Akeena Solar's Andalay AC Solar Panels Now Available at Lowe's Home Improvement Stores

"Plug-and-Play" AC Solar Photovoltaic (PV) Panel Systems Now On Shelves at Lowe's Energy Centers Throughout California

Akeena Solar of Los Gatos, California in December 2009 announced that its Andalay AC (alternating current) Solar Photovoltaic (PV) Panels are now available at 21 Lowe’s Energy Centers in Lowe’s home-improvement stores throughout California.

According to Clean Edge News, “The Lowe's Energy Centers aim to empower customers to create an energy plan that fits their budget and home-improvement goals. An information kiosk offers a touch-screen display to help customers evaluate their home's solar and wind potential, and the Energy Centers feature products that help them measure their energy use, reduce energy consumption and generate clean energy.”

Akeena Solar claims that its Andalay AC is the first fully “plug-and-play” AC solar power system. A White Paper, Video and Specifications provide evidence on “…how Andalay AC is the only rooftop system to take advantage of mainstream home AC electrical wiring standards, doing away with the need to work with dangerous DC circuits and resulting in faster, safer, more profitable installations with reduced engineering, inventory, supply chain and training requirements.” 

The White Paper “…examines how the innovations encompassed in Andalay AC not only revolutionize the way solar installation companies can do business, but also how consumers can benefit from the full promise of rooftop energy generation.” 

How Solar Power Works

Solar power systems turn sunlight into electricity. Silicon wafers capture photons from sunlight and turn them into DC power, which is then transformed into 120 volt AC power and connected to your existing electrical system — as well as the local electrical grid. When the sun shines, you can generate more power than you consume (your meter will literally spin backwards). At night you'll draw on utility company power, essentially using the electrical grid as a giant storage battery.

Image and text from Akeena Solar

From the December 10, 2009 Akeena Solar Press Release:

"The PC revolution in the computer industry occurred when new technology made PCs easy to use and affordable," said Barry Cinnamon, CEO of Akeena Solar. "Likewise, with panels becoming plug-and-play appliances, the solar revolution has started. The availability of solar panels in Lowe's stores makes it easy for homeowners to go solar and is a big step toward getting solar on every sunny rooftop."

“Andalay AC panels, developed by Akeena Solar in Silicon Valley, have integrated racking, wiring and grounding -- reducing the overall parts count by 80 percent and protecting against performance-threatening breakdowns that could happen with ordinary DC power systems.”

“Andalay panels also have built-in inverters that produce household AC power, so there is no high-voltage DC wiring. These safety and reliability benefits are achieved without compromising performance. In fact, Andalay AC panels produce 5 to 25 percent more energy output compared with ordinary DC solar panels. Because of the modular design of Andalay AC panels, homeowners could install a few panels now and gradually add on later, unlike DC systems that require a complete redesign when adding panels.”

"Buying panels off the shelf at Lowe's offers solar options to homeowners that they didn't have," continued Cinnamon. "Homeowners now can get a system as small as one panel. With Andalay's safe household AC power design, they are the only real choice for do-it-yourselfers."

“Participating Lowe's stores will stock the accessories required for installation, eliminating the need for do-it-yourselfers and contractors to pre-order components and enabling them to pick up what they need on the way to the installation.”

According to Akeena Solar, whereas direct-current (DC) solar power systems require special installation skills, Andalay’s alternating current (AC) solar system can be installed by electricians, Heating, Ventilating, and Air Conditioning (HVAC) contractors, and experienced do-it-yourselfers without specialized training.

A video by Andalay shows components of the system and how it is installed.

Solar Choices And Costs For Homes & Businesses

Heliodyne Offers Web-Based Courses On Installing Solar Thermal Systems


The New Mexico Coalition for Clean and Affordable Energy (NMCCAE) and the New Mexico Solar Energy Association (NMSEA) offer an 8-page document on solar energy for homes, businesses, and agricultural entities.





The guidebook, "How to Go Solar Using New Mexico's New Solar Energy Incentives," is a basic introduction for getting involved with solar energy.

Although specific to New Mexico in terms of reference information, the guidebook offers sound advice for potential residential, business and agricultural solar customers anywhere.

The guidebook has information on registering one's solar rights, descriptions of types of solar systems, estimated costs of solar systems, and putting together incentives such as solar tax credits.

The guidebook covers solar photovoltaic and active solar thermal heating systems -- the systems that use panels to collect solar energy. NMSEA and many others offer information on passive solar systems that are typically used for heating and cooling. A well designed passive solar home in New Mexico -- and other areas with cold but sunny winters -- saves about 80 (eighty) percent of the off-site energy purchased to heat and cool an average home.

The NMCCAE and NMSEA urge those considering solar systems to move carefully, be patient, and research options according to one's needs and budget. In many cases, low-cost or no-cost energy efficiency improvements will be a more economical solution than solar electric or solar thermal installations.

Look for restrictions such as homeowner covenants, historical district standards, etc. that affect your home or business.

Register and protect your solar rights under the New Mexico Solar Rights Law. You have the right to prevent nearby construction or other activities that will shade your solar system, but only if you register your rights and inform your neighbors.

Understand different types of solar systems and their costs.

• Solar Hot Water Systems provide domestic hot water.
• Large Solar Hot Water systems provide hot water for air heating.
• Direct Solar Hot Air Systems provide air heating.
• Grid-Tied Solar Photovoltaic (PV) systems provide solar electricity without batteries.
• Off-grid Solar Photovoltaic Systems provide solar electricity using batteries.

Positive Energy 1.5-kilowatt grid-tied solar panel array on a garage rooftop, Santa Fe, New Mexico. Positive Energy provides an instructive Photo Gallery of different types of solar systems and components of these systems.

Look at the incentives available to you. Incentives change frequently in the fast growing solar energy field, so check the links provided in the guidebook for updated information.

The Database of State Incentives for Renewables & Efficiency (DSIRE) in May 2009 created DSIRE Solar.

"DSIRE SOLAR is a comprehensive source of information on state, local, utility, and federal incentives and policies that promote the adoption of solar technologies. Funded by the U.S. Department of Energy’s Solar Energy Technology Program, DSIRE SOLAR is a new component of the DSIRE project that provides solar-specific policy information to consumers, policy makers, program administrators, the solar industry and other stakeholders."

For any USA state, one may search DSIRE Solar for incentives for either solar electric, solar thermal, or both technologies.

Locate a reputable installer. The North American Board of Certified Energy Practitioners (NABCEP) is training and certifying solar PV installers and will soon be training and certifying solar thermal installers. Beware of installers who suggest solar systems not be inspected. Report problems with installers to the Renewable Energy Industries Association of New Mexico and/or your local chamber of commerce or better business bureau.

The "How to Go Solar" guidebook was originally published in April, 2007. The guidebook is updated from time to time as new incentives and other information become available. See the NMCCAE and NMSEA web sites for current information.

Heliodyne, Inc. Offers Online Training For Installing Solar Thermal Systems

Heliodyne, Inc. Solar Thermal Roof Mounted Flat Plate Collector. Our Sun heats water in conduits inside the panel. Heated water flows into a tank or other storage system inside the building. A pump returns cooler water to the panel. Water flows in and out of the collector panel through the two silver pipes seen in the image.

Heliodyne, Inc. of Richmond, California announced on May 11, 2009 that it now offers web-based courses for trade professionals interested in installing solar thermal systems.

"Training includes topics such as solar hot water fundamentals, sales and quoting, sizing, installation and service and maintenance. The subjects are broken down into short lessons, which the student can study at his or her own pace from the convenience of his or her home or office.

"

"The beginner’s course is intended to educate professionals on solar hot water theory along with proper installation techniques." 



"'Utilizing the internet as a medium to train and educate plumbers, builders, dealers, engineers, architects, planners and other relevant industry professionals is an ideal solution since we can reach so many without the inconvenience and expense of travel,' said Robert Cooley, training manager at Heliodyne."

New Solar Photovoltaic Power Facilities Planned For Colorado & New Mexico

New CO & NM Solar PV Plants Have Small Power Output Compared With Solar Thermal Plants

Xcel/SunPower Solar PV Project in Southern Colorado

Xcel Energy of Minneapolis, Minnesota and SunPower Corporation of San Jose, California on April 7, 2009 announced an agreement to build a 17-megawatt (MW) solar photovoltaic (PV) power plant near Alamosa, Colorado. The facility will use Sunpower® Tracker systems that generate up to more than 30 percent more energy per land area than conventional systems.

The new solar PV power is an expansion of the existing 8.24-megawatt (MW) Xcel/SunEdison solar PV power plant located west of Colorado State Highway 17 about one mile north of Mosca, Colorado. See the post of March 26, 2009 below for photographs of the existing Xcel/SunEdison facility's solar PV heliostats and panel arrays.

In the announcement, SunPower CEO Tom Werner says, “Today, high-efficiency solar PV technology is competitively proceed for power plant applications. It’s fast to install, and reliably delivers clean power, particularly during peak demand hours.”




SunPower Trackers are arrays of solar photovoltaic (PV) panels mounted on axles aligned in a north-south orientation. The panels rotate on the axles allowing the panels to track the sun from east to west throughout daylight hours.

Cimarrón I Solar Project in Northern New Mexico

Tri-State Generation and Transmission Association of Westminster, Colorado, and First Solar of Tempe, Arizona, on March 24, 2009 announced an agreement to build a 30-megawatt (MW) solar photovoltaic (PV) power plant between Cimarrón and Springer, New Mexico. Click on the box below to bring up and enlarge an artist's depiction of the solar PV facility.


Cimarrón I Solar Project Visualization Still Frame 3. The view is from east to west on the high plains of New Mexico just northwest of Springer, NM and west of U.S Interstate Highway 25. The eastern foothills and peaks of the Sangre de Cristo Mountains are on the horizon, and include snow-covered Baldy Mountain in the upper right which is on Philmont Scout Ranch property. Tri-State Generation and Transmission Association provides outstanding visualizations, animations, and still photographs of the site.

The Cimarrón I Solar Project will use 500,000 (five hundred thousand) solar PV panels, each 2 (two) by 4 (four) feet, installed on 250 (two hundred fifty) acres of land. Construction is to begin in April 2010, and the first part of the system should be producing power by August 2010. Click on the box below to bring up and enlarge an artist's depiction of the solar PV facility.


Cimarrón I Solar Project Visualization Still Frame 6. The view is from west to east on the high plains of New Mexico east of Cimarrón and northwest of Springer. The hills south of Raton, NM are on the horizon, the tallest of which is Laughlin Peak which is about 20 miles southeast of Raton. Note the transmission facilities in the foreground. Tri-State Generation and Transmission Association provides outstanding visualizations, animations, and still photographs of the site.

Solar Photovoltaic & Concentrating Solar Power Production Numbers In Perspective

The announcements for the two solar PV power plants indicate they are among the largest of their type in the world. Although these projects may indeed be large in comparison with other power plants relying exclusively on solar photovoltaic panels, the two NM and CO facilities together will produce only about 47 (forty-seven) megawatts (MW) of power. This amounts to about 13 (thirteen) percent of the power now being generated, for example, by the 354-megawatt (three hundred fifty-four MW) concentrating solar thermal power (CSTP or CSP) facilities at Kramer Junction, Harper Lake and Daggett, California.

The facilities at Daggett, Kramer Junction, and Harper Lake, CA were built from 1984 through 1990 and are known as Solar Energy Generating Systems (SEGS) I through IX. The nine SEGS concentrating solar power plants generate from 14 (fourteen) to 80 (eighty) megawatts (MW) of power. The SEGS solar thermal power plants have operated continuously and have been commercially successful for the past 20 to 25 years.

The Solar Electric Industries Association (SEIA) in its US Solar Industry Year in Review 2008 report notes that no new concentrating solar thermal power (CSTP or CSP) plants came online in the USA in 2008. However, CSTP/CSP projects in the planning or construction stages currently total more than six gigawatts (GW; 6 GW = 6,000 megawatts).

Among these are projects planned for California's Mojave Desert, Arizona and Florida. The Arizona projects include the Abengoa 280-megawatt (MW) solar CSTP/CSP plant near Gila Bend, AZ, and the Albasia 200-MW Solar CSTP/CSP plant near Kingman, AZ.

Xcel Energy also issued a Request for Proposals (RFP) on January 9, 2009 for installing 600 (six hundred) megawatts (MW) of solar CSTP/CSP in southern Colorado.

The Xcel/SunPower and Tri-State/First Solar PV power plants and other similar plants of relatively small electrical output produce power appropriate for a portion of local demand. The Tri-State/First Solar PV plant output is estimated to serve about 9,000 residences, for example. Such plants could serve as models for distributed generation (DG) solar PV power with short transmission distances that could be installed almost anywhere in the USA or the world where the sun shines.

South Africa To Produce 10,000 Gigawatt-Hours of Wind & Solar Energy Using Feed-In Tariffs

South Africa's National Energy Regulator (NERSA) in late March 2009 introduced a system of Feed-in Tariffs (FITs) intended to produce 10 (ten) Terawatt-hours (TWh) = 10,000 (ten thousand) Gigawatt-hours (GWh) of electricity generated from wind, solar, small hydro, and landfill gas for the country by 2013.

"Feed-In Tariffs - Boosting Energy For Our Future" Report Front Cover, World Future Council, Hamburg, Germany, 2008.

Feed-In Tariffs For South Africa:

A March 31, 2009 Media Announcement briefs the NERSA Decision on Renewable Energy Feed-In Tariff (REFIT).

The 40-page report, South Africa Renewable Energy Feed-In Tariff (REFIT) - Regulatory Guidelines 26 March, 2009, states in its introduction:

"Grid connected renewable energy is currently the fastest growing sector in the global energy market. Installed global wind capacity at the start of 2008 is in the order of 90GW, with total world installed capacity having doubled since 2004. India, China, the United States, Spain and Germany together added over 20GW of wind power in 2007. China and India each are currently installing wind electricity in excess of 1GW per annum and both have targets of achieving over 10GW by 2015. The capacity of grid connected solar PV has also quadrupled from an installed capacity of 2GW in 2004 to approaching 8GW at the end of 2007. Commercial-scale solar thermal power plants are also under construction in countries such as the US and Spain. Targets for the promotion of renewable energy now exist in more than 58 countries, of which 13 are developing countries."

'The renewable energy industry is now a major economic player, with the industry employing over 2.5 million people worldwide. Renewable energy companies have grown significantly in size in recent years, with the market capitalisation of publicly traded renewables companies doubling from $50 billion to $100 billion in just two years (2005-7)."

"South Africa has a high level of renewable energy potential and presently has in place targets of 10,000 GWh of renewable energy by 2013. To contribute towards this target and towards socio-economic and environmentally sustainable growth, and kick start and stimulate the renewable energy industry in South Africa, there is a need to establish an appropriate market mechanism."

"Feed-in Tariffs (FIT) are, in essence, guaranteed prices for electricity supply rather than conventional consumer tariffs. The basic economic principle underpinning the FITs is the establishment of a tariff (price) that covers the cost of generation plus a "reasonable profit" to induce developers to invest. This is quite similar to the concept of cost recovery used in utility rate regulation based on the costs of capital."

"Under this approach it becomes economically appropriate to award different tariffs for different technologies. The price for the electricity produced should be set at a level and for a period that provides a reasonable return on investment for a specific technology. The tariff should also be certain and long term enough to allow for project financing to be raised by the project."

"Feed-in tariffs to promote renewable energy have now been adopted in over 36 countries around the world, including Spain and Germany and a number of states in the US, and also including developing nations such as Turkey, Thailand, Sri Lanka, Nicaragua, Indonesia, Ecuador, China, Brazil, Argentina and most recently Kenya."

"The establishment of the Renewable Energy Feed-In Tariff (REFIT) in South Africa will provide an excellent opportunity for South Africa to increase the deployment of renewable energy in the country and contribute towards the sustained growth of the sector in the country, the region and internationally."






"Feed-In Tariffs - Boosting Energy For Our Future" Report Back Cover, World Future Council, Hamburg, Germany, 2008.

USA Installs 1,265 Megawatts (MW) Of Solar Power In 2008

New Solar Energy Industries Association (SEIA) Report Details Solar Power Growth In The USA.

Xcel/SunEdison solar photovoltaic heliostats, 8.24 Megawatt (MW) Solar Photovoltaic (PV) Powerplant, San Luis Valley near Mosca, Colorado. This powerplant was activated in December 2007. View is eastward towards Sangre de Cristo Mountains.
Photograph by L.A. Brown, March 18, 2009.

The Solar Energy Industries Association (SEIA) released its 12-page summary report, 2008 U.S. Solar Industry Year in Review.

The report states 1,265 megawatts (MW) of solar power of all varieties were installed in the USA in 2008. These include 342 MW of solar photovoltaic (PV) installations, 139 MWTh (megawatts thermal equivalent) of solar water heating, 762 MWTh of pool heating, and an estimated 21 MW of solar space heating and cooling.

Surface detail of Xcel/SunEdison solar PV heliostat, Mosca, Colorado, showing reflective metal triangular ridges that focus solar radiation on solar PV receptors. Photograph by L.A. Brown, March 18, 2009.

California was the leader among state grid-tied PV installations with 178.6 MW, New Jersey followed with 22.5 MW installed, Colorado was next at 21.6 MW, Nevada installed 13.9 MW and Hawaii with 11.3 MW. For solar water heating systems, Hawaii led states, installing 37 percent of the total U.S. systems in 2008, followed by Florida at 20 percent, California with 7 percent and both Colorado and Arizona with 5 percent. The Mid-Atlantic States, an important emerging region for solar, installed 7 percent of solar water heating systems.

Close-up of solar PV receptors and reflective metal triangular ridges, Xcel/SunEdison heliostat, Mosca, Colorado. Note dirt on panel surfaces and dents in metal reflectors caused by hail. Photograph by L.A. Brown, March 18, 2009.

The SEIA report indicates solar PV manufacturing capacity in the USA increased by 65 percent in 2008. this created many new jobs in California, Michigan, Ohio, Oregon and Tennessee. Total solar power production capacity in those five states now stands at approximately 685 megawatts (MW).


















Solar panels, Xcel/SunEdison 8.24 MW Solar Photovoltaic Power Plant, Mosca, Colorado. These panels are supported by north-south aligned axles that rotate the panels from east to west throughout the day to track the sun. View is northeastward in the afternoon towards the Sangre de Cristo Mountains that form the eastern border of the San Luis Valley. Photograph by L.A. Brown, March 18, 2009.

The SEIA report notes that no new concentrating solar power (CSP) plants came online in the USA in 2008. However, CSP projects in the planning or construction stages currently total more than six gigawatts (GW; 6 GW = 6,000 megawatts). Among these are projects planned for California's Mojave Desert, Arizona and Florida.

Tracking The Sun

Solar Panels On Rooftops, Ohta, Japan, Focus Solar, 2008

Solar Photovoltaic Power Costs In USA Drop 30 Percent Over Past Decade

The Environmental Energy Technologies Division, Lawrence Berkeley National Laboratory in California released a new report, “Tracking the Sun,” that documents the installed costs of solar photovoltaic (PV) power in the USA from 1998-2007.

The February 27, 2009 revision of the 42-page document indicates a positive outlook for the future of customer economics of solar PV. Primary indicators include an oversupply of solar PV modules in the near future together with lifting the cap on the Federal Investment Tax Credit (ITC) for residential PV will reduce costs for residential installations. Large commercial solar PV promises to be the dominant growth market because of economies of scale, but both large and small solar PV systems stand to make major gains in reduced costs per unit of energy generated.

The report examines 37,000 grid-connected solar PV systems installed in 12 USA states from 1998-2007. Among these, average costs before financial incentives or tax credits declined from $10.50 per watt in 1998 to $7.6 per watt in 2007 – roughly a 35 percent cost reduction over ten years.

Non-module costs such as inverters, mounting hardware, labor, permitting and fees, shipping, overhead, taxes and profit were responsible for the bulk of cost reductions.

Systems less than 5 kilowatts in size exhibited the largest cost reductions; however, data are lacking for larger solar PV systems with output greater than 100 kilowatts.

Average costs for all systems flattened and remained almost unchanged from 2005-2007.

Installed costs of solar PV show economies of scale. Systems less than 2 kilowatts averaged about $9.00 per watt in 2006-2007, and systems greater than 750 kilowatts averaged about $6.80 per watt during the same period.

State and utility cash incentives for solar PV installations declined from 2002 through 2007.

The increase in the Federal ITC in 2006 tended to stimulate commercial-scale solar PV from 2007-2009; however, residential solar PV should gain cost advantages in 2009 with changes in the Federal residential ITC.

In its introduction, the report says: “Despite the significant year-on-year growth, however, the share of global and U.S. electricity supply met with PV remains small, and annual PV additions are currently modest in the context of the overall electric system.”

Nonetheless, the growth of solar PV is encouraging. The data on its declining costs with time offer a promise of even more accelerated growth in the next few years.

A February 25, 2009 brief at WorldChanging expands upon the following:

Business Green reported on February 23, 2009 that the price of solar PV panels could fall by as much as 40 percent by the end of this year. Other analysts have been predicting this price drop that is based on huge increases in polysilicon supplies leading to a drop in production costs.

New Energy Finance also predicts a fall in solar PV module prices because of recent global investments in increasing silicon production.

China-based solar PV panel manufacturer Suntech Power Holdings estimates that demand from the USA could reach 700 megawatts (MW) during 2009 as a result of President Obama’s new stimulus package.

Climate Progress suggests if the dramatic price drop for solar PV panels materializes, solar PV will become "...one of the largest job-creating industries of the century, projected to grow from $20 billion two years ago to a $74 billion industry by 2017."

Solar Power Milestones In 2009

Capturing The Energy Of The Sun, iStockphoto image in Science Daily, August 25, 2008.

The solar power industry continues its rapid evolution as evidenced by important milestones reached within the past few weeks. Progress in the solar power sector is being driven by practical economic, energy security, and environmental protection factors.

Guinness Atkinson Funds on December 31, 2008 for example argues that the long term prospects for solar power and other clean energies remain sound, in fact showing the potential to be one of the first sectors to emerge from the current financial downturn.

Guinness Atkinson invests in a wide variety of companies engaged in the production, exploration and discovery or distribution of energy, whether derived from fossil fuels or an “Alternative Energy” suite of solar, wind, hydro, efficiency, geothermal, biomass and biofuel.

Consistent with this appraisal, Suntech Power Holdings Co. Ltd. announced on January 9, 2009 that it has reached 1 gigawatt (GW) of solar photovoltaic (PV) cell and module production capacity in Wuxi, China. Suntech is the first solar photovoltaic company in the world to achieve 1 GW of solar cell and module production.

Suntech’s announcement comes in contrast to other companies that are scaling back production estimates for 2009 because of global credit and stock market declines. Suntech is headquartered in Jiangsu Province, People’s Republic of China, with offices in Schaffhausen, Switzerland; San Francisco, California; New South Wales, Australia; Munich, Germany; Madrid, Spain; Gangnam-gu, South Korea; and Tokyo, Japan.

In the United States, SunEdison on January 9, 2009 announced one of the largest solar distributed generation (DG) programs ever conceived. SunEdison is partnering in the venture with Developers Diversified Realty, a Cleveland-based real estate investment trust (REIT) engaged in the development and management of shopping centers.

Under the terms of the deal, SunEdison “…has the rights to deploy solar energy systems at more than 200 shopping centers, covering up to an estimated 30 million square feet. Potential capacity of the program is up to 259 MW and the centers are located in 24 states and in Puerto Rico.”

“Once a particular system is operational, Developers Diversified will be able to purchase energy from SunEdison. In addition, shopping center tenants can benefit and realize energy savings by opting to purchase the power generated through the program at rates lower than retail energy rates.” SunEdison spokesman Brian Jacolick stated, “…a typical sized solar energy system in the program will avoid an estimated 10 million pounds of carbon dioxide pollution.”

Also in the USA, the Solar Electric Power Association (SEPA) on January 7, 2009 released a new research report, “Facilitating Utility Use and Integration of Solar Electric Power.”

This report is based on work supported by the
US Department of Energy Office of Energy Efficiency and Renewable Energy through the Solar America Initiative.

The report contains two informative summary tables. One documents large-scale USA utility solar photovoltaic projects [those projects of more than 20 megawatts (MW)] either completed or in development as of September 2008. The second documents large-scale USA concentrating solar thermal power (CSP) projects either completed or announced as of July 2008.

The report says, “This year has seen an unprecedented number of utility-scale photovoltaic and concentrating solar thermal project announcements – some 3,000 to 5,000 megawatts over the next five years.

“However, SEPA believes this is only the cornerstone of what’s to come. The effect of the long-term extension of the federal investment tax credit—which includes eligibility for utilities—combined with the expansion of global solar manufacturing, rapidly declining cost and price curves, and federal and state environmental policies, is laying a foundation for utility solar innovation at unprecedented scales.”

The SEPA/DOE research offers critical insights into policy and procurement innovations that are possible with the solar power industry, but not possible with old technology power production and distribution. Because solar power is available everywhere the sun shines - albeit in greater or lesser degrees - utility companies are not limited to solar power solutions based on a central-station power generation, long-distance power transmission construct.

The SEPA/DOE report lists several benefits for utility companies to find ways to increase their portfolio of renewable energy in general and solar power in particular.

"Utilities need to compare solar costs with peak generation costs [and/or new plant acquisition] rather than base load [or avoided cost] electricity generation;

"The distributed nature of PV adds to grid reliability;

"The distributed generation of PV has limited transmission and distribution costs;

"Solar project developers actively pursuing residential and commercial customers to install their own solar generation are taking business away from utilities and driving utilities to acquire solar resources to remain competitive;

"In a carbon-regulated world, solar will offer utilities credits rather than costs that will be incurred for their carbon polluting generation;

"Increasing solar integration will be aided by and will in turn aid adoption of 'smart grid' technologies;

"Utilities improve their image to the public by taking voluntary environmental measures;

"Solar 'fuel' will remain free while costs of coal and natural gas continue to fluctuate in volatile markets.

"Although, historically, utilities outside of the Southwest have played a lesser role in the direct growth of solar power, within a decade solar power is expected to be cost-competitive in most regions of the U.S. on both a wholesale and retail basis.

"As utilities and others scale up their solar efforts, they are reaching economies of scale unlike anything seen in the past."

The Wedge Game – Solving the Climate Problem By 2055

Targets For Legislative Proposals In The USA Congress Of Mandatory Cap And Trade Programs For Greenhouse Gases Emissions, courtesy of World Resources Institute (WRI) – December 8, 2008.

The top (red) line shows historical and projected carbon emissions for the USA for 1990-2050 under conditions of "business as usual." The other lines show estimated carbon emissions reductions trends for 2010-2050 under different legislative proposals.

WRI offers a high resolution image of this graph plus details about the methodology, assumptions and references that went into creating it. WRI updates the graph each year.


A World In Transition

In the brief span of about two years – between the end of 2006 and the beginning of 2009 – our global society has greatly accelerated its transformation towards a new energy economy. Considering where we were just two short years ago, those of us in the business of climate change and economic improvement solutions should be very encouraged by this progress. In late 2006, global warming and climate change science and solutions were barely on the radar of our general public and the popular media.

As we begin 2009, concrete measures to better understand our Earth’s systems together with actions to manage climate change dominate global news, global politics, and the thinking of people at all levels of our global societies. Two years ago, I would have told people that such an expansive level of activity was a decade or more away.

By about the middle of 2007, my correspondents and audiences were demanding a story far more comprehensive than scientific accounts of global warming and its impacts. People were demanding solutions. And like people everywhere, they were demanding (and offering) straightforward solutions. And most were (and remain) convinced that somehow there would be an easy-to-understand and easily implemented single solution. How do we fix this quickly? What is the single most important thing we can do? What technology do we need? How much will it cost?

Unfortunately, there is no “silver bullet” solution to drastically eliminating the bulk of our polluting greenhouse gases (GHG) emissions in a reasonably short time. However, we can solve a major part of our emissions problems beginning now and using currently available technologies.

Often described as “silver shotgun” approaches, there are solutions scenarios that comprise several concurrent actions. These are actions that make sense physically, economically, and politically – actions that might be understandable and palatable across a broad spectrum of political, economic, cultural, spiritual and other viewpoints.

In 2004, prominent carbon management researchers Stephen Pacala and Robert Socolow of Princeton University introduced the “stabilization wedges” concept for solving our climate problem for the next 50 years using current technologies. This work continues to advance, and now is a joint project of Princeton University, BP, and Ford Motor Company. The project is called the Carbon Mitigation Initiative (CMI), and it seeks practical solutions to the greenhouse gases emissions problem.



The “stabilization wedges” concept is based upon using a suite of seven low-carbon energy technologies and enhancing natural carbon sinks. The concept name comes from the “wedge” or cut in emissions depicted on a graph of carbon emissions projected for 2005 – 2055. Each “wedge” represents a carbon-cutting strategy that can grow from zero in 2005 to one billion tons of carbon emissions by 2055.

Thus, pursuing seven “wedge” strategies would cut carbon emissions by seven billion tons, keeping global carbon emissions flat for the next 50 years. Pursuing more than seven strategies would reduce our carbon emissions below today’s levels by 2055. The CMI demonstrates that at least 15 “wedge” strategies are available now, showing there is already a more than adequate portfolio of tools available today to control carbon emissions for the next 50 years.



The CMI shows opportunities for cutting carbon emissions using current technologies in combinations of actions under these headings:

Efficiency & Conservation

Increased transport efficiency
Reducing miles traveled
Increased heating efficiency
Increased efficiency of electricity production

Fossil-Fuel-Based Strategies

Fuel switching (coal to gas)
Fossil-based electricity with carbon capture & storage (CCS)
Coal synfuels with CCS
Fossil-based hydrogen fuel with CCS

Nuclear Energy

Nuclear electricity

Renewables and Biostorage

Wind-generated electricity
Solar electricity
Wind-generated hydrogen fuel
Biofuels
Forest storage
Soil storage

The CMI provides briefs showing how GHG emissions reductions are calculated for each opportunity in this list. The briefs include commentaries on the pros and cons of each technology and how they interact with each other. The numbers in these commentaries should be useful to those wishing to understand the dimensions of combatting GHG emissions.

The CMI has produced a “Teachers Guide to the Stabilization Wedge Game.” This is a team-based exercise in which players build a portfolio of stabilization strategies and assess their impacts and costs. Those interested in explanations of our climate and carbon problem – and the relative contributions and costs of solutions using the strategies above – might want to examine this guide and its associated resources.

A significant feature of the “wedge” concept and game is that people may choose their preferred combinations of strategies from the above list, and reject strategies that might be less palatable for various political, economic or other reasons. For example, if you do not like current-technology nuclear or coal-fired electricity as a part of the suite of solutions, you can select a balancing alternative from the list of 15 opportunities. You might also consider the extra costs and benefits of substitututing compensating amounts of current-technology wind- and solar-generated electricity, for example.

Signet Solar Plans Large Solar Panel Facility In New Mexico

SunPower/Johnson & Johnson Ground-Mounted 739-kilowatt Solar Power System, New Jersey, USA.

Signet Solar, an international company with USA corporate headquarters in Menlo Park, California, will open a solar panel production facility in New Mexico in 2010. The company will produce large area, thin-film silicon photovoltaic modules for commercial rooftop and ground-mounted solar power systems.

Ground-mounted solar power systems are an important and growing contribution to distributed generation (DG). Ground-mounted systems are much more economical to install than rooftop systems, and can be integrated into communities and/or the existing power grid everywhere. A video by Applied Materials, a global company with corporate headquarters in Santa Clara, California, illustrates installation of a 10-megawatt (MW) ground-mounted solar power system in Germany.

Signet Solar plans an initial annual production of 65 megawatts (MW) growing to 300 MW per year, and creating 200 high-wage jobs growing to 600 as the New Mexico facility expands.


Renewable Energy World/Signet Solar/New Mexico

December 18, 2008

Signet Solar to Build 300-MW Production Facility in New Mexico

New Mexico, United States [RenewableEnergyWorld.com]

New Mexico Governor Bill Richardson announced that Signet Solar will build the company's first North American solar panel production facility in Belen, New Mexico. The first phase of the plant will bring 200 high-wage jobs to the state and is scheduled to begin operations in 2010. Signet's long-term plans call for expansion and the creation of a total of 600 jobs.

“As Governor, I’ve been dedicated to making New Mexico a national leader of renewable energy and the creation of green jobs,” Richardson said. “At a time of economic uncertainty, this project will create hundreds of jobs and reaffirm New Mexico as a clean energy state and major player in our nation’s effort build a new clean energy economy.”



The Signet Solar facility will produce large area thin-film silicon photovoltaic modules for commercial rooftop and ground mounted solar power systems. The first phase of the plant will have an annual production capacity of 65 megawatts (MW). Long-term plans call to increase production capacity to 300 MW per year with a 600,000 square foot production facility.



“New Mexico was an obvious starting point for Signet Solar’s expansion into the growing US renewable energy market,” said Rajeeva Lahri, Signet Solar’s Co-Founder and CEO. “Under Governor Richardson’s leadership, New Mexico has demonstrated commitment to renewable energy through public-private partnerships, leveraging its skilled workforce and world class research institutions.”

RenewableEnergyWorld.com's Stephen Lacey talked with Dr. Keshav Prasad, vice president of business development for Signet Solar about the Applied Materials' SunFab line it uses for production and the company's growth plans at Solar Power International in October.

Applied Materials, Inc. (Nasdaq:AMAT) is the global leader in Nanomanufacturing Technology™ solutions with a broad portfolio of innovative equipment, service and software products for the fabrication of semiconductor chips, flat panel displays, solar photovoltaic cells, flexible electronics and energy efficient glass.

Wind, Water & Sun Are Superior Energy Solutions

Vestas Horn Reef wind power facility off the coast of Denmark.

Stanford University on December 10, 2008 announces the results of the "...first quantitative, scientific evaluation of the proposed, major energy-related solutions..." and their respective impacts on "...global warming, human health, energy security, water supply, space requirements, wildlife, water pollution, reliability and sustainability."

This significant work debunks many of the myths surrounding our progress towards a new energy economy, notably the "clean coal" myth, the "nuclear power solution" myth, and the myths challenging the reliability and variability of wind, solar and wave power.

"Coal with carbon sequestration emits 60- to 110-times more carbon and air pollution than wind energy, and nuclear emits about 25-times more carbon and air pollution than wind energy..."

[Despite significant technological progress and applications of interconnected wind farms, stored solar energy, etc., that I have reported during the past two years, politicians, mass media, special interest groups, and others continue to dismiss wind and solar power potential for supplying baseline power. The potential is there, and we only must develop that potential while ignoring false claims that baseline wind, solar and wave power systems are not possible.]

See the reference links at the end of the article for supporting information and Professor Jacobson's 2007 work on interconnected wind systems for supplying baseline power. That study focused on interconnected wind system potential for an array of wind farms that have been growing for the past few years across eastern New Mexico, northern Texas, western Oklahoma, southwestern Kansas, and southeastern Colorado.

Note the priority lists of best to worst power and vehicle options near the end of the article.

Importantly, Mark Jacobson's work represents a high level of integrity inasmuch as the research "...received no funding from any interest group, company or government agency."


Stanford University News Service

Energy & Environmental Science

Stanford Report, December 10, 2008

Wind, water and sun beat other energy alternatives, study finds

BY LOUIS BERGERON

The best ways to improve energy security, mitigate global warming and reduce the number of deaths caused by air pollution are blowing in the wind and rippling in the water, not growing on prairies or glowing inside nuclear power plants, says Mark Z. Jacobson, a professor of civil and environmental engineering at Stanford.

And "clean coal," which involves capturing carbon emissions and sequestering them in the earth, is not clean at all, he asserts.

Jacobson has conducted the first quantitative, scientific evaluation of the proposed, major, energy-related solutions by assessing not only their potential for delivering energy for electricity and vehicles, but also their impacts on global warming, human health, energy security, water supply, space requirements, wildlife, water pollution, reliability and sustainability. His findings indicate that the options that are getting the most attention are between 25 to 1,000 times more polluting than the best available options. The paper with his findings will be published in the next issue of Energy and Environmental Science but is available online now. Jacobson is also director of the Atmosphere/Energy Program at Stanford.

"The energy alternatives that are good are not the ones that people have been talking about the most. And some options that have been proposed are just downright awful," Jacobson said. "Ethanol-based biofuels will actually cause more harm to human health, wildlife, water supply and land use than current fossil fuels." He added that ethanol may also emit more global-warming pollutants than fossil fuels, according to the latest scientific studies.

The raw energy sources that Jacobson found to be the most promising are, in order, wind, concentrated solar (the use of mirrors to heat a fluid), geothermal, tidal, solar photovoltaics (rooftop solar panels), wave and hydroelectric. He recommends against nuclear, coal with carbon capture and sequestration, corn ethanol and cellulosic ethanol, which is made of prairie grass. In fact, he found cellulosic ethanol was worse than corn ethanol because it results in more air pollution, requires more land to produce and causes more damage to wildlife.

To place the various alternatives on an equal footing, Jacobson first made his comparisons among the energy sources by calculating the impacts as if each alternative alone were used to power all the vehicles in the United States, assuming only "new-technology" vehicles were being used. Such vehicles include battery electric vehicles (BEVs), hydrogen fuel cell vehicles (HFCVs), and "flex-fuel" vehicles that could run on a high blend of ethanol called E85.

Wind was by far the most promising, Jacobson said, owing to a better-than 99 percent reduction in carbon and air pollution emissions; the consumption of less than 3 square kilometers of land for the turbine footprints to run the entire U.S. vehicle fleet (given the fleet is composed of battery-electric vehicles); the saving of about 15,000 lives per year from premature air-pollution-related deaths from vehicle exhaust in the United States; and virtually no water consumption. By contrast, corn and cellulosic ethanol will continue to cause more than 15,000 air pollution-related deaths in the country per year, Jacobson asserted.

Because the wind turbines would require a modest amount of spacing between them to allow room for the blades to spin, wind farms would occupy about 0.5 percent of all U.S. land, but this amount is more than 30 times less than that required for growing corn or grasses for ethanol. Land between turbines on wind farms would be simultaneously available as farmland or pasture or could be left as open space.

Indeed, a battery-powered U.S. vehicle fleet could be charged by 73,000 to 144,000 5-megawatt wind turbines, fewer than the 300,000 airplanes the U.S. produced during World War II and far easier to build. Additional turbines could provide electricity for other energy needs.

"There is a lot of talk among politicians that we need a massive jobs program to pull the economy out of the current recession," Jacobson said. "Well, putting people to work building wind turbines, solar plants, geothermal plants, electric vehicles and transmission lines would not only create jobs but would also reduce costs due to health care, crop damage and climate damage from current vehicle and electric power pollution, as well as provide the world with a truly unlimited supply of clean power."

Jacobson said that while some people are under the impression that wind and wave power are too variable to provide steady amounts of electricity, his research group has already shown in previous research that by properly coordinating the energy output from wind farms in different locations, the potential problem with variability can be overcome and a steady supply of baseline power delivered to users.

Jacobson's research is particularly timely in light of the growing push to develop biofuels, which he calculated to be the worst of the available alternatives. In their effort to obtain a federal bailout, the Big Three Detroit automakers are increasingly touting their efforts and programs in the biofuels realm, and federal research dollars have been supporting a growing number of biofuel-research efforts.

"That is exactly the wrong place to be spending our money. Biofuels are the most damaging choice we could make in our efforts to move away from using fossil fuels," Jacobson said. "We should be spending to promote energy technologies that cause significant reductions in carbon emissions and air-pollution mortality, not technologies that have either marginal benefits or no benefits at all".

"Obviously, wind alone isn't the solution," Jacobson said. "It's got to be a package deal, with energy also being produced by other sources such as solar, tidal, wave and geothermal power."

During the recent presidential campaign, nuclear power and clean coal were often touted as energy solutions that should be pursued, but nuclear power and coal with carbon capture and sequestration were Jacobson's lowest-ranked choices after biofuels. "Coal with carbon sequestration emits 60- to 110-times more carbon and air pollution than wind energy, and nuclear emits about 25-times more carbon and air pollution than wind energy," Jacobson said.

Although carbon-capture equipment reduces 85-90 percent of the carbon exhaust from a coal-fired power plant, it has no impact on the carbon resulting from the mining or transport of the coal or on the exhaust of other air pollutants. In fact, because carbon capture requires a roughly 25-percent increase in energy from the coal plant, about 25 percent more coal is needed, increasing mountaintop removal and increasing non-carbon air pollution from power plants, he said.

Nuclear power poses other risks. Jacobson said it is likely that if the United States were to move more heavily into nuclear power, then other nations would demand to be able to use that option.

"Once you have a nuclear energy facility, it's straightforward to start refining uranium in that facility, which is what Iran is doing and Venezuela is planning to do," Jacobson said. "The potential for terrorists to obtain a nuclear weapon or for states to develop nuclear weapons that could be used in limited regional wars will certainly increase with an increase in the number of nuclear energy facilities worldwide." Jacobson calculated that if one small nuclear bomb exploded, the carbon emissions from the burning of a large city would be modest, but the death rate for one such event would be twice as large as the current vehicle air pollution death rate summed over 30 years.

Finally, both coal and nuclear energy plants take much longer to plan, permit and construct than do most of the other new energy sources that Jacobson's study recommends. The result would be even more emissions from existing nuclear and coal power sources as people continue to use comparatively "dirty" electricity while waiting for the new energy sources to come online, Jacobson said.

Jacobson received no funding from any interest group, company or government agency.


Energy and vehicle options, from best to worst, according to Jacobson's calculations:

Best to worst electric power sources:

1. Wind power
2. Concentrated solar power (CSP)
3. Geothermal power
4. Tidal power
5. Solar photovoltaics (PV)
6. Wave power
7. Hydroelectric power
8. A tie between nuclear power and coal with carbon capture and sequestration (CCS).

Best to worst vehicle options:

1. Wind-BEVs (battery electric vehicles)
2. Wind-HFCVs (hydrogen fuel cell vehicles)
3. CSP-BEVs
4. Geothermal-BEVs
5. Tidal-BEVs
6. Solar PV-BEVs
7. Wave-BEVs
8. Hydroelectric-BEVs
9. A tie between nuclear-BEVs and coal-CCS-BEVs
11. Corn-E85
12. Cellulosic-E85.

Hydrogen fuel cell vehicles were examined only when powered by wind energy, but they could be combined with other electric power sources. Although HFCVs require about three times more energy than do BEVs (BEVs are very efficient), HFCVs are still very clean and more efficient than pure gasoline, and wind-HFCVs still resulted in the second-highest overall ranking. HFCVs have an advantage in that they can be refueled faster than can BEVs (although BEV charging is getting faster). Thus, HFCVs may be useful for long trips (more than 250 miles) while BEVs more useful for trips less than 250 miles. An ideal combination may be a BEV-HFCV hybrid.


Related Information

Professor Mark Jacobson discusses alternative energy sources

Jacobson's paper in Energy & Environmental Science

Jacobson's Stanford web page

Stanford December 2007 press release on interconnecting wind farms to smooth power delivery

Jacobson's interconnecting windfarms paper in J. Applied Meteorology and Climatology