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Thursday, August 29, 2013

Solar Classroom Update: Making Clean Energy Upgrades a Back-to-School Priority


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 28, 2013

Solar Classroom Update: Making Clean Energy Upgrades a Back-to-School Priority

It’s five weeks into the school year at the Central Park School for Children in Durham, North Carolina, and each and every week, the students in Aaron Sebens's fourth-grade class have successfully used solar energy to power their classroom. “We’re able to run everything we want to off of our solar electricity,” said Aaron.
Back in June, Energy.gov brought you Aaron’s story, an educator who inspired his students to problem-solve their way to a solar-powered classroom. One of the most important takeaways from the experience: clean energy upgrades are more within reach than many realize. “Fourth graders can understand how solar power works and that it can work for everyone,” said Aaron.
Every year, K-12 schools in the U.S. spend $6 billion on energy costs. To address high-energy expenditures, thousands of schools across the country are investing in comprehensive clean energy upgrades—from solar installations to added insulation to air sealing. Comprehensive energy upgrades for schools can provide a range of benefits—boosting efficiency, improving heating and cooling and increasing comfort. Probably the most important benefit, these investments can help schools lower energy bills and allow them to spend more money on educating students. For the complete story, see the Energy Blog.

EPA, NREL Screen Contaminated Sites for Renewable Energy Potential


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 28, 2013

EPA, NREL Screen Contaminated Sites for Renewable Energy Potential

The U.S. Environmental Protection Agency (EPA) on August 5 updated its RE-Powering mapping and screening tool, which will now provide preliminary screening results for renewable energy potential at 66,000 contaminated lands, landfills, and mine sites across the country. Working in collaboration with the Energy Department’s National Renewable Energy Laboratory (NREL), RE-Powering developed screening criteria for solar, wind, biomass, and geothermal potential at various levels of development.
The RE-Powering America’s Land Initiative, started by EPA in 2008, encourages development of renewable energy on potentially contaminated land, landfills, and mine sites when it is aligned with a community’s vision for the site. Pulling from EPA databases of potentially and formerly contaminated lands, as well as partnering with state agencies from California, Hawaii, New Jersey, New York, Oregon, Pennsylvania, Virginia, and West Virginia, the RE-Powering Initiative expanded the universe of sites from 24,000 to more than 66,000.
The updated tool provides insight into the significant potential for renewable energy generation on contaminated lands and landfills nationwide. For solar energy alone, EPA identified more than 10,000 contaminated sites with the potential to install a 300-kilowatt solar array or greater. Based on mapped acreage, these sites could cumulatively host solar energy systems that capture greater than 30 times more solar energy than all renewable energy systems operating in the United States today. See the EPA press release and the RE-Powering mapping tool.

Renewable Energy Provided Nearly 50% of 2012 U.S. Added Capacity


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 28, 2013

Renewable Energy Provided Nearly 50% of 2012 U.S. Added Capacity

Renewable energy sources in the United States accounted for nearly 50% of U.S. electric capacity added in 2012, according to a new report. Wind deployment added a record 13,124 megawatts (MW) of capacity, and solar added 3,313 MW of capacity, according to the latest edition of the Ernst & Young report on U.S. renewable energy attractiveness indices. The report highlights trends in U.S. renewable investment and ranks the states in terms of their attractiveness for clean technology investment. The indices provide scores for state renewable energy markets, renewable energy infrastructures, and their suitability for individual technologies, and are updated on a biannual basis.
California led the nation in the report's measure of all renewable energy attractiveness, followed by Hawaii, Texas, Colorado, and Nevada. Texas was the leader in the actual installed wind base. See the Ernst & Young press release and the latest indices report.

EPA Kicks Off Energy Star National Building Competition


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 28, 2013

EPA Kicks Off Energy Star National Building Competition

The U.S. Environmental Protection Agency (EPA) on August 20 launched the 2013 Energy Star National Building Competition: Battle of the Buildings. Teams from more than 3,000 buildings across the country are competing to see who can most reduce their buildings’ energy use. In support of President Obama’s Climate Action Plan, which calls for buildings to cut waste and become at least 20% more energy efficient by 2020, the competition specifically targets wasted energy in commercial buildings and motivates businesses to improve energy efficiency, reduce harmful carbon pollution, and save money.
More than 25 different types of commercial buildings are facing off in this year’s Energy Star National Building Competition, representing all 50 states, the District of Columbia, Puerto Rico, and the U.S. Virgin Islands. The diverse field of competitors includes the Hard Rock Hotel in Orlando, Florida; a Catholic cathedral and rectory in Seattle, Washington; New York City’s historic 100 Park Avenue building; and Busch Stadium—home of the St. Louis Cardinals in St. Louis, Missouri. Competitors measure and track their buildings’ monthly energy consumption using Portfolio Manager, EPA's Energy Star online energy measurement and tracking tool, and work over the year to cut energy waste through improvements that range from equipment replacement to changes in occupant behavior. Midpoint “weigh-in” results will be posted in December, with the winner announced in April 2014.
The number of participants in the Battle of the Buildings has increased from 14 buildings in 2010—the competition’s first year—to more than 3,200 buildings in 2013. Altogether, last year’s competitors cut their energy costs by more than $50 million and reduced annual greenhouse gas emissions equal to the electricity used by more than 43,000 homes. Commercial buildings in the United States are responsible for approximately 20% of both the nation’s energy use and greenhouse gas emissions at a cost of more than $100 billion annually. See the EPA press release and the Battle of the Buildings website.

USDA Awards $21 Million to Renewable and Energy Efficiency Projects


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 28, 2013

USDA Awards $21 Million to Renewable and Energy Efficiency Projects

The U.S. Department of Agriculture (USDA) on August 15 announced more than $21 million in funding for 631 projects across the nation that will help agricultural producers and rural small businesses reduce their energy consumption and costs, use renewable energy technologies in their operations, and conduct feasibility studies for renewable energy projects. Farmers, ranchers, business owners, and agriculture producers in 42 states, the U.S. Virgin Islands, and Puerto Rico will receive funding. Grants and loans are made through the USDA's Rural Energy for America Program (REAP).
REAP helps producers reduce energy costs and increase production efficiency. For example, a family in North Carolina will use a $7,403 grant to install an energy-efficient geothermal system. And a nursery in Nevada will use a $12,476 grant to install a solar photovoltaic system to provide power for its farm and nursery. Under the terms of REAP, up to 25% of an eligible energy production or conservation project can be funded through a grant, and additional support can be provided in the form of a loan. Since the start of the Obama Administration, REAP has helped fund nearly 7,000 renewable energy and energy efficiency projects nationwide.
The funding includes almost $300,000 in grants to 19 agricultural producers and rural businesses to conduct feasibility studies for renewable energy systems. For example, the Gunnison County Electric Association, Inc., in Gunnison, Colorado, will receive a $6,739 grant to assess the feasibility of installing a small hydropower generating plant at the Taylor Reservoir Dam. If built, the plant would generate 4 megawatts of power. See the USDA press release.

Hydrogen Fuel From Sunlight

Berkeley Lab Researchers at Joint Center for Artificial Photosynthesis Make Unique Semiconductor/Catalyst Construct

AUGUST 29, 2013
Lynn Yarris (510) 486-5375  lcyarris@lbl.gov
 21 
 
 
   
Feature
For more than two billion years, nature, through photosynthesis, has used the energy in sunlight to convert water and carbon dioxide into fuel (sugars) for green plants. (Photo by Roy Kaltschmidt)
For more than two billion years, nature, through photosynthesis, has used the energy in sunlight to convert water and carbon dioxide into fuel (sugars) for green plants. (Photo by Roy Kaltschmidt)
In the search for clean, green sustainable energy sources to meet human needs for generations to come, perhaps no technology matches the ultimate potential of artificial photosynthesis. Bionic leaves that could produce energy-dense fuels from nothing more than sunlight, water and atmosphere-warming carbon dioxide, with no byproducts other than oxygen, represent an ideal alternative to fossil fuels but also pose numerous scientific challenges. A major step toward meeting at least one of these challenges has been achieved by researchers with the U.S. Department of Energy (DOE)’s Lawrence Berkeley National Laboratory (Berkeley Lab) working at the Joint Center for Artificial Photosynthesis (JCAP).
“We’ve developed a method by which molecular hydrogen-producing catalysts can be interfaced with a semiconductor that absorbs visible light,” says Gary Moore, a chemist with Berkeley Lab’s Physical Biosciences Division and principal investigator for JCAP. “Our experimental results indicate that the catalyst and the light-absorber are interfaced structurally as well as functionally.”
Moore is the corresponding author, along with Junko Yano and Ian  Sharp, who also hold joint appointments with Berkeley Lab and JCAP, of a paper describing this research in theJournal of the American Chemical Society (JACS). The article is titled
“Photofunctional Construct That Interfaces Molecular Cobalt-Based Catalysts for H2Production to a Visible-Light-Absorbing Semiconductor.” Co-authors are Alexandra Krawicz, Jinhui Yang and Eitan Anzenberg.
Earth receives more energy in one hour’s worth of sunlight than all of humanity uses in an entire year. Through the process of photosynthesis, green plants harness solar energy to split molecules of water into oxygen, hydrogen ions (protons) and free electrons. The oxygen is released as waste and the protons and electrons are used to convert carbon dioxide into the carbohydrate sugars that plants use for energy. Scientists aim to mimic the concept but improve upon the actual process.
Gary Moore is a chemist with Berkeley Lab’s Physical Biosciences Division and principal investigator for the Joint Center for Artificial Photosynthesis. (Photo by Roy Kaltschmidt)
Gary Moore is a chemist with Berkeley Lab’s Physical Biosciences Division and principal investigator for the Joint Center for Artificial Photosynthesis. (Photo by Roy Kaltschmidt)
JCAP, which has a northern branch in Berkeley and a southern branch on the campus of the California Institute of Technology (Caltech), was established in 2010 by DOE as an Energy Innovation Hub. Operated as a partnership between Caltech and Berkeley Lab, JCAP is the largest research program in the United States dedicated to developing an artificial solar-fuel technology. While artificial photosynthesis can be used to generate electricity, fuels can be a more effective means of storing and transporting energy. The goal is an artificial photosynthesis system that’s at least 10 times more efficient than natural photosynthesis.
To this end, once photoanodes have used solar energy to split water molecules, JCAP scientists need high performance semiconductor photocathodes that can use solar energy to catalyze fuel production. In previous efforts to produce hydrogen fuel, catalysts have been immobilized on non-photoactive substrates. This approach requires the application of an external electrical potential to generate hydrogen. Moore and his colleagues have combined these steps into a single material.
“In coupling the absorption of visible light with the production of hydrogen in one material, we can generate a fuel simply by illuminating our photocathode,” Moore says. “No external electrochemical forward biasing is required.”
The new JCAP photocathode construct consists of the semiconductor gallium phosphide and a molecular cobalt-containing hydrogen production catalyst from the cobaloxime class of compounds. As an absorber of visible light, gallium phosphide can make use of a greater number of available solar photons than semiconductors that absorb ultraviolet light, which means it is capable of producing significantly higher photocurrents and rates of fuel production. However, gallium phosphide can be notoriously unstable during photoelectrochemical operations.
Gary Moore is a chemist with Berkeley Lab’s Physical Biosciences Division and principal investigator for the Joint Center for Artificial Photosynthesis. (Photo by Roy Kaltschmidt)
Grafting molecular cobalt-containing hydrogen production catalysts to a visible-light-absorbing semiconductor exploits the UV-induced immobilization chemistry of vinylpyridine to p-type (100) gallium phosphide (GaP).
Moore and his colleagues found that coating the surface of gallium phosphide with a film of the polymer vinylpyridine alleviates the instability problem, and if the vinylpyridine is then chemically treated with the cobaloxime catalyst, hydrogen production is significantly boosted.
“The modular aspect of our method allows independent modification of the light-absorber, linking material and catalyst, which means it can be adapted for use with other catalysts tethered over structured photocathodes as new materials and discoveries emerge,” Moore says. “This could allow us, for example, to replace the precious metal catalysts currently used in many solar-fuel generator prototypes with catalysts made from earth-abundant elements.”
Despite its promising electronic properties, gallium phosphide features a mid-sized optical band gap which ultimately limits the total fraction of solar photons available for absorption. Moore and his colleagues are now investigating semiconductors that cover a broader range of the solar spectrum, and catalysts that operate faster at lower electrical potentials. They also plan to investigate molecular catalysts for carbon dioxide reduction.
“We look forward to adapting our method to incorporate materials with improved properties for converting sunlight to fuel,” Moore says. “We believe our method provides researchers at JCAP and elsewhere with an important tool for developing integrated photocathode materials that can be used in future solar-fuel generators as well as other technologies capable of reducing net carbon dioxide emissions.”
This research was funded by the DOE Office of Science.
Additional Information
For more about JCAP go here
#  #  #
Lawrence Berkeley National Laboratory addresses the world’s most urgent scientific challenges by advancing sustainable energy, protecting human health, creating new materials, and revealing the origin and fate of the universe. Founded in 1931, Berkeley Lab’s scientific expertise has been recognized with 13 Nobel prizes. The University of California manages Berkeley Lab for the U.S. Department of Energy’s Office of Science. For more, visit www.lbl.gov.
DOE’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit the Office of Science website atscience.energy.gov/.

Wednesday, August 28, 2013

NextFuels to Produce Biofuels from Palm Plantation - REW - Renewable Energy from Waste

NextFuels to Produce Biofuels from Palm Plantation - REW - Renewable Energy from Waste

Q&A: The Facility for Low Energy eXperiments in Buildings (FLEXLAB)

AUGUST 27, 2013
Allan Chen   a_chen@lbl.gov
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Science Short
The Facility for Low Energy eXperiments in Buildings (FLEXLAB) is designed to be a national focal point for developing, simulating and testing energy-efficient technologies and strategies for buildings. FLEXLAB users will conduct research and develop technologies at FLEXLAB on single components as well as whole-building integrated design and operation aimed at substantially lowering the energy use, and improving the comfort and performance of both new and existing buildings. FLEXLAB is a facility of Lawrence Berkeley National Laboratory’s Environmental Energy Technologies Division (EETD).
In the following Q&A, Cindy Regnier, FLEXLAB’s manager, discusses FLEXLAB’s capabilities, and how its users will be able to use the facility when it opens.
How is the construction of FLEXLAB going? When will it be ready for users?
Rendering of Berkeley Lab's FLEXLAB
Rendering of Berkeley Lab's FLEXLAB
Construction is going well. At this point, FLEXLAB is on time and on budget, and construction should be complete in early 2014, including the commissioning process. Following that, we will put the facility through a calibration process to determine testbed accuracies, begin testing the data acquisition system and gathering baseline data from its many sensors.
Who do you expect will be the primary users of FLEXLAB when it is completed? And what needs does FLEXLAB address for these users?
The diversity of users is broad—maybe broader than you think. FLEXLAB can address the energy efficiency needs of utilities, federal and state research programs, manufacturers, building owners and the AECO [architecture, engineering, construction and owner-operated] community.
Product manufacturers of almost any type of building product or service are a natural user group for FLEXLAB, which can help extend the impact and market potential of products by developing integrated design solutions—such as automated shading coupled with dimmable lighting systems—that validate performance (for example, visual comfort,) as well as energy savings.
FLEXLAB can also help where they’ve developed emerging technology whose performance isn’t yet recognized in industry—for example, code, or simulation tools—they need verified performance data and a means to extend results to the rest of industry.
We expect to work with the AECO community, too. The developer and AECO community is increasingly being asked to deliver guaranteed performance of building designs, whether for energy performance disclosure laws or for other energy efficiency-related purposes. The community currently only develops mockups for constructability, not verification of energy or comfort performance. Verification of a design’s energy and overall performance in FLEXLAB lowers risk for the construction of the facility, especially where there are unique combinations of low energy systems, or high-risk elements that might affect comfort and performance such as full height glazing.
AECO users will be able to specify and test innovative systems for their designs in one or more of FLEXLAB’s testbeds, and use feedback data from their operation to improve their designs. Building new energy-efficient buildings, or improving the energy performance of existing buildings in an investment portfolio enhances value. The AECO community will develop higher confidence in and reduce financial risk of new innovative design strategies with higher energy efficiency targets. This is a capability that can differentiate the truly innovative AECO firms in the marketplace.
Utilities need verified performance of emerging technologies to increase certainty on their impact on energy use, as well as R&D in emerging areas of energy reduction strategies to meet their energy efficiency programmatic goals, such as whole building integrated system performance.
To read the rest of this Q&A, go here.

Friday, August 23, 2013

NREL Study Suggests Cost Gap for Western Renewables Could Narrow by 2025


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NREL Press Release:

NREL Study Suggests Cost Gap for Western Renewables Could Narrow by 2025

Friday, August 23, 2013

A new Energy Department study conducted by the National Renewable Energy Laboratory (NREL) indicates that by 2025 wind and solar power electricity generation could become cost-competitive without federal subsidies, if new renewable energy development occurs in the most productive locations.
The report, "Beyond Renewable Portfolio Standards: An Assessment of Regional Supply and Demand Conditions Affecting the Future of Renewable Energy in the West," compares the cost of renewable electricity generation (without federal subsidy) from the West's most productive renewable energy resource areas--including any needed transmission and integration costs--with the cost of energy from a new natural gas-fired generator built near the customers it serves.

"The electric generation portfolio of the future could be both cost effective and diverse," said NREL Senior Analyst David Hurlbut, the report's lead author. "If renewables and natural gas cost about the same per kilowatt-hour delivered, then value to customers becomes a matter of finding the right mix.
"Renewable energy development, to date, has mostly been in response to state mandates," Hurlbut said. "What this study does is look at where the most cost-effective yet untapped resources are likely to be when the last of these mandates culminates in 2025, and what it might cost to connect them to the best-matched population centers."
The study draws on an earlier analysis the lab conducted for the Western Governors' Association to identify areas where renewable resources are the strongest, most consistent, and most concentrated, and where development would avoid protected areas and minimize the overall impact on wildlife habitat.
Among the study's findings:
  • Wyoming and New Mexico could be areas of robust competition among wind projects aiming to serve California and the Southwest. Both states are likely to have large amounts of untapped, developable, prime-quality wind potential after 2025. Wyoming's surplus will probably have the advantage of somewhat higher productivity per dollar of capital invested in generation capacity; New Mexico's will have the advantage of being somewhat closer to the California and Arizona markets.
  • Montana and Wyoming could emerge as attractive areas for wind developers competing to meet demand in the Pacific Northwest. The challenge for Montana wind power appears to be the cost of transmission through the rugged forests that dominate the western part of the state.
  • Wyoming wind power could also be a low-cost option for customers in Utah, which also has its own diverse portfolio of in-state resources.
  • Colorado is a major demand center in the Rockies and will likely have a surplus of prime-quality wind potential in 2025. However, the study suggests that Colorado is likely to be isolated from future renewable energy trading in the West due to transmission costs between the state and its Rocky Mountain neighbors.
  • California, Arizona, and Nevada are likely to have surpluses of prime-quality solar resources. None is likely to have a strong comparative advantage over the others within the three-state market, unless environmental or other siting challenges limit in-state development. Consequently, development of utility-scale solar will probably continue to meet local needs rather than expand exports.
  • New geothermal development could trend toward Idaho by 2025 since much of Nevada's resources have already been developed. Geothermal power from Idaho could be competitive in California as well as in the Pacific Northwest, but the quantity is relatively small. Reaching California, Oregon, and Washington may depend on access to unused capacity on existing transmission lines, or on being part of a multi-resource portfolio carried across new lines.
The study notes future electricity demand will be affected by several factors including: trends in the supply and price of natural gas; consumer preferences; technological breakthroughs; further improvements in energy efficiency; and future public policies and regulations. While most of these demand factors are difficult to predict, the study's supply forecasts rely on empirical trends and the most recent assessments of resource quality.
NREL is the U.S. Department of Energy's primary national laboratory for renewable energy and energy efficiency research and development. NREL is operated for the Energy Department by The Alliance for Sustainable Energy, LLC.
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Wednesday, August 21, 2013

eGallon and Electric Vehicle Sales: The Big Picture


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 21, 2013

eGallon and Electric Vehicle Sales: The Big Picture

For certain markets, time of year has a distinct effect on prices and/or sales volumes. For instance, sales of Halloween favors tend to be high in October and decline in November. But that drop in sales doesn’t spell doom for candy and costume shops. Similarly, falling peach harvests between August and October don’t say much about the overall health of the orchards. This seasonality is why we often look at year-on-year growth instead of month-to-month growth to determine market dynamics.
July exhibits some of that same seasonality for the electric vehicle (EV) market. Taken in this context, both the EV market and eGallon are performing extremely well.
Just like gasoline, the eGallon price tends to rise with the summer heat. This mostly results from increased electricity use associated with air conditioning. But despite this, the eGallon to gasoline ratio has held steady at about a 1:3—meaning that a gallon of unleaded gasoline is about three times as expensive as an eGallon. The average eGallon price for the country, which is based on May’s electricity prices, is now about $1.22—four cents higher than last month. Since our last eGallon update, gasoline prices have actually jumped about 7 cents to $3.56—though they too are down compared to this time last year. Use our eGallon tool to see gasoline and eGallon prices for your state. For the complete story, see the Energy Blog.

BLM Approves California Geothermal Development Project


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 21, 2013

BLM Approves California Geothermal Development Project

The Bureau of Land Management (BLM) and the U.S. Forest Service Inyo National Forest on August 13 signed the Record of Decision approving a new 40-megawatt geothermal project near Mammoth Lakes, California. The Casa Diablo IV Geothermal Development Project will be built on lands administered by the Inyo National Forest and on private lands within four existing federal geothermal leases. The project will include construction of a new geothermal power plant, up to 16 new production and injection wells, multiple pipelines, and an electric transmission line.
Ormat Nevada Inc. will develop the project on public and private land. When completed, the project would produce enough energy to power 36,000 homes. See theBLM press release.

Largest Federally-Owned Wind Farm Breaks Ground


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 21, 2013

Largest Federally-Owned Wind Farm Breaks Ground

The Energy Department on August 13 broke ground on the nation’s largest federally-owned wind project at the Pantex Plant in Amarillo, Texas. Once completed, this five-turbine 11.5 megawatt project will power more than 60% of the plant and reduce carbon emissions by more than 35,000 metric tons per year. The Pantex Plant is the primary site for the assembly, disassembly, and maintenance of the United States’ nuclear weapons stockpile.
Located on 1,500 acres east of the Pantex Plant, the wind farm will generate approximately 47 million kilowatt-hours of electricity annually—enough to power nearly 3,500 homes. The project is expected to complete construction and start generating electricity in summer 2014. See the Energy Department press release.

Energy Department Invests in Heating, Cooling, and Lighting


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 21, 2013

Energy Department Invests in Heating, Cooling, and Lighting

The Energy Department on August 14 announced 12 projects to develop innovative heating, cooling, and insulation technologies as well as open-source energy efficiency software to help homes and commercial buildings save energy and money. These projects will receive approximately $9 million from the Energy Department along with about $1 million in matching private sector funding.
The Energy Department will invest about $6 million for nine projects that will develop new energy efficient building technologies, including heating, ventilation, and air conditioning (HVAC) systems and building insulation. The projects will also help curb emissions of hydrofluorocarbons (HFCs), potent greenhouse gases primarily used in refrigeration and air conditioning. Among the selected projects, the Energy Department's National Renewable Energy Laboratory will develop affordable insulation plastic film for large windows. The Energy Department's Sandia National Laboratories along with United Technologies Research Center will help demonstrate a rotating heat exchanger technology for residential HVAC systems. And the Energy Department's Oak Ridge National Laboratory, along with Thermolift, Stony Brook University, and National Grid will help commercialize a natural gas heat pump to provide heating, cooling, and hot water for homes and commercial buildings. See the complete project list PDF.
Commercial and residential buildings use nearly 40% of the total energy consumed in the United States each year and produce more than 40% of the nation’s carbon pollution. According to the Energy Information Administration, about 48% of energy consumption in U.S. homes in 2009 was for heating and cooling, down from 53% in 1993. While better insulation and more efficient windows and equipment helped precipitate this decline, the projects announced are focused on furthering these savings.
The Energy Department also announced about $3 million to three projects—led by the University of California, Virginia Tech, and Carnegie Mellon University—to develop open source software that helps building owners and operators measure, monitor, and adjust lighting, HVAC, and water heating energy use to save energy without compromising performance. According to a study by the Energy Department's Pacific Northwest National Laboratory, commercial building owners could save an average 38% on heating and cooling bills by installing energy control systems. See the Energy Department press release.

DOI Establishes Renewable Energy Evaluation Area in California


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This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 21, 2013

DOI Establishes Renewable Energy Evaluation Area in California

The U.S. Department of Interior (DOI) on August 13 announced that it has approved the establishment of the West Chocolate Mountains Renewable Energy Evaluation Area (REEA) on public lands in California’s Imperial Valley. This REEA will prioritize the Bureau of Land Management (BLM) lands for the exploration and development of solar and geothermal energy. The BLM estimates that the 64,058-acre area has the potential to develop over 3,330 megawatts of solar power and 150 megawatts of geothermal power. The REEA creates a new Solar Energy Zone, which is part of the Obama Administration's efforts to facilitate solar energy development by identifying areas in six Western states with high solar potential, few resource conflicts, and access to existing or planned transmission.
As part of President Obama’s Climate Action Plan to reduce carbon pollution, move toward clean energy sources, and slow the effects of climate change, the Interior Department is working to approve 20,000 megawatts of renewable energy production on public lands by 2020. See the DOI press release.

NREL: Continuum Magazine - "Drop-In" Biofuels Solve Integration Issues?

NREL: Continuum Magazine - "Drop-In" Biofuels Solve Integration Issues?

Lab works to create biofuels indistinguishable from conventional petroleum-based fuels.

NREL: Continuum Magazine -

NREL: Continuum Magazine - Not Too Hot, Not Too Cold

NREL: Continuum Magazine - Not Too Hot, Not Too Cold

Deadline for NREL Director's Fellowships Approaching


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NREL News Release:

Deadline for NREL Director's Fellowships Approaching
Tuesday, August 20, 2013

The September 30 application deadline for scientists and engineers interested in participating in the Energy Department's National Renewable Energy Laboratory (NREL) Director's Fellowships program is quickly approaching.

NREL Director's Fellowships are designed to attract the next generation of exceptionally qualified scientists and engineers with outstanding talent and credentials in renewable energy research and related disciplines. Candidates must be recent Ph.D. graduates (within two years of completion), and demonstrate a promising career of leadership and research.

For more information, watch NREL's Research Participant Program Video (Preview) . Additional application information is available online; applications must be received by September 30.

NREL is the U.S. Department of Energy's primary national laboratory for renewable energy and energy efficiency research and development. NREL is operated for the Energy Department by The Alliance for Sustainable Energy, LLC.

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Solar Classroom Update: Making Clean Energy Upgrades a Back-to-School Priority | Department of Energy

Solar Classroom Update: Making Clean Energy Upgrades a Back-to-School Priority | Department of Energy

Tuesday, August 20, 2013

EMR, Chinook Sciences to Open WTE Plant in UK - REW - Renewable Energy from Waste

EMR, Chinook Sciences to Open WTE Plant in UK - REW - Renewable Energy from Waste

Covanta Acquires Camden Resource Recovery Facility - REW - Renewable Energy from Waste

Covanta Acquires Camden Resource Recovery Facility - REW - Renewable Energy from Waste

Germany Shatters Monthly Solar Generation Record With 5.1 Terawatt Hours of Clean Energy | Inhabitat - Sustainable Design Innovation, Eco Architecture, Green Building

Germany Shatters Monthly Solar Generation Record With 5.1 Terawatt Hours of Clean Energy | Inhabitat - Sustainable Design Innovation, Eco Architecture, Green Building

Alaska, Idaho, Oregon and Washington businesses compete to reduce energy costs and greenhouse gases in EPA’s Energy Star Battle of the Buildings


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EPA Press Release:

Alaska, Idaho, Oregon and Washington businesses compete to reduce energy costs and greenhouse gases in EPA’s Energy Star Battle of the Buildings

Contact:  Suzanne Skadowski, EPA Public Affairs, 206-295-4829, skadowski.suzanne@epa.gov

(Seattle – August 20, 2013) The U.S. Environmental Protection Agency today launched the 2013 Energy Star National Building Competition: Battle of the Buildings. Teams from more than 220 buildings in the Pacific Northwest -- 3,000 buildings nationwide -- are competing to see who can most reduce their buildings’ energy use.

“Battle of the Buildings is a great opportunity for businesses to save money while reducing carbon pollution that contributes to climate change,” said EPA Administrator Gina McCarthy. “These are the kinds of smart, innovative solutions that are going to help solve the environmental challenges we face today.”

Battle of the Buildings competitors in the Pacific Northwest include the Pioneer US Courthouse in Portland built in 1875 and buildings built in every decade from 1900 to 2010.  The top three competitors in the Pacific Northwest by numbers of buildings are Catholic Archdiocese of Seattle with 63 buildings competing in Washington, General Services Administration with 49 buildings in Alaska, Idaho, Oregon and Washington, and Union Bank with 31 buildings competing in Oregon and Washington.

Energy Star’s Battle of the Buildings motivates businesses to improve energy efficiency and save energy costs. Competitors measure and track their buildings’ monthly energy consumption using Portfolio Manager, EPA's Energy Star online energy measurement and tracking tool. Competitors cut energy waste through efficiency improvements from equipment replacement to changes in building occupant actions.

Commercial buildings are responsible for 20 percent of U.S. energy use and greenhouse gas emissions at a cost of more than $100 billion annually. By improving the energy efficiency where Americans work, play, and learn, Battle of the Buildings competitors will save energy and reduce greenhouse gas emissions to fight climate change. Last year’s competitors cut energy costs more than $50 million and reduced annual greenhouse gas emissions equal to the electricity used by more than 43,000 homes.

Peak Energy: Our Clean Energy Future

Peak Energy: Our Clean Energy Future

Thursday, August 15, 2013

Tacoma Completes Major Hydropower Upgrade at Cushman Dam

This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 14, 2013

Tacoma Completes Major Hydropower Upgrade at Cushman Dam

The Energy Department and the city of Tacoma on August 7 inaugurated a new powerhouse and fish passage facility at its Cushman Hydroelectric Project in Washington State, powering over 2,000 additional homes and reintroducing steelhead and salmon to their native habitats.
Tacoma Power's Cushman Hydroelectric Project installed a new two-generator powerhouse that increases electric generation capacity by 3.6 megawatts and captures energy from previously untapped water flows. The project also added an innovative elevator and transportation system to reintroduce Washington's endangered steelhead and salmon populations upriver from the Cushman Hydroelectric Project for the first time since the 1920s. This $28 million project was supported by a $4.7 million American Recovery and Reinvestment Act award from the Energy Department. See the Energy Department Progress Alert.

President Obama Signs Two Bills to Boost Small Hydropower Projects

This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 14, 2013

President Obama Signs Two Bills to Boost Small Hydropower Projects

President Obama on August 9 signed into law two bills aimed at boosting development of small U.S. hydropower projects. The bills, H.R. 267, the Hydropower Regulatory Efficiency Act, and H.R. 678, the Bureau of Reclamation Small Conduit Hydropower Development and Rural Jobs Act, are expected to help unlock some of the estimated 60,000 megawatts of untapped U.S. hydropower capacity.
H.R. 267 promotes the development of small hydropower and conduit projects and aims to shorten regulatory timeframes of certain other low-impact hydropower projects, such as projects that add power generation to the nation’s existing non-powered dams and closed-loop pumped storage projects.
H.R. 678 authorizes small hydropower development at existing canals, pipelines, aqueducts, and other manmade waterways owned by the U.S. Bureau of Reclamation. Such development could provide enough power for 30,000 U.S. homes. See theNational Hydropower Association press release PDF.

NREL Analyzes Solar Energy Land-Use Requirements






This is an excerpt from EERE Network News, a weekly electronic newsletter.

August 14, 2013

NREL Analyzes Solar Energy Land-Use Requirements

The Energy Department’s National Renewable Energy Laboratory (NREL) has published a report on the land use requirements of solar power plants based on land-use practices from existing solar facilities. The report, “Land-use Requirements for Solar Power Plants in the United States,” gathered data from 72% of the solar power plants currently installed or under construction in the United States.
Among the findings were that a large, fixed-tilt photovoltaic (PV) plant that generates 1 gigawatt-hour per year requires an average of 2.8 acres for the solar panels. This means that a solar power plant that provides electricity for 1,000 homes would require 32 acres of land. Also, small single-axis PV systems require on average 2.9 acres per annual gigawatt-hour, or 3.8 acres when considering all unused area that falls inside the project boundary. And finally, concentrating solar power plants require on average 2.7 acres per annual gigawatt-hour for solar collectors and other equipment, or 3.5 acres when considering all land enclosed within the project boundary.
By the third quarter of 2012, the United States had deployed more than 2.1 gigawatts of utility-scale solar power generation capacity, with another 4.6 gigawatts under construction. A previous NREL report, “Land-use Requirements and the Per-capita Solar Footprint for Photovoltaic Generation in the United States,” had estimated that if solar energy was to meet 100% of all electricity demand in the United States, it would take up 0.6% of the total area in the United States. For the newer report, the data come not from estimates or calculations, but from compiling land use numbers from actual solar power plants. See the NREL press release and complete reportPDF.

Smart Grid Market to Surpass $400 Billion Worldwide by 2020 : Greentech Media

Smart Grid Market to Surpass $400 Billion Worldwide by 2020 : Greentech Media

Low-temperature combustion enables cleaner, more efficient engines







Sandia Labs News Releases


Low-temperature combustion enables cleaner, more efficient engines

LIVERMORE, Calif.— As demand climbs for more fuel-efficient vehicles, knowledge compiled over several years about diesel engines and a new strategy known as “low-temperature combustion” (LTC) might soon lead auto manufacturers and consumers to broader use of cleaner diesel engines in the United States.
The journal Progress in Energy and Combustion Science published a summary of recent research on diesel LTC in a review article titled “Conceptual models for partially premixed low-temperature diesel combustion.” The article, prepared by researchers at Sandia National Laboratories, provides what the authors say is a necessary science base for auto and engine manufacturers to build the next generation of cleaner, more fuel-efficient engines using LTC.

Using new optical diagnostic techniques, Sandia National Laboratories combustion researcher Mark Musculus and his colleagues identified the sources of key pollutants from LTC engines. Understanding how LTC works as a combustion technique may lead to broader use of cleaner diesel engines.(Photo by Dino Vournas) Click on the thumbnail for a high-resolution image.
“Diesel engines are generally more efficient than gasoline engines,” said combustion researcher Mark Musculus, the lead author on the paper along with Sandia researchers Paul Miles and Lyle Pickett. “When long-haul truck drivers are burning thousands of gallons per year for cross-country freight runs, or when consumers are faced with high fuel prices, a more efficient engine becomes very important.” The increased efficiency also translates into lower carbon dioxide (CO2) emissions, which are a major driver of global climate change.
Though diesel engines are more efficient, they still have serious pollutant emissions problems.
Gasoline-powered engines have become ever cleaner by inserting better and better catalytic converters between the engine and the tailpipe to clean up pollutants created by the engine.
But the same catalytic converter that works so well for gasoline engines will not work for diesel engines. Other more complicated exhaust aftertreatment systems are deployed in modern diesel engines, but engine designers and operators would like to avoid the cost and efficiency penalties imposed by those systems.
“It would be great to find some other way to clean up the diesel engine if we want to enjoy its full efficiency advantages,” explained Musculus, “and LTC might just be the solution.”
Low-temperature combustion reduces NOx and smoke
Largely due to landmark work in the 1980s and 1990s at Sandia’s Combustion Research Facility(CRF) in California, researchers already understand how pollutants are created during conventional diesel combustion. Details of how conventional diesel combustion works – research that took advantage of special optical engines and diagnostics with lasers and scientific cameras to probe the combustion processes – were consolidated into a much-referenced conceptual model developed by Sandia’s John Dec in 1997.
The laser-based diagnostics showed that one pollutant, smoky particulate matter, or PM, was formed in regions where fuel concentrations were too high. Another serious pollutant, nitrogen oxides, or NOx, arose from a high-temperature flame inside the engine. NOx emissions are not only toxic, but once released into the atmosphere and exposed to sunlight, they react with other pollutants to create ground-level ozone, or smog.
LTC addresses the NOx emissions by recirculating some of the exhaust gases expelled by a diesel engine back inside the engine, where they absorb the heat from combustion. With this dilution effect, the combustion temperatures are lower so NOx formation is significantly reduced. The other part of the LTC strategy, Musculus said, is to spray in fuel earlier in the engine cycle to give the fuel more time to mix with air before it burns. LTC thereby avoids much of the fuel-rich regions that lead to PM as well as the high temperatures that lead to NOx.

In this video, Sandia National Laboratories researcher Mark Musculus discusses the science base for auto and engine manufacturers to build the next generation of cleaner, more efficient engines using low-temperature combustion.
Breakthrough measurement identifies sources of other pollutants
While LTC helps reduce PM and NOx pollution, it is not without its own problems. While NOx and PM are reduced, other pollutants go up, including carbon monoxide (CO) and unburned hydrocarbons (UHC) from the fuel. Both are not only toxic, but they also result in a loss of fuel efficiency.
The CRF research team identified the sources of these emissions from LTC engines using new optical diagnostic techniques. In a breakthrough measurement, researchers used two-photon laser-induced fluorescence to map in-cylinder CO, a difficult measurement that had never been achieved inside a diesel engine.
Detecting UHC is also problematic because many different chemical species make up the overall UHC, and their composition evolves during combustion. So, instead of detecting UHC directly, researchers used laser-induced fluorescence of other markers of combustion, such as formaldehyde and hydroxyl, to observe and understand the chemical processes that lead to UHC. The combined measurements showed that the fuel that ended up near the fuel injector was “over-mixed” – there was too much air and not enough fuel, so the fuel couldn’t burn to completion, leading to the CO and UHC in the exhaust.
With this new understanding of UHC and CO emissions, Musculus and Sandia post-doctoral researcher Jacqueline O’Connor looked for a way to increase the fuel concentration in that area. One way, they discovered, is to add post-injections, which are smaller squirts of fuel after the main spray, which add more fuel in just the right area. With the post-injections, the zone of complete combustion extends over a larger region, leading to lower UHC and CO emissions while increasing efficiency by making sure that less fuel is wasted by not even burning it.
Musculus and his colleagues, through their latest research paper, hope to communicate the details of how LTC works to the broader engine research community. “This is the kind of scientific research and data that engine designers, who help to guide our research, tell us they need so that they can build the kind of fuel-efficient diesel engines that consumers will want,” he said.
The Sandia work was completed for the U.S. Department of Energy’s Office of Energy Efficiency and Renewable Energy (EERE).

Sandia National Laboratories is a multi-program laboratory operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin company, for the U.S. Department of Energy’s National Nuclear Security Administration. With main facilities in Albuquerque, N.M., and Livermore, Calif., Sandia has major R&D responsibilities in national security, energy and environmental technologies and economic competitiveness.