Category: Solar Recycling Benefits

How Much Silver Is Used in Solar Panels?

Find out how much silver is used in solar panels below

Solar panels and their accompanying systems are growing more popular among people looking for an alternative electricity supply or a backup for the grid. Unknown to many, silver plays a key role in the fabrication of these panels, and its supply is affected by the continuous rise in demand for solar power.

Solar Panel Demand Causing Increase in Silver Prices

If you’re wondering why silver is so important in making solar panels, it’s because silver is a metal with incredibly low electrical resistance. Other closely related metals cannot sufficiently match its conductivity for these panels. Silver is so crucial that it can equate up to 6 percent of the total cost of building each unit of the panel.

The average panel of approximately 2 square meters can use up to 20 grams of silver. There’s a silver paste in the solar photovoltaic (PV) cells that collects the electrons generated when the sunlight hits the panel. Because of silver’s high conductivity, it maximally converts sunlight into electricity.

A recent market trend report conducted by London-based consultancy CRU explored the relationship between the demand for solar power and the market trend of silver. According to this study, the solar power industry will likely continue to face expansion as a result of the combination of favorable government policies and global efforts to diminish our reliance on fossil fuel. Even industrial sites, especially those in remote locations, recognize solar as a competitive alternative to power supply from the grid.

New research anticipates that the cost of silver’s use in building each solar panel unit will increase to over 10 percent by the end of 2020. Also noteworthy, the growing cost of its contribution to the panels could greatly outweigh its expense percentage per unit with any other industrial use of silver in the future.

As of 2018, the solar panel manufacturing industry used about 8% of the world’s annual physical silver supply. In the near future, the entire world, and especially in fast-growing countries like China, is expected to experience an increased demand for solar power systems, which may cause a temporary rise in the price of silver. This, of course, would negatively affect the cost of producing solar panels.

Silver To Be Less Needed in Future Panels

The CRU study predicts that the PV sector will consume about 81 million ounces of silver per year over the next decade. Much more silver was used in 2019 in making PV cells (100 million ounces). This anticipated drop implies that the market demand may have peaked in the previous year.

Also noteworthy, PV cells made with materials other than silver, such as copper and aluminum, usually turn out to be less reliable. This presents a major challenge for the commercial progress of these non-silver PVs, but it is one that leading manufacturers are making progress towards resolving.

Recovering the Value of Used Silver in PV Equipment

Being as silver is a finite natural resource, and although solar panels do have long lifespans (some models can be effective for up to 30 years), the demand for silver can be profitable for owners of broken or decommissioned solar equipment.

Through unique direct-to-refinery approaches, silver from damaged or otherwise unusable PV cells can be extracted and the value recovered. The value of this silver can off-set disposal or removal costs related to a solar installation. Even if the effects that the solar industry have on silver pricing lessens, panels still provide multiple trace elements that can provide value.

Do you need solar panel recycling and disposal services? Call us today at 480) 482-7050 or (833) 294-3512 for B2B solutions.

We Recycle Solar’s Partner to Join Plant It 2020

Plant It 2020 is a nonprofit foundation that performs worldwide tree-planting, donates fuel-efficient cooking stoves to needy families, and provides forestry, soil, and biochar education.

Through their tree planting events, the cooking stove program, and numerous education programs, Plant It 2020 has been a friend to the environment since 1992 when the foundation was started by John Denver. Many great organizations have joined the call to further the cause, and We Recycle Solar is proud to name one of our partners, EcoMark Solar, as one of them this year.

EcoMark Solar is committed to sustainability, not only in working with us by sending their damaged panels and modules for responsible disposal, but by joining the efforts of Plant It 2020 as well. As their CEO Jake DiRe puts it, “Living in one of the most beautiful places on Earth, we understand our commitment goes further than creating the best renewable energy solutions for our neighbors.” We couldn’t have said it better ourselves!

It is up to us as leaders in the solar industry to ensure that environmental stewardship continues to be a key value along with customer satisfaction.

Although solar panels provide amazing environmental benefits like reducing fossil fuel use, as a whole the solar industry still has a lot of work to do to move towards goals of a reduced carbon footprint. Just as states like New York aim to be 100 percent carbon-free by 2040, the recycling of PV equipment and the potential benefits from these processes are only now becoming a major part of the industry’s innovation. As processes become more refined, more and more solar panels can be reused and less waste produced, driving solar energy into new areas by lowering the cost of equipment.

Hat’s off to the EcoMark Solar team for this year’s participation in Plant It 2020.

Can You Recycle Silicon?

Can you really recycle silicon from Solar Panels? Here’s what the experts say

Silicon: What Are We Recycling

When describing the recycling process for silicon as an elemental component of photovoltaic cells, let’s first understand what silicon is (and isn’t).

Silicon is a metalloid, with the properties of both metals and non-metals. Its greatest quality is probably its ability to conduct electricity, especially at high temperatures. Silicon’s potential as a semiconductor makes the element a familiar component in computer chips and solar panels.

What silicon isn’t though, is silicone.

Silicone is a polymer made of elements, usually silicon, carbon, hydrogen and oxygen. Instead of being a semiconductor, silicone is an electric insulator. As an insulator, silicone can also be found in computers, but to protect parts from electric currents instead of passing them. Generally liquid or a flexible plastic-like solid, silicone is used in medical implants, contact lenses, bandages, personal care items and much more.

While silicone can be recycled, it is not often included in the list of items that municipalities will pick up. Neither is silicon as it is used in solar panels, but environmentally compliant solar recyclers can handle the element at utility-scale levels.

Silicon Recycling Processes for Solar Panels

As a layer of semiconductors within the middle of a solar cell, silicon aids in the absorption of solar energy. This absorbed energy is sent through a circuit and is eventually captured as electrical current.

Silicon can be found in various types of photovoltaic cells, including monocrystalline, polycrystalline, amorphous silicon, and thin-film cells, making it a component in most of today’s solar panels.

Through a comprehensive process of demanufacturing, parts harvesting, recovery, and recycling, silicon can be effectively recycled from solar cells.

If You Can Recycle Silicon, Then What Does It Become?

Silicon is not often found free in nature – it is usually bound with other elements and mined both as sand or vein deposits. This means that to get the silicon used in solar panels and computer chips, the found minerals need to be processed for the extraction of silicon.

Since silicon is not found by itself, recycling solar panels is a great way to retain the mined element for new or refurbished photovoltaic cells. Recycled silicon has also been tested in lithium-ion batteries and could help the batteries store more energy, giving another use for this rarely-alone element.