as several technology issues, namely, storage and transmission, are fundamentally materials issues.

Resource availability and life-cycle analysis

All materials and processes have an environmental impact along their life cycles, said plenary speaker Duan Weng of Tsinghua University. However, it is not always easy to determine which material or option is better for the environment. For example, while the silicon solar cell is “green” during operation, it takes 3–5 years to reclaim the energy consumed during its manufacture. And while the electric vehicle is “green” during use, consideration must be given to the source of electricity and hydrogen. In China, about 80% of electricity comes from coal-fired power, said Weng. Life-cycle analysis can serve as a key component in materials selection and development, as various countries are becoming aware and determining policy to support it.

Another aspect of energy and sustainability is access to certain materials. “The materials community should be aware of risks associated with resource availability,” said plenary speaker Randolph Kirchain of the Massachusetts Institute of Technology. When the cost of a resource skyrockets due to temporary scarcity, price changes can be temporary, but the effects on a manufacturing company can be permanent, he said.

A long-term goal, according to a breakout session on a topic related to sustainability, is having the raw materials required for energy technologies when they are needed, provided sustainably, at an affordable price. Analysis methods for resource production include consideration of the materials, the use of water and energy, and the effect on land and emission of greenhouse gases. The group in this session identified numerous opportunities for materials research, including the science for substitutions through materials discovery (e.g., alloys, nanomaterials, and components) in terms of composition, structure, and morphology. The group also cited opportunities in research on properties of and processes using recycled metals, efficient chemistries using CO2 as a raw material, and in developing more efficient and benign extraction and refinement processes. The group also advocates international cooperation in areas such as coordination of research needs as well as programs and networks of information.

Water use and purification

Plenary speaker David Cahill of the University of Illinois, Urbana-Champaign illustrated the interdependent relationship of water and energy. Energy and power production require water in the areas of thermoelectric cooling, hydropower, production of fossil fuels and biofuels, and CO2 separation and sequestration, for example. Likewise, energy is needed for water treatment and distribution.

According to the breakout group that studied materials research opportunities for water, current trends in water purification and wastewater treatment include increased use of membrane separations and increased use of advanced oxidation for disinfection and the destruction of low-level toxic contaminants. Among the key goals the group identified is the development of low-cost, robust clean water systems with minimal energy and chemical inputs that can be deployed worldwide.

Significant reduction in costs can be achieved by developing materials with multiple functions. For example, membranes with the ability to self-clean or membranes that can both separate and disinfect could transform membrane processes, the group said. “Molecular level understanding of membrane separations is currently lacking,” reported the group. For example, they said, “There is no quantitative understanding of the connections between the molecular structure of the membrane and water permeability.” Such gaps in knowledge stand in the way of designing new materials for specific applications.

Energy sectors

Plenary speakers and subgroup discussions also addressed various energy sectors. Jerry Gibbs of U.S. DOE Vehicle Technologies said that oil is predominantly a transportation energy problem. Reduction of oil consumption will depend on alternative fuels and electrification of vehicles, hybridization, efficiency increases in internal combustion engines, and lightweighting of vehicles. A 10% mass reduction in an electric vehicle will result in a 10% increase in driving distance, Gibbs said.

In addressing renewable energy, George Crabtree of Argonne National Laboratory and the University of Illinois at Chicago said, “Complex, high-tech materials and chemistry are both the driver and the bottleneck for raising the performance and lowering the cost of renewable energy.” He said that with traditional energy sources, the most important “material” is the fuel that is burned to turn heat into work. In the sustainable regime, the most important “material” is unused energy flow, he said.

Patrick Bressler of Fraunhofer-Gesellschaft, Institute for Solar Energy Systems (ISE) said that the photovoltaics market is forecasted to be 110 GW in Germany by 2020, which he said will require a “huge growth rate” to achieve. German public opinion is strongly against nuclear energy because the risk is not considered acceptable, according to Bressler. The government announced a policy of shutting down all nuclear power reactors by 2022, and replacing most of the lost power with renewable resources.

V.S. Arunachalam of the Center for Study of Science, Technology and Policy in Bangalore said there is a future for nuclear power, despite radiation fears, and safety and security concerns, because Generation 4 nuclear reactors, including fast breeder reactors and supercritical water-cooled reactors, will be much safer. “We must learn to live with complex systems,” Arunachalam said.

A dialogue on nuclear energy continued in one of the breakout sessions and a panel presentation, engaging the delegates in one of the most controversial discussions of the Summit. While individual countries will approach the topic differently, it is likely that nuclear power will continue to be used as a source of energy. “Meeting materials challenges is a key technology response to provide ‘safer’ nuclear energy, specifically radioactive material control, extended life plant operation, and safety associated with decay heat removal in the extreme case of station blackouts,” reported the panel on this topic. “Building active collaborations among the countries performing nuclear research will expedite materials solutions,” the panel said.

A long-term vision in the building sector is to strengthen relationships among materials researchers, building scientists, architects, the building materials industry, and policymakers in order to achieve a 50% reduction in global energy consumption in buildings by 2030.

Along with the identification of materials challenges in this area, the breakout group realized cultural differences must also be recognized and understood. “A crucial stumbling block in the building industry is in assuming that all buildings exist in that singular country,” said the panel. “Western researchers do not typically have a strong familiarity with the Chinese-built environment and social considerations, especially in rural areas,” the panel reported. The panelists recommended opportunities in international collaboration in order to accelerate progress.

The participants in the Student Congress, many of whom met with colleagues from other parts of the world for the first time, were most instrumental in determining the urgency as well as the challenges for international collaboration. For example, in recognizing that decisions about the usage of energy and technology in each region are best made by local decision makers, they advocated the development of unbiased information to be shared across borders. The materials community should increase its efforts to standardize metrics such as greenhouse gas emissions, life-cycle analysis, risk assessment and reduction, and region-specific assessment of potential technologies which can then help researchers and policymakers determine best solutions for the specific needs of their region.

Most of the presentations from the speakers as well as each breakout session and a set of panels by the Student Congress are posted on the 2011 World Materials Summit website at www.mrs.org/2011wms. Their reports are also being posted upon completion. For ongoing discussion two LinkedIn groups were formed, World Materials Summit Student Congress 2011, and a broader one, Materials for Energy and Sustainable Development.

This Summit marked the third in a series sponsored by the three Societies. Prior Summits were held in Lisbon, Portugal, and Suzhou, China.

The 2011 World Materials Summit was funded, in part, by the National Science Foundation, the Office of Basic Energy Sciences, the Office of Naval Research, Aldrich Materials Science, Dow Chemical Company, American Elements, and the Materials Science and Engineering Expert Committee of the European Science Foundation.