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Are the solar roadways covered in snake oil?

They did pass their traction tests, but the excitement for solar roadways is a little premature.  Is the product innovative? #Totally. Here’s a quick rundown of what the Solar Roadways phenomenon is about.  Several years back, the Federal Highway Administration funded a project for roadways that could pay for themselves.  Solar Roadways’ prototype provides modular roads with solar panels integrated within them to generate electricity.  They will also be fitted with heaters and LED’s to clear roads of ice and warn drivers of conditions ahead. There are many other features that make it great, and we’ll save reality for last.

Why did this pipe dream go viral?

Good public relations and a revolutionary new type of road.  Solar panels last for 25 years and often see a payback within ten years or less.  That concept alone of a road that can last 25 years and create a return on investment is already better than stinky asphalt.  I’ve been told that in other parts of the country; their roads get covered in frozen water and become difficult to drive on.  This prototype contains heaters that will melt all of that frozen water that will eliminate ice related accidents and snow plows. Pretty awesome if you’ve been stuck behind one or have seen the salts eat away at your car.

Next awesomeness, the LED warning system.  Personally, this is my favorite feature of the solar roadways and is totally viable for particular situations.  From this picture, you can see that the roadways will replace the painted stripes, crosswalks, etc.  In the middle of the photo, you can see someone crossing the street and the crosswalk turns red.  You can also see the speed limit displayed and the bike path illuminated.  We could instantly change the speed limit, warn drivers of pedestrians or wildlife, or any other emergency situation.

Pave all the roads with solar!

They want to put these roadways everywhere.  Installers have a general rule of thumb, don’t install solar where the sun don’t shine.  Here’s a quick list of things that cause shade, everything that is not transparent like a tree, a building, or a car. The designers have danced around the question of which solar technology they will use.  Photovoltaic crystalline panels actually have serious performance issues even in partial shade because of weird physics voodoo that exponentially messes up production. Thin film solar does not share this issue and only loses ten percent of production when ten percent is shaded.  Thin film is flexible and theoretically cheaper, but it’s less efficient.  I would feel more confident with them using thin film while we put efficient PV on the roofs. They are currently using microinverters and from pictures it appears as they are using crystalline cells.  This adds cost and more components that can break.  They have been working the numbers though, and microinverters might be the most cost-effective solution to increase production.

Shade is the enemy

Roads get shade from just about everything because they are the lowest point.  A lot of things are built next to roads because that’s um…. #convenient. Buildings cast huge shadows.  I think Solar Roadways have potential in downtown intersections to safely alert drivers of pedestrians, bicyclists, and snow.

There are a lot of other cool possibilities with these from cabling conduits, wastewater treatment, piezoelectric generators, etc.  My sort of problem is that it shouldn’t be seen as a solution to climate change or meeting renewable energy requirements.  It is a solution to a safer society. There is no possible way that these road modules will be more efficient than a roof or ground mounted solar system.  The roadways have thick textured glass, that can withstand 250,000 POUNDS, that will get dirty and obstruct light from hitting the solar cell.

After reading a few other critical roadways articles, it’s apparent they aren’t there yet. The sound alone from the textured surface makes a silent, clean technology annoying.  We need to take a step back and remember that this is still in its prototyping phase.  Lots of stuff can change and lots of stuff can prevent it from coming to fruition.  Sit back and join Ameco in installing effective, affordable solar solutions.

Founders reply to the “haters”

Trumpets are blaring and drums are rolling because AMECO Solar has a new website!

Our new, fresh design was planned with a straight-forward layout that is much easier to navigate. Just one look at our new homepage and you can easily tell that AMECO Solar is a full-service solar installation company. We have options for anyone interested in solar panels from residential solar electric and solar pool installations to medium-sized commercial systems and large-scale solar installations.

You may click through our pages to learn more about solar energy by checking out step-by-step explanations of how it works or reading our pages on residential solar installation and commercial solar installation.

Of course, you may already know that our company blog is a great resource about solar installation.  Plus, we would also like to highlight our new Solar Installation Photo Gallery. It features photos of our recent solar installs, and new photos are being added all the time.

Give the new AMECO Solar website a spin…we hope you’ll like it!

You've probably seen headlines about incredible new solar panel films that can be rolled up or even integrated into windows. This exciting technology is all about thin film photovoltaic solar panels. Their flexibility and light weight are game-changers, opening doors for solar power in places we never thought possible. But this raises an important question for homeowners: if this thin film photovoltaic tech is so great, why aren't we all using it? Let's explore what makes these panels so unique and why the trusted solar modules AMECO installs are still the best choice for your roof.

While they’re considerably thinner and could potentially be sold at a lower cost, the technology is still in the early stages and not available for residential installation just yet.

What Are Thin-Film Photovoltaic Solar Panels?

So, what exactly is this technology? Think of thin-film solar panels as a streamlined version of the traditional solar panels you see on rooftops. Instead of using thick, rigid silicon wafers, they are made by placing incredibly thin layers of photovoltaic material—the stuff that converts sunlight into electricity—onto a base. This base, or substrate, can be anything from glass to flexible plastic or even metal. The result is a solar cell that is hundreds of times thinner than a standard silicon cell, making it lightweight and versatile. While this technology is still evolving for home use, it represents an exciting direction for solar energy, promising new applications and manufacturing methods that could change how we power our world.

How Are Thin-Film Panels Made?

The manufacturing process for thin-film panels is quite different from that of their crystalline silicon cousins. It’s less about slicing individual wafers and more about depositing layers of material. This method is generally faster and requires less energy and raw material, which is a big part of the technology's appeal. The specific process depends on the type of photovoltaic material being used, but the core idea is to build the solar cell layer by layer. This approach is what gives thin-film panels their unique characteristics, including their signature slim profile and flexibility, opening the door for solar technology to be integrated in ways we haven't seen before.

The Layered Structure

At its heart, a thin-film solar panel is a sandwich of specialized materials. It starts with a substrate, like glass or plastic, which provides the foundation. On top of that, a very thin layer of photovoltaic material is deposited. This is the active layer that absorbs sunlight and generates an electric current. Common materials include amorphous silicon (a-Si), cadmium telluride (CdTe), or copper indium gallium selenide (CIGS). A conductive sheet is added to help the electricity flow, and the whole thing is sealed with a protective top layer to shield it from the elements. This layered construction is what makes them so distinct from traditional panels.

Manufacturing Process and Materials

The creation of thin-film panels involves depositing these photovoltaic materials in a vacuum, a process that allows for precise, uniform layers. Because the active material is so thin, manufacturers can use less of it, which helps reduce production costs and the overall environmental footprint. The choice of material—whether it's the abundant and non-toxic amorphous silicon or the highly efficient cadmium telluride—plays a huge role in the panel's performance, cost, and ideal application. This advanced manufacturing is what makes the technology so promising for large-scale production and innovative uses beyond typical rooftop installations.

A Brief History of Thin-Film Technology

While it might seem like a cutting-edge development, the story of thin-film solar technology actually begins decades ago. Researchers started exploring the potential of thin-film materials back in 1972, looking for more efficient and cost-effective alternatives to traditional silicon. After years of development and refinement in the lab, the first commercial thin-film solar panel was introduced in 1986. Since then, scientists and engineers have continued to improve the efficiency and durability of these panels, pushing the boundaries of what's possible and bringing this innovative technology closer to widespread use in both commercial and residential settings.

Types of Thin-Film Solar Panels

Thin-film technology isn't a one-size-fits-all solution; it’s a family of different technologies, each with its own unique material composition and strengths. The four main types you'll hear about are Cadmium Telluride (CdTe), Copper Indium Gallium Selenide (CIGS), Amorphous Silicon (a-Si), and Gallium Arsenide (GaAs). Each type uses a different combination of elements to capture sunlight and convert it into energy. Understanding the differences between them helps explain why one might be better suited for a large-scale solar farm while another might be perfect for flexible, portable applications. This variety is a key strength of thin-film technology, allowing for tailored solutions to different energy needs.

Cadmium Telluride (CdTe)

Cadmium Telluride is currently the most common type of thin-film solar panel on the market, especially for large, utility-scale projects. Its popularity comes from a combination of good efficiency and relatively low manufacturing costs. In laboratory settings, CdTe cells have reached efficiencies of around 22%, while commercially available panels from leading manufacturers typically achieve about 18% efficiency. This makes them competitive with some traditional silicon panels. CdTe technology has a low carbon footprint and a quick energy payback time, making it a strong contender in the renewable energy landscape, particularly for commercial and industrial applications.

Copper Indium Gallium Selenide (CIGS)

CIGS panels are known for their high efficiency potential and versatility. In the lab, CIGS cells have demonstrated efficiencies of over 23%, putting them at the top of the thin-film category. One of the most exciting aspects of CIGS technology is that it can be deposited on flexible substrates, creating lightweight panels that can be integrated into a variety of surfaces, from metal roofs to vehicle exteriors. This flexibility opens up a world of possibilities for solar power, though the manufacturing process can be more complex than that of other thin-film types, which has impacted its market share.

Amorphous Silicon (a-Si)

Amorphous Silicon is the non-crystalline form of the same element used in traditional solar panels. Because silicon is abundant and non-toxic, a-Si panels are an attractive option from an environmental and resource perspective. They are also relatively inexpensive to produce. While their efficiency is generally lower than other thin-film types, they perform well in low-light conditions and can be made flexible. You’ve likely seen a-Si technology in action in small electronics like solar-powered calculators and watches, but it's also used in larger applications where high efficiency isn't the primary concern.

Gallium Arsenide (GaAs)

When it comes to performance, Gallium Arsenide is the champion of thin-film solar cells. These cells hold the record for the highest efficiency of any single-junction solar cell, reaching an impressive 29.1%. They are also known for their excellent heat resistance, maintaining their performance even in very high temperatures. However, this high performance comes at a cost—GaAs is expensive to produce. Because of this, its use is typically reserved for specialized applications where efficiency and durability are absolutely critical, such as in satellites and spacecraft for aerospace missions.

Thin-Film vs. Traditional Crystalline Panels

When deciding on a solar solution for your home, the choice usually comes down to traditional crystalline panels, which is the technology we trust and install at AMECO. These panels have a long track record of reliability and high efficiency. However, it's helpful to understand how thin-film technology compares. The main differences lie in their efficiency, cost, appearance, and performance under various conditions. While thin-film panels offer unique advantages like flexibility and a lower profile, traditional panels currently provide the durability and power output that most homeowners need to see a significant return on their investment.

Key Advantages of Thin-Film Technology

Thin-film solar panels bring some unique benefits to the table that set them apart from conventional options. Their manufacturing process is less energy-intensive and requires fewer raw materials, which can lead to a lower overall cost and a smaller environmental footprint. They also tend to have a sleeker, more uniform appearance that some people find more aesthetically pleasing. Perhaps most importantly, their performance in certain conditions, like high heat and low light, can be superior to that of traditional panels, making them a versatile option for a range of environments and applications.

Flexibility and Lightweight Design

One of the most significant advantages of thin-film technology is its physical form. Because the photovoltaic material is deposited in such a thin layer, the panels can be made lightweight and even flexible. This opens up a whole new world of applications where traditional, rigid panels just wouldn't work. Imagine solar technology integrated directly into roofing materials, the body of a car, or even portable charging mats that you can roll up and take with you. This versatility is a key reason why researchers are so excited about the future of thin-film solar.

Performance in Low Light and High Heat

Here in California, we get plenty of sun, but we also get plenty of heat. High temperatures can actually reduce the efficiency of traditional silicon solar panels. Thin-film panels, however, tend to handle heat better, losing less power as the temperature rises. They also generally perform better than their crystalline counterparts in low-light or overcast conditions. This means they can continue to produce a more consistent amount of energy throughout the day, from sunrise to sunset, even when the sun isn't shining at full strength.

Environmental Impact and Energy Payback

From a sustainability standpoint, thin-film panels have a strong case. Their manufacturing process is typically faster and requires less energy compared to producing crystalline silicon panels. This results in a shorter energy payback time—the time it takes for a panel to generate enough clean energy to offset the energy used to produce it. For some thin-film technologies, this payback period can be as short as a year. This quick turnaround, combined with the use of fewer raw materials, makes them an appealing option for reducing our carbon footprint.

Disadvantages and Considerations

Despite their advantages, thin-film panels have a few key drawbacks that have kept them from becoming the standard for residential installations. The primary concern is their lower efficiency compared to traditional crystalline silicon panels. This means you would need a larger surface area of thin-film panels to generate the same amount of electricity, which can be a problem for homes with limited roof space. Additionally, many thin-film technologies tend to have a shorter operational lifespan and can degrade faster over time, which is a critical factor when considering a long-term investment in your home's energy future. This is why proven, durable solar solutions remain the top choice for homeowners.

Are Thin Film Photovoltaic Panels Efficient Enough?

The major issue holding back thin-film solar? Efficiency. A typical solar electric panel can convert about 20 percent of the sunlight that hits them into electricity, while thin-film solar cells currently in development only have efficiency rates in the single digits.

As a result, one of the main focuses of renewable energy researchers is to develop thin-film solar modules that can match or improve on the efficiency of conventional panels.

Lifespan and Durability

Beyond efficiency, another key consideration is how long the panels will last. Thin-film panels generally have a shorter lifespan, typically lasting between 10 to 20 years. While this is less than the 25-plus years you can expect from the traditional crystalline panels we install, the technology is constantly improving. According to research from EcoWatch, these panels can sometimes pay for themselves more quickly through electricity savings, which helps offset their shorter operational life. For now, homeowners looking for a long-term, durable investment find that conventional solar panels offer more peace of mind and proven longevity for their rooftops.

Where Are Thin-Film Solar Panels Used Today?

Even though thin-film panels aren't the standard for residential rooftops just yet, they’ve found some really interesting and practical uses in other areas. Because they are lightweight, flexible, and perform well in various conditions, they are the perfect solution for specific applications where traditional panels just wouldn't work. From massive energy projects to innovative building designs, thin-film technology is already making a significant impact. These applications showcase the unique strengths of the technology and give us a glimpse into what a more solar-integrated future might look like for both large-scale commercial projects and everyday life.

Utility-Scale Solar Farms

Picture vast fields covered in solar panels, generating power for thousands of homes—that's a utility-scale solar farm. Thin-film panels are often a great fit for these massive projects. Their lower manufacturing cost and lighter weight make them easier and more affordable to install over large areas. While their efficiency is lower, space isn't a constraint in a sprawling desert field, so developers can simply use more panels to generate the required amount of energy. The American Solar Energy Society notes that these qualities make thin-film a promising technology for the future of the solar industry, especially in these large-scale applications that power our communities.

Building-Integrated Photovoltaics (BIPV)

This is where solar technology starts to feel like science fiction. Building-Integrated Photovoltaics, or BIPV, involves integrating thin-film solar cells directly into building materials. Instead of mounting panels on a roof, the solar technology becomes part of the structure itself. As Solar Magazine highlights, this can look like solar shingles that blend seamlessly with a roof, or even transparent solar cells embedded in windows that generate power while letting light through. This approach combines aesthetics with functionality, and while it's still an emerging field, it points toward a future where our buildings are also our power plants. It’s an exciting concept that merges expert roofing with energy generation.

Portable and Mobile Applications

One of the coolest advantages of thin-film solar is its flexibility. Unlike rigid crystalline panels, some thin-film materials can be bent or rolled up without breaking. This makes them perfect for on-the-go power. You can find this technology in portable solar chargers for camping, integrated into backpacks to power your devices, or even applied to curved surfaces. For example, flexible thin-film panels can be installed on the roofs of RVs or the decks of boats, providing a source of clean energy for life on the move. This adaptability opens up a world of possibilities for personal power generation that just isn't possible with traditional panels.

The Future of Solar Technology

So, what does all this mean for you as a homeowner? While thin-film technology is incredibly promising and already proving its worth in specific industries, it’s still on the path to becoming a mainstream residential option. Researchers are working hard to improve efficiency and durability, and as manufacturing scales up, costs are expected to come down. The future is bright for this innovative technology, and it will likely play a huge role in our global transition to clean energy. For today, however, the most reliable, efficient, and cost-effective solution for powering your home remains traditional crystalline solar panels. They offer a proven track record of performance and longevity, ensuring you get the best return on your investment. When you're ready to explore the best solar solutions available now, our team can help you find the perfect fit for your home's needs.

Can Gemstones Improve Solar Panel Performance?

Many studies have been published on the subject showing the possibility of higher conversion rates, but one of the most interesting is a report published in the academic journal Advanced Optical Materials.

Scientists at Purdue University in Indiana, have used light diffraction properties in gemstones, specifically opal, to come up with a molecular structure that does a more efficient job of capturing sunlight. They referred to this structure as “inverse opal.”

In simpler terms, the gemstones cause the sunlight to spread out within the thin-film solar panel instead of bouncing directly out. By keeping the sunlight within the solar cell, the solar cell therefore creates more usable energy. This technology could result in solar panels that are 100 times less expensive than conventional solar panels.

The Role of Emerging Technologies

The "inverse opal" structure is a perfect example of the creative thinking driving thin-film solar forward. It's just one piece of a larger puzzle, as scientists are constantly experimenting with new photovoltaic materials and manufacturing techniques. They're exploring compounds like Cadmium Telluride (CdTe) and Copper Indium Gallium Selenide (CIGS) to develop panels that are not only more efficient but also lightweight and flexible enough to be used in new and exciting ways. The ultimate goal is to make solar energy more versatile and affordable than ever before. While this cutting-edge technology is still on the horizon, we at AMECO are always watching these advancements to ensure we provide our customers with the most effective and reliable solar solutions available today.

Breaking Down the True Cost of Solar

Innovations such as this are important for the solar industry, as panel prices have already dropped significantly in the last decade. This has led many industry observers to speculate that silicon PV modules could soon “hit bottom,” at which point further reductions simply wouldn’t be possible.

That would mean that price decreases would have to come from other areas, such as eliminating inefficiencies in the supply chain or even lowering administrative costs. These aspects of solar pricing are referred to as “soft costs,” and they’ve remained relatively flat while panel prices have come down. To reduce prices further, it will be necessary to develop thin-film modules for commercial use.

Homeowners may have to wait a few years for thin-film solar to become commercially available for residential solar energy systems, but that doesn’t mean residents can’t take advantage of solar power today. AMECO can provide your family with a solar electric system that will lower your monthly energy expenses and help you reduce your carbon footprint. For more information, contact us today by calling (888) 595-9570 or emailing gosolar@th2.e81.myftpupload.com!

Are Thin-Film Panels Right for Your Home?

While the idea of flexible, lightweight solar panels is certainly exciting, thin-film technology isn't quite ready for the average home just yet. The main hurdles are efficiency and longevity. For most homeowners, the goal is to generate as much power as possible from a limited rooftop space, and right now, thin-film panels require a much larger area to produce the same amount of energy as their traditional counterparts. Although they have found a niche in certain commercial applications and portable devices, they generally aren't the most practical or cost-effective choice for a residential solar installation today.

Why Crystalline Silicon Remains the Residential Standard

The primary reason crystalline silicon panels are the go-to for homes comes down to performance and durability. Standard solar panels, like the ones we install, typically convert around 20% of sunlight into usable electricity, while most thin-film options are significantly less efficient. This means you'd need to cover a much larger portion of your roof to get the same power output. Beyond efficiency, a home solar system is a long-term investment, and you want it to last. Crystalline silicon panels are known for their robust construction and long lifespans, often backed by 25-year warranties. In contrast, thin-film panels tend to degrade faster with a shorter lifespan of 10 to 20 years, making crystalline silicon the most effective and dependable solar solution for homeowners.

Frequently Asked Questions

Why aren't thin-film solar panels recommended for homes yet? The main reason comes down to efficiency and space. Your roof has a limited amount of surface area, and the goal is to generate as much power as possible from that space. Since traditional crystalline panels are significantly more efficient, they produce more electricity per square foot. To get the same amount of power from thin-film panels, you would need a much larger system, which most residential roofs simply can't accommodate.

What's the main advantage of thin-film panels if they're less efficient? Their biggest strengths are flexibility and their lightweight design. This allows them to be used in ways traditional panels can't, like on large-scale solar farms where space isn't an issue, or integrated directly into building materials. They are also perfect for portable applications, such as roll-up chargers for camping or power sources for RVs and boats, where adaptability is more important than maximum power output.

How much longer do traditional solar panels last compared to thin-film? A home solar system is a long-term investment, and durability is key. The crystalline silicon panels we install are built to last, typically coming with a 25-year warranty and an expected lifespan that can extend even further. Thin-film panels, on the other hand, generally have a shorter operational life, often in the range of 10 to 20 years, as the materials can degrade more quickly over time.

Could thin-film technology make solar more affordable in the future? Yes, that's one of the most exciting possibilities. The manufacturing process for thin-film panels uses less energy and fewer raw materials, which points to a lower production cost. As researchers continue to improve their efficiency and lifespan, this technology could play a major role in making solar energy more accessible and affordable for everyone, though it's not quite there for residential use today.

What are "building-integrated" solar panels? This is an innovative concept where thin-film solar cells are built directly into the construction materials of a building. Instead of placing panels on top of a roof, the solar technology becomes a part of the roof itself, like solar shingles. It can even be integrated into windows as a transparent film that generates electricity. This approach blends energy production with design, creating a seamless and functional aesthetic.

Key Takeaways

• Thin-film solar shows future promise: While its flexibility is exciting for large-scale projects and portable gadgets, this technology isn't efficient enough yet for the limited space on a typical home's roof.
• Performance is the deciding factor for homeowners: Traditional crystalline panels provide higher efficiency, converting more sunlight into power, and offer a much longer lifespan of over 25 years compared to the 10 to 20 years for thin-film.
• Proven technology is your best bet today: For a reliable, long-term investment that maximizes your energy savings, crystalline silicon panels are the established and most effective choice for residential solar installations.

Related Articles

• Are Thin-Film Solar Cells the Future of Photovoltaics?
• Dye-Sensitized Solar Cells Herald Promising Future For Transparent Panels
• Ameco Solar News: UCLA's New Transparent Solar Film Could Be Game-Changer
• Researchers Develop Ultra-Thin, Light-Absorbing Material
• Top Solar Panels for 2023: Maximizing Efficiency | AMECO Solar

Happy Anniversary to AMECO Solar! This year our solar installation company is celebrating our 40th anniversary.

That’s right, forty years! We’ve officially made it over the hill and are taking a look back on the history of our company. From our humble beginnings in 1974 to our many solar successes today in 2014, it has been a bright and sunny journey. Read on below for details on some of our highlighted accomplishments.

1974: Our company is founded under its original name Link (& Sun) Solar. Shortly thereafter, the name is changed to AMECO Solar, Inc.

1978: Congress passes the Energy Tax Act giving homeowners a tax credit for installing solar thermal panels. The law is seen as a way to promote energy conservation and shift away from using oil and gas.

1980: AMECO Solar joins CALSEIA, a nonprofit organization dedicated to spreading solar technology in the state. Later on, Patrick Redgate (our CEO) serves as an elected member.

1982: Thousands of Californians go solar taking advantage of the federal tax credit and the state’s generous rebates. AMECO Solar adds two offices to our original location in Long Beach.

1985: California’s Contractors State License Board (CSLB) creates a license specifically for solar contractors. AMECO Solar is one of the first solar companies to receive it and is given License #483280.

1996: Thanks to Governor Pete Wilson and the State Legislature, California offers solar rebates and incentives through the Emerging Renewables Program for solar electric systems.

2004: Governor Arnold Schwarzenegger promotes the Million Solar Roofs Program, challenging Californians to install 3,000 megawatts by 2017 to cut down on the output of greenhouse gasses.

2007: Authorized by the California Public Utilities Commission, the California Solar Initiative launches with new solar rebates for homeowners and businesses who are customers of SCE, PG&E and SDG&E.

2008: Now that the cost of solar is low and significant rebates are available, AMECO helps even more Californians go solar. We outgrow our offices yet again and move to our current location in Paramount.

2010: Because customers rate us so highly and write such great reviews on Angie’s List, AMECO Solar is awarded our first Angie’s List Super Service Award. We also receive this award in 2011, 2012 and 2013.

2014: AMECO Solar celebrates 40 years of installing solar panels for homeowners and businesses in Southern California. As we look back on our solar success, we are also looking forward to an even brighter future.

The following sources were referenced for this solar infographic: California Energy Commission, California Solar Initiative, Environment California, Wikipedia, Angie’s List, Contractors State Licensing Board, and The Capital Environmental News.