This article provides an in-depth analysis of the costs associated with solar panels, including manufacturing expenses, marketing and distribution efforts, regulatory compliance, and market dynamics.
Dramatic falls in the cost of energy from solar PV have been driven by the increasing cost competitiveness of the PV module itself, with crystalline silicon (c-Si) PV the dominant technology. In the last decade, the installed capacity of PV modules has grown by an order of magnitude.
The all-world distribution range of module costs in 2025 is 0.10–0.18 $/W (10th–90th percentile). The enormous downward pricing pressure on PV modules will likely result in the most competitive manufacturers' cost models represented at the lower end of this distributions, such as the lower 10th percentile values shaded in the figure.
Sources: Solarbuzz, 2011; Photovoltaik, 2012 and Luo, 2011. (emerging economy manufacturers) and USD 2.21/W (high eficiency c-Si modules), while thin-film PV modules cost USD 1.27/W. In the United States, the price range for monocrystalline silicon PV modules was between USD 1.74/W and USD 2.53/W, with thin-film PV modules costing USD 1.19/W.
The capital cost of a PV system is composed of the PV module cost and the Balance of system (BOS) cost. The PV module is the interconnected array of PV cells and its cost is determined by raw material costs, notably silicon prices, cell processing/manufacturing and module assembly costs.
As discussed above, photovoltaic components, especially photovoltaic modules, are required to have. At present, these requirements are best met by crystalline silicon modules. These modules currently have an efficiency of 16–22%. The trend of increasing the efficiency of mass-produced PV modules is demonstrated in Figure 7.
Utility PV systems were benchmarked to have an LCOE of approximately 5 cents/kWh in 2020 (Feldman, Ramasamy et al. 2021). To achieve the 2030 SunShot goal, the lifetime economics of PV systems must be improved across multiple dimensions.