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When you think of solar panel efficiency, you’re most likely thinking about how much sunlight a given panel turns into electricity.
While this is certainly an important consideration for customers choosing a new photovoltaic system, it’s far from the only aspect of “efficiency” that goes into a high-performing PV system.

In this blog, we’ll look at a few different variables that go into making an efficient solar installation. We’ll start with how well different panels and panel types turn sunlight into electricity, but also looks at other factors, like planning, installation, and maintenance.

But let’s get started where the rubber hits the road: the solar panels themselves.


When discussing solar cell efficiency, we mean the amount of sunlight that hits a solar panel and is converted into electricity. A solar panel is only as efficient as its weakest link: the cell. Cells, made of silicon, absorb photons and convert them to electricity.

Not all photons are absorbed, however: Depending on the wavelength of light hitting the cell, some photons are reflected and others pass through while others are absorbed and produce heat. What’s left are able to separate electrons from the silicon, thus producing energy.

The age-old struggle of solar cell design is designing cells to maximize photon receptivity by improving the following factors:

  • Material. The type of material (monocrystalline, polycrystalline, etc) plays a critical role in overall panel efficiency. The most efficient cells incorporate the purest silicon. Impurities can lead to recombination, which results from electrons recombining when they encounter an impurity or defect in the cell’s crystalline structure.
  • Wiring and busing. Cells with multiple busbars and passivation help efficiently capture and transfer electricity.
  • Reflection. Minimizing the amount of light reflected off the cell is also an important factor affecting efficiency. Thus cells treated with anti-reflective coatings (the blue or black you see on a solar panel) perform best.


Taking it up one level, solar panel efficiency is measured under strictly controlled test conditions called standard test conditions (STC). STC is established by exposing a panel to a constant light source and temperature, measuring the current and voltage produced for different load resistances. STC accommodates a cell temperature of 25°C, 1000W/m2 irradiance, and air mass of 1.5.

Efficiency is determined by the panel’s maximum power rating at STC divided by the panel’s area in meters:

Efficiency = ([Pmax / Area] / 1000) x 100%

Under STC, a one-meter square, 15% efficient solar panel would produce 150 watts.

Average panel efficiency in the real world is a whole different story, though. Solar panel efficiency is measured at standard factory testing conditions, so real-world efficiency may vary from what’s advertised. That means there’s a whole lot more that goes into the efficiency cocktail, such as:

  • Wiring and busing used to capture and transfer electricity
  • Reflection
  • Panel installation and placement
  • The region’s potential solar output
  • Solar panel age
  • Weather
  • Shade
  • Color of the roof and protective back sheeting


Four major solar panel types are available to the consumer market today, each with its own advantages, disadvantages, and cell configurations:

  • Monocrystalline cells are one solid silicon crystal. Mono cells provide more space for electrons to flow, resulting in a smaller, more efficient panel. The downside is they tend to be more expensive.
  • Polycrystalline cells are constructed of many individual shards of silicon melted together. While not as efficient as mono cells, poly cells have a lower price point.
  • Thin-film cells are thin enough to be flexible, making them ideal for small-scale or portable applications, but are not efficient enough for use in large-scale installations.

Cells can be further configured to maximize efficiency. We’ll go through the various solar cell types and efficiencies below, but first, a brief description of some acronyms:

  • PERC (Passivated emitter and rear cells) reflect light back into the cell, thereby reducing the tendency of electrons to recombine. As a plus, they also absorb greater wavelengths of light, and have a high efficiency rating compared to traditional modules.
  • MBB (Multiple busbars): Reduces current loss by shortening the length a current must flow across a cell wafer.
  • IBC (Interdigitated back contact): Energy conversion occurs on the back of the cell, allowing the entire front of the cell to absorb sunlight, offering higher efficiency, yield, and reliability.


It should be noted there’s a difference between setting max efficiency records and maintaining consistent performance in the real world. As stated above, a highly efficient panel may look good in a lab, but could lack the performance needed to operate consistently in practical applications.

If your chief goal is to maximize electrical output of your system, technology like smart modules and module-level power electronics have to be considered along with panel efficiency. Maximizing this output by making a PV system as efficient as possible also has the potential benefit of revenue from net energy metering.

Unlock output potential with proper planning

Regardless of which solar panel is chosen, detailed planning and resources should go into determining the best installation and placement possible.

A good first step is making sure the sun shines on the panels by avoiding shaded areas and installing panels at the best possible angle.

Cleaning and maintenance

The work isn’t done after a system is installed. Just like maintenance on a car, keeping a solar panel system clean and in good repair is essential to peak performance. Dust buildup over the course of a year can reduce output up to 4.4%, so if your system is in a particularly dry area where rain doesn’t regularly wash your panels naturally, manually cleaning them is a good idea.

Even if you get regular rainfall, all panels should be regularly checked for pollen, bird droppings, leaves, ash, and other pollutants and residue. Wash panels gently with a hose first. If they’re still dirty, softly squeegee with mild soapy water to effect.


After looking at all the factors, it’s clear that solar panel efficiency is an important part of designing an efficient PV system. Just like fuel efficiency in a car, an efficient solar panel means less raw materials, a smaller footprint, and less required space for proper energy output.

For some applications, highly efficient solar panels are the only option. If space is limited, solar panel efficiency is vitally important to ensure enough energy can be harnessed. This may be the case on smaller residential homes where roof area or bare ground is at a premium.

When looking for the perfect photovoltaic system, however, efficiency isn’t everything. After choosing a panel, proper installation and placement of the entire PV system is critical to coaxing the most out of those panels. Improper installation—unsuitable back sheeting, inadequate ancillary equipment, etc.—and placement can significantly impede solar panel performance.

A professional installers have to consider all aspects of a project (cost, value, warranty, homeowner needs, and aesthetics) to determine what type of panel works best for any given installation.


Trilect Solar is a division of Trilect Services, New Zealand’s master electrician since 1997.

We are members of the Sustainable Energy Association of New Zealand (SEANZ) which offers additional peace of mind to our customers.

Trilect Electrical Services is a large electrical service company that is a member of the Master Electricians & Mastercraft network with 40 employees and a 20+ years history of customer satisfaction.

We do not use sub-contractors. All of the installations will be carried out by our experienced team.

Trilect Solar offers a customized energy plan that works for your home/ business.

Get started now by booking a free on-site consultation.

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Or call us on 0800 850 888