Monocrystalline silicon is also used for high-performance
photovoltaic (PV) devices. Since there are less stringent demands on structural imperfections compared to microelectronics applications, lower-quality solar-grade silicon (Sog-Si) is often used for solar cells. Despite this, the monocrystalline-silicon photovoltaic industry has benefitted greatly from the development of faster mono-Si production methods for the electronics industry.
Market share In the past, monocrystalline solar panels have historically taken up a significantly smaller market share of PV solar manufacturing globally compared to polysilicon technologies due to the latter's lower cost and ease of manufacture. However monocrystalline market share has been growing rapidly since at least 2018. In recent years the price gap between the two technologies has narrowed, both in an absolute sense (panel cost per watt), and in
LCoE. This has contributed in monocrystalline becoming the dominant technology, with some studies even showing faster payback periods for monocrystalline despite higher upfront cost. This is especially true if space is considered, since the higher efficiency panels can either use less land or roof-space, or produce more energy in the same area.
Efficiency With a recorded single-junction cell lab efficiency of 26.7%, monocrystalline silicon has the highest confirmed conversion efficiency out of all commercial PV technologies, ahead of poly-Si (22.3%) and established
thin-film technologies, such as
CIGS cells (21.7%),
CdTe cells (21.0%), and
a-Si cells (10.2%).
Solar module efficiencies for mono-Si—which are always lower than those of their corresponding cells—finally crossed the 20% mark for in 2012 and hit 24.4% in 2016. The high efficiency is largely attributable to the lack of recombination sites in the single crystal and better absorption of photons due to its black color, as compared to the characteristic blue hue of poly-silicon. Since they are more expensive than their polycrystalline counterparts, mono-Si cells are useful for applications where the main considerations are limitations on weight or available area.
Manufacturing Besides the low production rate, there are also concerns over wasted material in the manufacturing process. Creating space-efficient
solar panels requires cutting the circular wafers (a product of the cylindrical ingots formed through the Czochralski process) into octagonal cells that can be packed closely together. The leftover material is not used to create PV cells and is either discarded or recycled by going back to ingot production for melting. Furthermore, even though mono-Si cells can absorb the majority of photons within 20 μm of the incident surface, limitations on the ingot sawing process mean commercial wafer thickness are generally around 200 μm. However, advances in technology are expected to reduce wafer thicknesses to 140 μm by 2026. Other manufacturing methods are being researched, such as direct wafer
epitaxial growth, which involves growing gaseous layers on reusable silicon substrates. Newer processes may allow growth of square crystals that can then be processed into thinner wafers without compromising quality or efficiency, thereby eliminating the waste from traditional ingot sawing and cutting methods. == Comparison with other forms of silicon ==