Renewable Energy

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Welcome to the sixth edition of the annual Solar Power World and Wind power Engineering and Development Renewable Energy Handbook. It’s stunning to think we’ve produced six editions now—each one more useful and comprehensive than the last. Whether you’re a long-time reader—with a half-dozen issues organized on your bookshelf, declaring your renewable energy authority to anyone who sees them—or enjoying the handbook for the first time, we thank you for reading. We hope you learn a lot!

This handbook is a reflection of my career in renewable energy. I joined this industry as an editorial intern, way back in 2011 (when most of today’s solar projects were just a twinkle in developer’s eyes). My boss told me if I put together the inaugural edition of the handbook, it would earn me a full-time position. What I didn’t know is that it would become an annual tradition, or that I would enjoy it more with each passing year.

The Renewable Energy Handbook forces me to learn as much as I can, perfecting and refreshing my knowledge every year (“How do solar meters work again?”). It also offers a chance to work with the many industry veterans who are kind enough to share their expertise. And because this is a year-round team effort (the fruit of the labors of all Wind power Engineering & Development and Solar Power World editors—and intrepid interns), I’m constantly reminded that I’m lucky to be part of such a hard working, knowledgeable team.

While my career has been on a steady rise, the wind and solar industries have had ups and downs since we first published the handbook. Despite uncertainty, or perhaps because of it, it’s still an exciting time to be in renewable. No one can argue with the long term viability of renewable energy. We know how this will end.

In the first three quarters of this year, the U.S. has more the doubled the number of wind-powered electricity brought to the grid, compared with the same time period in 2014. The total wind capacity across the country stands at just over 69,470 MW. An additional 4,100 MW is in advanced stages of development, and offshore wind is getting closer to reality in U.S. waters. What’s more, wind energy pricing has reached an all-time low.

Likewise, great advances are being made in the solar industry. We should see a million U.S. homes with solar panels in February 2016. It’s true the industry might look a little different in 2017 if the ITC isn’t renewed, with the utility scale market expected to take the biggest hit. But smaller projects should stay on track, in large part because the industry has worked hard to lower component and installation costs.

It’s a great time to be part of these industries, and we’re here to help you succeed. We have more than 45 articles answering common questions about projects and components. What do you need to know before you order cables? How has O&M changed? What type of battery is best for your project? A section with component charts will help you compare equipment specification with a glance. And new sections include maps to help you understand where renewables are working now and could work in the future.

As always, we welcome feedback— please feel free to share it. We look forward to the hard work you’ll do for renewables in 2016.

Kathie Zipp

Managing Editor

Solar Power World

kzipp@wtwhmedia.com

Post Sorce: http://www.solarpowerworldonline.com/2016/01/2016-renewable-energy-handbook/

Top 6 Things You Didn't Know About Solar Energy

Installing a concentrating solar power system in Gila Bend, Arizona. The curved mirrors are tilted toward the sun, focusing sunlight on tubes that run the length of the mirrors. The reflected sunlight heats a fluid flowing through the tubes. The hot fluid then is used to boil water in a conventional steam-turbine generator to produce electricity. | Photo by Dennis Schroeder

6. Solar energy is the most abundant energy resource on earth – 173,000 terawatts of solar energy strikes the Earth continuously. That's more than 10,000 times the world's total energy use.

5. The first silicon solar cell, the precursor of all solar-powered devices, was built by Bell Laboratories in 1954. On page one of its April 26, 1954 issue, The New York Times proclaimed the milestone, “the beginning of a new era, leading eventually to the realization of one of mankind’s most cherished dreams -- the harnessing of the almost limitless energy of the sun for the uses of civilization.”

4. The space industry was an early adopter of solar technology. In the 1960s the space industry began to use solar technology to provide power aboard spacecrafts. The Vanguard 1 -- the first artificial earth satellite powered by solar cells -- remains the oldest manmade satellite in orbit – logging more than 6 billion miles.

3. Fast track to today and demand for solar in the United States is at an all time high. In the first quarter of 2012, developers installed 85 percent more solar panels compared to the first quarter of last year. Total U.S. installations may reach 3,300 megawatts this year – putting the country on track to be the fourth largest solar market in the world.

2. As prices continue to fall, solar energy is increasingly becoming an economical energy choice for American homeowners and businesses. Still, the biggest hurdle to affordable solar energy remains the soft costs – like permitting, zoning, and hooking a solar system up to the power gird. On average local permitting and inspection processes add more than $2,500 to the total cost of a solar energy system. The Energy Department SunShot Initiative works to aggressively drive down these soft costs – making it faster and cheaper for families and businesses to go solar.

1. In California’s Mojave Desert, the largest solar energy project in the world is currently under construction. The project relies on a technology known as solar thermal energy. Once the project is complete 350,000 mirrors will reflect light onto boilers. When the water boils, the steam turns a turbine, creating electricity. The project is expected to provide clean, renewable energy for 140,000 homes and is supported by an Energy Department loan guarantee.


Source: http://www.energy.gov/articles/top-6-things-you-didnt-know-about-solar-energy

The Latest in Solar Technology

Solar technologies have evolved a lot since they first made their debut in the 1960s. While previously solar photovoltaics (PV) were seen as a thing of the future, today, technological breakthroughs have positioned the industry for huge growth.

A series of new developments in solar PV technology also promise to contribute to the industry's success.

Advances in Solar Cell Technology

Researchers have longed looked for ways to improve the efficiency and cost-effectiveness of solar cells - the life blood of solar PV systems. A solar PV array is comprised of hundreds, sometimes thousands of solar cells, that individually convert radiant sun light into electrical currents. The average solar cell is approximately 15% efficient, which means nearly 85% of the sunlight that hits them does not get converted into electricity. As such, scientists have constantly been experimenting with new technologies to boost this light capture and conversion.

Light-Sensitive Nanoparticles. Recently, a group of scientists at the University of Toronto unveiled a new type of light-sensitive nanoparticle called colloidal quantum dots, that many believe will offer a less expensive and more flexible material for solar cells. Specifically, the new materials use n-type and p-type semiconductors - but ones that can actually function outdoors. This is a unique discovery since previous designs weren't capable of functioning outdoors and therefore not practical applications for the solar market. University of Toronto researchers discovered that n-type materials bind to oxygen - the new colloidal quantum dots don't bind to air and therefore can maintain their stability outside. This helps increase radiant light absorption. Panels using this new technology were found to be up to eight percent more efficient at converting sunlight.

Gallium Arsenide. Researchers at Imperial College University in London believe they have discovered a new material - gallium arsenide - that could make solar PV systems nearly three times more efficient than existing products on the market. The solar cells are called "triple junction cells" and they're much more efficient, because they can be chemically altered in a manner that optimizes sunlight capture. The model uses a sensor-driven window blind that can track sun light along with "light-pipes" that guide the light into the system.

Advances in Energy Storage

Another major focus of scientists is to find new ways to store energy produced by solar PV systems. Currently, electricity is largely a "use it or lose it" type resource whereby once it's generated by a solar PV system (or any type of fuel source) the electricity goes onto the grid and must be used immediately or be lost. Since the sunlight does not shine twenty four hours a day, this means that most solar PV systems are only meeting electrical demands for a portion of the day - as a result, a lot of electricity is lost, if it's not used. There are a number of batteries on the market that can store this energy, but even the most high-tech ones are fairly inefficient; they're also expensive and have a pretty short shelf life, making them not the most attractive options for utility companies and consumers. That is why scientists are exploring different ways to store this electricity so that it can be used on demand.

Molten Salt Storage Technology. A company called Novatec Solar recently commissioned a promising energy storage solution for solar PV systems using a molten salt storage technology. The process uses inorganic salts to transfer energy generated by solar PV systems into solar thermal using heat transfer fluid rather than oils as some storage system have. The result is that solar plants can operate at temperatures over 500 degrees Celsius, which would result in a much higher power output. This means that costs to store solar would be lowered significantly and utility companies could finally use solar power plants as base load plants rather than to meet peak demand during prime daylight hours.

Solar Panel with Built-In Battery. In a project funded by the United States Department of Energy, Ohio State University researchers recently announced they created a battery that is 20% more efficient and 25% cheaper than anything on the market today. The secret to the design is that the rechargeable battery is built into the solar panel itself, rather than operating as two standalone systems. By conjoining the two into one system, scientists said they could lower costs by 25% compared to existing products.

Advances in Solar Cell Manufacturing

Another area that has made solar PV technologies cost prohibitive compared to traditional fuel sources is the manufacturing process. Scientists are also focused on ways to improve the efficiency of how solar components are manufactured.

Magnesium Chloride. While over ninety percent of solar panels on the market today are comprised of silicon semiconductors, the key ingredient to converting sunlight into electricity, many believe the next generation of solar panels will be made of a thin film technology that uses narrow coatings of cadmium telluride in solar cells - this technology promises to be a much cheaper and more efficient way to engage the photovoltaic process. One major obstacle for cadmium telluride thin film cells is that they become highly unstable during the manufacturing process, which currently uses cadmium chloride. Researchers have devised a new, safe and seemingly low cost way to overcome this hurdle by using a material called magnesium chloride in replace of cadmium chloride. Magnesium chloride is recovered from seawater, an abundant resource, which makes the resource very low cost, as well as non-toxic. Replacing the manufacturing process with this material promises to increase the efficiency of these solar cells from two percent to up to fifteen percent.

New Solar Applications

When most people think of solar PV systems they think of them atop roofs or mounted for industrial scale use. But researchers are exploring a number of unconventional solar applications that could promise to transform the industry.

Solar Roadways. Scientists are exploring ways to actually line highways and roads with solar panels that would then be used to deploy large amounts of electricity to the grid. This would help overcome a major barrier to industrial scale solar, which opponents say threatens to take up too much land. Solar roadways have already popped up in the Netherlands.

Floating Solar. Another way to address land use concerns associated with wide scale solar is to erect solar plants on the water, since over 70% of the Earth's surface is covered in water. Some researchers, including a French firm called Ciel et Terre, are experimenting with this technology. The company has projects set up in France, Japan, and England and other parts of the world are also piloting projects including a project in India and California in the U.S.

Space Based Solar. Scientists are resurrecting a technology that was first tested over forty years ago in which space-based satellites capture sunlight and convert it into microwave energy that is then beamed back to earth. This type of technology promises to capture significant more amount of sunlight (nearly ninety percent) since satellites can be positioned to optimize light capture round the clock. India, China and Japan are investing heavily in these technologies right now.

Source: http://www.altenergy.org/renewables/solar/latest-solar-technology.html

Invisibility cloak might enhance efficiency of solar cells

Material hides contact fingers that extract current from solar cells and cover the active surface; measurements confirm cloaking effect

Summary:

Success of the energy turnaround will depend decisively on the extended use of renewable energy sources. However, their efficiency partly is much smaller than that of conventional energy sources. The efficiency of commercially available photovoltaic cells, for instance, is about 20 percent. Scientists of Karlsruhe Institute of Technology have now published an unconventional approach to increasing the efficiency of the panels. Optical invisibility cloaks guide sunlight around objects that cast shadows on the solar panel.

A special invisibility cloak (right) guides sunlight past the contacts for current removal to the active surface area of the solar cell.

Success of the energy turnaround will depend decisively on the extended use of renewable energy sources. However, their efficiency partly is much smaller than that of conventional energy sources. The efficiency of commercially available photovoltaic cells, for instance, is about 20%. Scientists of Karlsruhe Institute of Technology (KIT) have now published an unconventional approach to increasing the efficiency of the panels. Optical invisibility cloaks guide sunlight around objects that cast a shadow on the solar panel, such as contacts for current extraction.

Energy efficiency of solar panels has to be improved significantly not only for the energy turnaround, but also for enhancing economic efficiency. Modules that are presently mounted on roofs convert just one fifth of the light into electricity, which means that about 80% of the solar energy are lost. The reasons of these high losses are manifold. Up to one tenth of the surface area of solar cells, for instance, is covered by so-called contact fingers that extract the current generated. At the locations of these contact fingers, light cannot reach the active area of the solar cell and efficiency of the cell decreases.

"Our model experiments have shown that the cloak layer makes the contact fingers nearly completely invisible," doctoral student Martin Schumann of the KIT Institute of Applied Physics says, who conducted the experiments and simulations. Physicists of KIT around project head Carsten Rockstuhl, together with partners from Aachen, Freiburg, Halle, Jena, and Jülich, modified the optical invisibility cloak designed at KIT for guiding the incident light around the contact fingers of the solar cell.

Normally, invisibility cloak research is aimed at making objects invisible. For this purpose, light is guided around the object to be hidden. This research project did not focus on hiding the contact fingers visually, but on the deflected light that reaches the active surface area of the solar cell thanks to the invisibility cloak and, hence, can be used.

To achieve the cloaking effect, the scientists pursued two approaches. Both are based on applying a polymer coating onto the solar cell. This coating has to possess exactly calculated optical properties, i.e. an index of refraction that depends on the location or a special surface shape. The second concept is particularly promising, as it can potentially be integrated into mass production of solar cells at low costs. The surface of the cloak layer is grooved along the contact fingers. In this way, incident light is refracted away from the contact fingers and finally reaches the active surface area of the solar cell (see Figure).

By means of a model experiment and detailed simulations, the researchers demonstrated that both concepts are suited for hiding the contact fingers. In the next step, it is planned to apply the cloaking layer onto a solar cell in order to determine the efficiency increase. The physicists are optimistic that efficiency will be improved by the cloak under real conditions: "When applying such a coating onto a real solar cell, optical losses via the contact fingers are supposed to be reduced and efficiency is assumed to be increased by up to 10%," Martin Schumann says.

Source: http://www.sciencedaily.com/releases/2015/09/150930110429.htm

Solar Manufacturer 1366 Technologies Selects New York for New Plant

New York draws another solar manufacturer as it continues to reform the energy vision.

By Chris Martin, Bloomberg

New York is about to become a hub for U.S. solar manufacturing as the state lured a start-up called 1366 Technologies Inc. to build its first factory in Genesee County.

With a package of state grants and tax incentives worth about $97 million, 1366 plans to start construction on a polysilicon wafer factory that will eventually produce 3 gigawatts (GW) a year and employ 1,000 people, Chief Executive Officer Frank van Mierlo said in an interview Wednesday. The wafers are used to make solar cells.

The new factory is in addition to the 1-GW panel factory that SolarCity Corp. is building nearby in Buffalo, which will make New York home to the largest solar manufacturing plant in the western hemisphere when its completed in the first quarter of 2017. Governor Andrew Cuomo agreed to contribute about $750 million for that project.

“We’re going to have a very competitive factory in New York,” 1366’s van Mierlo said. Power costs in that part of the state are low compared with other regions and are supplied mostly by hydroelectric dams, so the solar factories will run on renewable energy, he said.

Different Technologies

That echoes the comments of SolarCity CEO Lyndon Rive when his company broke ground on their factory in September 2014. The two manufacturers use different technologies, and van Mierlo doesn’t expect to sell his wafers to SolarCity.

Within an initial $100 million investment, the 1366 factory will be capable of producing about 60 million wafers annually, which corresponds to 250-MW of power-generation capacity. The company’s Direct Wafer Technology produces them in a single step that reduces waste, improves efficiency and cuts costs, he said.

The Bedford, Massachusetts-based company plans to gain market share quickly with its lower-cost wafers and van Mierlo said he’ll know by the time the factory opens how fast to expand to the planned three gigawatts.

“We’ll sell at a discount to market prices to grow rapidly,” van Mierlo said.

John B. Rhodes, President and CEO of the New York State Research and Development Authority (NYSERDA) reacted positively to the news. In a statement he said that the announcement “shows how Governor Cuomo’s Reforming the Energy Vision strategy spurs economic development, creates jobs and protects the environment. This project will build out the state’s growing clean energy economy, improve solar manufacturing, lower the cost of solar panels, and boost the solar market.

Source:  http://www.renewableenergyworld.com/articles/2015/10/solar-manufacturer-1366-technologies-selects-new-york-for-new-plant.html

How do solar systems produce energy?

Solar power is arguably the cleanest, most reliable form of renewable energy available, and it can be used in several forms to help power your home or business. Solar-powered photovoltaic (PV) panels convert the sun's rays into electricity by exciting electrons in silicon cells using the photons of light from the sun. This electricity can then be used to supply renewable energy to your home or business.

To understand this process further, let’s look at the solar energy components that make up a complete solar power system.

The roof system
In most solar systems, solar panels are placed on the roof. An ideal site will have no shade on the panels, especially during the prime sunlight hours of 9 a.m. to 3 p.m.; a south-facing installation will usually provide the optimum potential for your system, but other orientations may provide sufficient production. Trees or other factors that cause shading during the day will cause significant decreases to power production. The importance of shading and efficiency cannot be overstated. In a solar panel, if even just one of its 36 cells is shaded, power production will be reduced by more than half. Experienced installation contractors such as NW Wind & Solar use a device called a Solar Pathfinder to carefully identify potential areas of shading prior to installation.

Not every roof has the correct orientation or angle of inclination to take advantage of the sun's energy. Some systems are designed with pivoting panels that track the sun in its journey across the sky. Non-tracking PV systems should be inclined at an angle equal to the site’s latitude to absorb the maximum amount of energy year-round. Alternate orientations and/or inclinations may be used to optimize energy production for particular times of day or for specific seasons of the year.

Solar panels
Solar panels, also known as modules, contain photovoltaic cells made from silicon that transform incoming sunlight into electricity rather than heat. (”Photovoltaic” means electricity from light — photo = light, voltaic = electricity.)

Solar photovoltaic cells consist of a positive and a negative film of silicon placed under a thin slice of glass. As the photons of the sunlight beat down upon these cells, they knock the electrons off the silicon. The negatively-charged free electrons are preferentially attracted to one side of the silicon cell, which creates an electric voltage that can be collected and channeled. This current is gathered by wiring the individual solar panels together in series to form a solar photovoltaic array. Depending on the size of the installation, multiple strings of solar photovoltaic array cables terminate in one electrical box, called a fused array combiner. Contained within the combiner box are fuses designed to protect the individual module cables, as well as the connections that deliver power to the inverter. The electricity produced at this stage is DC (direct current) and must be converted to AC (alternating current) suitable for use in your home or business.

Inverter
The inverter is typically located in an accessible location, as close as practical to the modules. In a residential application, the inverter is often mounted to the exterior sidewall of the home near the electrical main or sub panels. Since inverters make a slight noise, this should be taken into consideration when selecting the location.

The inverter turns the DC electricity generated by the solar panels into 120-volt AC that can be put to immediate use by connecting the inverter directly to a dedicated circuit breaker in the electrical panel.

The inverter, electricity production meter, and electricity net meter are connected so that power produced by your solar electric system will first be consumed by the electrical loads currently in operation. The balance of power produced by your solar electric system passes through your electrical panel and out onto the electric grid. Whenever you are producing more electricity from your solar electric system than you are immediately consuming, your electric utility meter will turn backwards!

Net meter
In a solar electric system that is also tied to the utility grid, the DC power from the solar array is converted into 120/240 volt AC power and fed directly into the utility power distribution system of the building. The power is “net metered,” which means it reduces demand for power from the utility when the solar array is generating electricity – thus lowering the utility bill. These grid-tied systems automatically shut off if utility power goes offline, protecting workers from power being back fed into the grid during an outage. These types of solar-powered electric systems are known as “on grid” or “battery-less” and make up approximately 98% of the solar power systems being installed today.

Other benefits of solar
By lowering a building’s utility bills, these systems not only pay for themselves over time, they help reduce air pollution caused by utility companies. For example, solar power systems help increase something called “peak load generating capacity,” thereby saving the utility from turning on expensive and polluting supplemental systems during periods of peak demand. The more local-generating solar electric power systems that are installed in a given utility's service area, the less capacity the utility needs to build, thus saving everyone from funding costly additional power generating sources. Contributing clean, green power from your own solar electric system helps create jobs and is a great way to mitigate the pollution and other problems produced by electricity derived from fossil fuel. Solar-powered electrical generating systems help you reduce your impact on the environment and save money at the same time!

Source: http://www.nwwindandsolar.com/solar-power-in-seattle-and-the-northwest/how-do-solar-systems-produce-energy/

Make Solar Energy Economical

Summary
Solar energy provides less than 1% of the world's total energy, but it has the potential to provide much, much more.

As a source of energy, nothing matches the sun. It out-powers anything that human technology could ever produce. Only a small fraction of the sun’s power output strikes the Earth, but even that provides 10,000 times as much as all the commercial energy that humans use on the planet.

Why is solar energy important?

Already, the sun’s contribution to human energy needs is substantial — worldwide, solar electricity generation is a growing, multibillion dollar industry. But solar’s share of the total energy market remains rather small, well below 1 percent of total energy consumption, compared with roughly 85 percent from oil, natural gas, and coal.

Those fossil fuels cannot remain the dominant sources of energy forever. Whatever the precise timetable for their depletion, oil and gas supplies will not keep up with growing energy demands. Coal is available in abundance, but its use exacerbates air and water pollution problems, and coal contributes even more substantially than the other fossil fuels to the buildup of carbon dioxide in the atmosphere.

For a long-term, sustainable energy source, solar power offers an attractive alternative. Its availability far exceeds any conceivable future energy demands. It is environmentally clean, and its energy is transmitted from the sun to the Earth free of charge. But exploiting the sun’s power is not without challenges. Overcoming the barriers to widespread solar power generation will require engineering innovations in several arenas — for capturing the sun’s energy, converting it to useful forms, and storing it for use when the sun itself is obscured.

Many of the technologies to address these issues are already in hand. Dishes can concentrate the sun’s rays to heat fluids that drive engines and produce power, a possible approach to solar electricity generation. Another popular avenue is direct production of electric current from captured sunlight, which has long been possible with solar photovoltaic cells.

How efficient is solar energy technology?

But today’s commercial solar cells, most often made from silicon, typically convert sunlight into electricity with an efficiency of only 10 percent to 20 percent, although some test cells do a little better. Given their manufacturing costs, modules of today’s cells incorporated in the power grid would produce electricity at a cost roughly 3 to 6 times higher than current prices, or 18-30 cents per kilowatt hour [Solar Energy Technologies Program]. To make solar economically competitive, engineers must find ways to improve the efficiency of the cells and to lower their manufacturing costs.

Prospects for improving solar efficiency are promising. Current standard cells have a theoretical maximum efficiency of 31 percent because of the electronic properties of the silicon material. But new materials, arranged in novel ways, can evade that limit, with some multilayer cells reaching 34 percent efficiency. Experimental cells have exceeded 40 percent efficiency.

Another idea for enhancing efficiency involves developments in nanotechnology, the engineering of structures on sizes comparable to those of atoms and molecules, measured in nanometers (one nanometer is a billionth of a meter).

Recent experiments have reported intriguing advances in the use of nanocrystals made from the elements lead and selenium. [Schaller et al.] In standard cells, the impact of a particle of light (a photon) releases an electron to carry electric charge, but it also produces some useless excess heat. Lead-selenium nanocrystals enhance the chance of releasing a second electron rather than the heat, boosting the electric current output. Other experiments suggest this phenomenon can occur in silicon as well. [Beard et al.]

Theoretically the nanocrystal approach could reach efficiencies of 60 percent or higher, though it may be smaller in practice. Engineering advances will be required to find ways of integrating such nanocrystal cells into a system that can transmit the energy into a circuit.

How do you make solar energy more economical?

Other new materials for solar cells may help reduce fabrication costs. “This area is where breakthroughs in the science and technology of solar cell materials can give the greatest impact on the cost and widespread implementation of solar electricity,” Caltech chemist Nathan Lewis writes in Science. [Lewis 799]

A key issue is material purity. Current solar cell designs require high-purity, and therefore expensive, materials, because impurities block the flow of electric charge. That problem would be diminished if charges had to travel only a short distance, through a thin layer of material. But thin layers would not absorb as much sunlight to begin with.

One way around that dilemma would be to use materials thick in one dimension, for absorbing sunlight, and thin in another direction, through which charges could travel. One such strategy envisions cells made with tiny cylinders, or nanorods. Light could be absorbed down the length of the rods, while charges could travel across the rods’ narrow width. Another approach involves a combination of dye molecules to absorb sunlight with titanium dioxide molecules to collect electric charges. But large improvements in efficiency will be needed to make such systems competitive.

How do you store solar energy?

However advanced solar cells become at generating electricity cheaply and efficiently, a major barrier to widespread use of the sun’s energy remains: the need for storage. Cloudy weather and nighttime darkness interrupt solar energy’s availability. At times and locations where sunlight is plentiful, its energy must be captured and stored for use at other times and places.

Many technologies offer mass-storage opportunities. Pumping water (for recovery as hydroelectric power) or large banks of batteries are proven methods of energy storage, but they face serious problems when scaled up to power-grid proportions. New materials could greatly enhance the effectiveness of capacitors, superconducting magnets, or flyweels, all of which could provide convenient power storage in many applications. [Ranjan et al., 2007]

Another possible solution to the storage problem would mimic the biological capture of sunshine by photosynthesis in plants, which stores the sun’s energy in the chemical bonds of molecules that can be used as food. The plant’s way of using sunlight to produce food could be duplicated by people to produce fuel.

For example, sunlight could power the electrolysis of water, generating hydrogen as a fuel. Hydrogen could then power fuel cells, electricity-generating devices that produce virtually no polluting byproducts, as the hydrogen combines with oxygen to produce water again. But splitting water efficiently will require advances in chemical reaction efficiencies, perhaps through engineering new catalysts. Nature’s catalysts, enzymes, can produce hydrogen from water with a much higher efficiency than current industrial catalysts. Developing catalysts that can match those found in living cells would dramatically enhance the attractiveness of a solar production-fuel cell storage system for a solar energy economy.

Fuel cells have other advantages. They could be distributed widely, avoiding the vulnerabilities of centralized power generation.

If the engineering challenges can be met for improving solar cells, reducing their costs, and providing efficient ways to use their electricity to create storable fuel, solar power will assert its superiority to fossil fuels as a sustainable motive force for civilization’s continued prosperity.



References

Beard, M.C., et al.  2007.  Multiple Exciton Generation in Colloidal Silicon Nanocrystals.  Nano Letters 7(8): 2506-2512.  DOI: 10.1021/nl071486l S1530-6984(07)01486-5

DOE (U.S. Department of Energy).  2007.  Solar America Initiative: A Plan for the Integrated Research, Development, and Market Transformation of Solar Energy Technologies.  Report Number SETP-2006-0010.  Office of Energy Efficiency and Renewable Energy Solar Energy Technologies Program.  Washington, D.C.: DOE.

DOE.  Solar Energy Technologies Program Multi-Year Program Plan 2007-2011.  Office of Energy Efficiency and Renewable Energy.  Washington, D.C.: DOE.

Lewis, N.S.  2007.  Toward Cost-Effective Solar Energy Use.  Science 315(5813): 798-801.  DOI: 10.1126/science.1137014

Ranjan, V., et al.  2007.  Phase Equilibria in High Energy Density PVDF-Based Polymers.  Physical Review Letters 99: 047801-1 - 047801-4.  DOI: 10.1103/PhysRevLett.99.047801

Schaller, R.D., and V.I. Klimov.  2004.  High Efficiency Carrier Multiplication in PbSe Nanocrystals: Implications for Solar Energy Conversion.  Physical Review Letters 92(18): 186601-1 - 186601-4.  DOI: 10.1103/PhysRevLett.92.186601

Source: http://www.engineeringchallenges.org/challenges/solar.aspx