Powering your home, business or any other space using green energy can save you money while helping decrease your total carbon footprint. 

Solar Panels change free energy from the sun into electric power. Each panel consists of multiple photovoltaic cells made from mostly boron, silicon and phosphorus. 

There are at least 6 different types of solar panels. Learning the different kinds of solar panels can help you choose the right type for your situation.

How Do Solar Panels Work?

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The typical solar panel contains 3 distinct layers. There’s a silicon layer that acts as a semiconductor, a boron layer that serves as a positive charge generator, and a phosphorus sheet that produces a negative charge. 

When the sun shines, it emits packets of electromagnetic energy known as photons. And when these photons strike the surface of a solar module, the electrons in the silicon layer get excited. As a consequence, these electrons start flowing, kicking off a direct electric current (DC).

6 Solar Panel Types

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Solar cells differ in terms of performance, construction materials, efficiency, durability and quality. There are basically 6 different options to familiarize yourself with before you begin shopping:

1. Monocrystalline solar panels
2. Polycrystalline solar panels 
3. Thin-film solar panels
4. Concentrated solar panels
5. Bifacial solar panels
6. Biohybrid solar cells

Here’s what each kind looks like, how it works and where it’s typically used. 

1. Monocrystalline Solar Panels

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These are solar panels made from a single silicon crystal. You can easily tell this kind apart from others because it’s black in color. To make this panel, the manufacturer wastes tons of silicon, but the end product is pretty pure. 

While mono-crystalline panels demonstrate great performance in low light, the performance dips marginally when the sun heats up. Still, they’re one of the most efficient solar panel types that can be had. 

They typically have an efficiency rating of 20-25 percent according to The National Renewable Energy Laboratory (NREL). If you don’t have much room on your roof or have a bunch of cloudy days each year to contend with, consider installing this type. 

Finally, they’re quite durable. In fact, most have a 25-year warranty. Designing an entire photovoltaic solar system with these cells can cost a small fortune. 

Pros and Cons of Monocrystalline Solar Panels

Pros

• Highly efficient even in low sunshine; they’re one of the most efficient options on the market
• A good choice for small spaces and cloudy or Northern environments
• More durable than most
• A great option in situations that prioritize maximum power output

Cons

• Can be pretty expensive
• Made using a wasteful manufacturing process
• Performance dips to some extent when the temperature increases, but this happens to all types

Where they’re often used: Typically used to power residential buildings as well as commercial property. 

2. Polycrystalline Solar Panels 

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Poly means many. Polycrystalline solar panels are created from a bunch of silicon crystals. To make these units, manufacturers melt down multiple fragments of silicon into a block. They then cut down this block into multiple wafers which are molded into square-shaped panels.

They’re cheaper to produce compared to their single-crystal counterparts. However, the silicon fragments aren’t as pure, which is why they’re not as efficient. They’re identifiable by their blueish color. 

They also post good performance in low-sunshine conditions and their high temperature tolerance is remarkable. But they’re more vulnerable to heat-related degradation versus monocrystalline ones.

Their efficiency rating typically hovers between 15-20 percent, according to NREL. 

Pros and Cons of Polycrystalline Solar Panels

Pros

• More affordable compared to monocrystalline panels
• Perform satisfactorily in low-sunlight situations
• Demonstrate reasonably high temperature tolerance levels
• An OK option for large-scale installations
• Less wastage during the manufacturing process

Cons

• A lower heat tolerance level compared to monocrystalline cells
• Not as efficient as monocrystalline options in low-sunlight/cloudy scenarios since the silicon fragments used aren’t as pure

Where they’re often used: If you have to design a really large solar panel system while spending less money, consider installing polycrystalline panels.

3. Thin-Film Solar Panels

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One key difference between thin-film and crystalline solar panels is that the former isn’t 100 percent silicon-dependent. 

Manufacturers use alternative materials such as amorphous silicon, copper indium gallium selenide, or cadmium telluride. “Amorphous” simply means not crystalline.

Several layers of these materials are added to a glass or plastic backing. Note that the CDC does say that cadmium is a cancer-causing agent. 

Thin-film panels aren’t as thick or stiff as their crystalline competitors. Being thinner and more flexible makes them easier to work with in different kinds of installation situations.

While they’re cheaper to produce, they’re less efficient than crystalline ones. The efficiency rating can be as low as 6 percent or as high as 18 percent depending on the material used. 

The most efficient are copper indium gallium selenide panels at upwards of 20 percent in laboratory tests. Cadmium telluride (CdTe) solar panels take second place at 10-11 percent while the least efficient material is amorphous silicon (a-Si) at about 7 percent, according to EnergySage. 

A single-crystal panel of a given size typically produces more power than a thin-film one of the same size. Also, the lifespan of a thin-film panel tends to be shorter.

One advantage thin-film solar panel systems have over crystalline options is a shorter payback time. That said, they’re not the most durable option. 

Another advantage is that their construction requires a smaller number of semiconductors, which means a smaller carbon footprint in the final analysis.

Pros and Cons of Thin-Film Solar Panels

Pros

• Lightweight, which makes them suitable for use in cases where portability and convenience are a priority (such as RVs)
• More flexible than crystalline options, making installation easier in different situations
• Lower construction costs, translating to lower costs overall and faster payback time
• A brilliant choice for gigantic solar panel system installs because they’re cheaper
• Associated with a lower carbon footprint 

Cons

• Not as efficient as crystalline choices
• Require more roof room to generate the same amount of energy as similarly sized conventional solar panels
• Not as durable as traditional types
• Cadmium is a known cancer-causing agent

Where they’re often used: They’re best suited for super-sized solar power projects where installation costs could quickly stack up and become a monstrous concern. 

They’re also a suitable choice for applications where weight and ease of installation are a priority. 

4. Concentrated Solar Panels (CSP Systems)

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Concentrated solar panels count on flat or parabolic mirrors or lenses to focus sunlight onto a small surface area of a photovoltaic material. 

They’re the best performing PV systems efficiency-wise, currently standing at 20 to 40 percent, according to NREL. 

What’s more, they’re great at energy storage, which makes them reliable pre-sunrise and post-sunset energy providers. However, they need tons of space to function optimally. 

Often used in large-scale commercial power plants, these are highly efficient solar energy generators. Once harnessed, the energy from the sun powers turbines which in turn generate electrical energy. 

Advantages and Disadvantages of Concentrated Solar Panels

Pros

• High-efficiency solar power systems; the most efficient solar system available
• Suitable for generating massive amounts of renewable energy
• A reliable source of energy even when the sun isn’t shining

Cons

• Not viable in densely populated areas 
• Large quantities of water needed for driving the steam engines and cooling the system

Where they’re often used: They’re pretty common in large-scale solar power plants.

5. Bifacial Solar Panels

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Green Tech Media predicts that by 2024, installed bifacial module capacity will be in excess of 21 gigawatts. This estimated capacity could be as much as four times what it was in 2019.

While mono facial solar panels (traditional ones) rely on one surface to harness solar radiation, bifacial solar panels put two sunlight-trapping, tempered-glass surfaces to work.

They deliver a higher energy yield compared to conventional solar panels of the same size, up to 11 percent more, according to Energy Link. 

Small wonder they’re costlier than single-surface panels. Since they’re more efficient, however, you need fewer panels or less room on the roof. 

With this technology, consumers could get a 30-year warranty versus the usual 25-year warranty. These solar panels are of better quality than conventional ones, perform better, look nicer (because they’re frameless) and last longer. 

Pros and Cons of Bifacial PV Solar Panels

Pros

• Generate more energy compared to regular panels of the same size
• Last longer and perform better than most PV panels in diffuse light/low-sunshine environments
• Are frameless and made from tempered glass, which many find more aesthetically pleasing
• Longer warranties 
• Great for consumers with space constraints  

Cons

• Pricier than conventional panel systems 
• Heavier than regular panels and require specialized equipment for installation, which bumps up installation costs
• Way less flexible, making installation more challenging

Where they’re often used: Homes and offices without much roof space 

6. Biohybrid Solar Panels

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While still under research, this type of solar panel is worth keeping an eye on. When making biohybrid solar panels, manufacturers combine organic matter with inorganic matter.

Like regular solar panels, hybrid solar panels convert photonic energy into electrical energy, but hybrids work a little differently. They convert the sun’s energy into chemical energy through a photosynthesis-like process before creating an electric current that flows through the cell. 

This new type of solar panel could cost less to construct and have a high solar radiation conversion rate in comparison to regular solar cells. However, their reliability as a continuous energy source may not be guaranteed. Besides that, their lifespan and durability could be questionable.

These devices are currently inaccessible outside of research laboratories, but this might soon change. 

Pros and Cons of Biohybrid Solar Panels

Pros

• Have a super high solar energy conversion potential
• Less costly to make compared to regular panels
• Almost zero power losses when converting chemical energy into electrical power 

Cons

• Not available for use in homes and businesses since they’re still being researched and developed
• Durability and lifespan aren’t great

Wrapping Up

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Understanding the advantages and disadvantages of different types of solar panels is helpful because it makes picking out an option that matches your anticipated household energy consumption easier. 

For most residential and commercial applications, monocrystalline and polycrystalline solar panels are ideal because they’re pretty efficient and long lasting.

For specific installations, thin-film panels work great. And for setting up massive and reliable power generators, concentrated solar power panels are the way to go. 

Feature image: American Public Power Association; Image 1: Marco Pregnolato

The post What Types Of Solar Panels Are There? appeared first on Green Building Canada.

The post What Types Of Solar Panels Are There? appeared first on Green Building Canada.