Environmental Impact of PV Power Systems
Abstract
:1. Introduction
Literature Review
2. Materials and Methods
3. Results and Discussion
3.1. Land Use
- Land use conflicts: ground-mounted PV plants may compete with other land uses, such as agriculture, forestry, conservation, or urban development. This can lead to trade-offs between different environmental, economic, and social goals, such as food security, biodiversity protection, or local employment. Therefore, careful site selection and land use planning are essential to avoid or minimize negative impacts and maximize positive synergies.
- Environmental impacts: Both rooftop and ground-mounted PV systems can have direct or indirect impacts on the environment, such as habitat loss or fragmentation, soil erosion or pollution, water use and pollution, visual impacts, or glare. Therefore, environmental impact assessments and mitigation measures are required to ensure compliance with relevant standards and regulations and improve environmental sustainability.
3.2. Greenhouse Gas Emissions
- The largest share of emissions comes from the manufacturing phase of the PV system components (80% to 95%), followed by the end-of-life disposal phase (5% to 20%), and negligible amounts of GHGs are emitted during the operation of the PV power plant (0.3% to 1%). For comparison, most GHG emissions from non-renewable energy sources occur during the operation phase of the power plant (about 98%), with the remainder occurring during the construction and decommissioning phases of the power plant. (Author’s estimation).
- GHG emissions for the production of PV power plants decrease over time as PV modules become more efficient, the production of solar cells becomes less energy intensive, and the share of renewable energy in the power grid increases [68].
- The carbon footprint of PV solar systems is estimated in the range (14–130 g CO2-eq/kWh) [58], which is lower than for gas (608 CO2-eq/kWh), oil (742 CO2-eq/kWh), and coal-fired (975 g CO2-eq/kWh) power plants [69]. However, the carbon footprint of PV solar is larger than that of CSP (14–32 CO2-eq/kWh) [2], wind power (8–23 CO2-eq/kWh), geothermal power plants (38 CO2-eq/kWh), nuclear power plants (24–66 CO2-eq/kWh), and hydroelectric power plants (10–13 CO2-eq/kWh) [64].
3.2.1. The Energy Payback Time (EPBT)
- The materials used to manufacture the PV system and the technology used
- The efficiency of the solar cells
- The irradiation related to the location of the PV solar system
3.2.2. Other Pollutant Emissions
3.3. Hazardous Materials
3.4. Water Use
3.5. The Impact on Biodiversity
3.6. Noise
3.7. End of Life
- Removal of the frame and junction box;
- Removing the encapsulant from the laminated structure;
- Separation of the glass and silicon wafer by thermal, mechanical, or chemical processes;
- Separation and purification of silicon cells and special metals (e.g., silver, tin, lead, copper, Al) by chemical and electrical processes.
3.7.1. Land Use
3.7.2. Water Use
3.7.3. Gas Emissions
3.7.4. Solid Wastes
3.7.5. Hazardous Materials
3.7.6. Noise Pollution
3.7.7. Challenges and Barriers in PV Recycling
- The lack of a standardized and efficient collection system for PV modules. There is no global regulation or incentive for the owners of PV modules to return them to the recyclers. This leads to a low recycling rate and a high risk of illegal landfilling of PV modules.
- Lack of recycling facilities and technologies.
- Lack of market demand for recycled or reused PV modules.
- Lack of awareness and education among stakeholders and consumers.
- The complexity and diversity of PV module materials and designs. Each material has different properties and requires different recycling methods. This makes it difficult to separate and recover the valuable materials from the PV modules.
- The high cost and low profitability of PV module recycling. The recycling process of PV modules is often labor-intensive, energy-consuming, and technically demanding. The cost of recycling may exceed the value of the recovered materials.
- Develop and harmonize regulations and standards for the EOL treatment of PV modules.
- Establish extended producer responsibility (EPR) systems that hold manufacturers accountable for the EOL management of their products.
- Support research and development of innovative recycling and reuse technologies and methods.
- Promote market development and value creation for recycled or reused PV modules
- Raise public awareness of the benefits and opportunities of EOL management of PV modules.
- Develop better technologies to improve PV panel recycling. Designing for Recycling, for example, is one such technology.
4. Conclusions
- An average area of 4.53 km2/GW is required for the installation of rooftop PV power plants, and 19 km2/GW for large-scale power plants (Table 1 and Table 2). Based on the planned capacities for 2030 and the assumed share of rooftop PV power plants in these capacities, the required area in Europe and worldwide was calculated (Table 3).
- Based on the data on the available area (rooftops and vacant land), it can be concluded that this area is much larger than needed and that there should be no problem reaching the planned PV power plant capacities.
- Possible land use conflicts, e.g., with agriculture and forestry, should be considered.
- In general, emissions range from 12.5 to 126 CO2 eq./kWh, which is far below fossil fuel power plant emissions but higher than emissions from other renewable energy plants
- Most of the CO2 emissions come from the production phase of the PV system components, as this is an energy-intensive process. The energy payback time for Europe is between 1 and 2.5 years (Figure 2).
- Hazardous substances (heavy metals) are also used in the production of PV system components. They can only pose a significant environmental problem if the modules are not recycled at the end of the power plant’s life but are landfilled, and in this way they can significantly pollute the soil and drinking water.
- Water consumption in the life cycle of the PV power plant is not large and does not represent a significant problem; the same applies to noise emissions.
- At the end of the life cycle, recycling can reduce the need for new materials and the associated energy consumption and emissions. This is particularly important given concerns about potential material shortages to achieve decarburization and electrification on a global scale.
- The recycling process requires the use of a certain amount of mechanical, thermal, or electrical energy to separate the components of the module, and that certain chemicals and water must be used, resulting in certain gas emissions
- The forecast for 2050 assumes a recyclable value of 630 GW of modules, which corresponds to a mass of 32.1 million tons of waste.
- The recycling processes for the various PV technologies are not yet fully developed
- After disassembly and extraction, the mass fraction of the various resources in a typical solar module breaks down as follows: Glass 54.7%, aluminum 12.7%, adhesive 10%, silicon 3.1%, and others 19.5%
- The main problems in recycling modules are the removal of ethylene vinyl acetate and the extraction of metals with minimal development of toxic gases and effluents.
- Globally, there are no regulations or incentives for owners of PV modules to return them to recyclers. This results in a low recycling rate and a high risk of illegal disposal of PV modules.
- The big problem is the high cost and low profitability of recycling PV modules
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Company | Solar Panel Model | Power (W) | Hight (m) | Width (m) | Area (m2) | Area (m2/kW) | Weight (kg/kW) |
---|---|---|---|---|---|---|---|
Jinko | Tiger Neo N-type 72HL4 | 575 | 2.278 | 1.134 | 2.58 | 4.49 | 48.7 |
Longi | HI-MO-5 | 550 | 2.256 | 1.133 | 2.56 | 4.65 | 58.7 |
Q Cells | Q.tron G1+ Series | 395 | 1.717 | 1.045 | 1.79 | 4.54 | 50.4 |
JA Solar | 72-cell MBB Half-cell Module | 565 | 2.278 | 1.134 | 2.58 | 4.57 | 55,9 |
AIKO | AIKO-A-MAH72Mb | 615 | 2.278 | 1.134 | 2.58 | 4.20 | 45.9 |
SOLVIS | SV144 E HC9B | 455 | 2.094 | 1.038 | 2.62 | 4.63 | 54.9 |
Project Solar | Evolution Titan 445 | 415 | 1.724 | 1.134 | 1.96 | 4.71 | 48.2 |
RISEN | RSM108-9-415N-440N | 440 | 1.722 | 1.134 | 1.95 | 4.44 | 50.0 |
REC Solar | Alpha Pure-R | 420 | 1.729 | 1.118 | 1.93 | 4.60 | 51.2 |
Sunpower | MAXEON 6 AC | 435 | 1.872 | 1.032 | 1.93 | 4.44 | 50.1 |
Average | 492 | 2.008 | 1.112 | 2.26 | 4.53 | 51.0 |
PV Power Plant Capacity, Year of Start of Work | Required Land Area (km2/GW) | Source |
---|---|---|
PV < 10 kW | 13 | Tawalbeth [3] |
PV < 10 MW | 22 | Tawalbeth [3] |
PV > 100 MW | 25–32 | Tawalbeth [3] |
1 MW | 10–20 | IFC [48] |
Examples of installed utility-scale PV power plants: | ||
PV power plant Kaštelir 2, Croatia, 2 MW, 2021 | 20 | HEP Group [49] |
PV power plant Marići, Croaria, 1 MW, 2021 | 18 | HEP Group [49] |
PV power plant Stankovci, Croatia, 2.5 MW, 2022 | 26 | HEP Group [49] |
PV power plant Obrovac, Croatia, 8.7 MW, 2022 | 13 | HEP Group [49] |
PV power plant Nunez de Balboa, Spain, 2020 | 20 | Iberdrola [50] |
Europe | Global | |||||
---|---|---|---|---|---|---|
Total | Rooftop | Utility Scale | Total | Rooftop | Utility Scale | |
Planned capacity (GW) | 600 | 282 | 318 | 4400 | 1804 | 2596 |
Share (%) | 100% | 47% | 53% | 100% | 41% | 59% |
Area (km2/GW) | 5 | 19 | 5 | 19 | ||
Required area (km2) | 7452 | 1410 | 6042 | 58,344 | 9020 | 49,324 |
Power Plant Type | Required Area (m2/MWh) |
---|---|
PV power plant | 0.3–15 |
Solar concentrated (CSP) | 7.8–19 |
Coal-fired power plants | 0.2–5.1 |
Wind turbine power plants | 0.3–1.3 |
Nuclear power plants | 0.1–1.0 |
Natural gas power plants | 0.1–1.0 |
Hydropower plants | 3.3–16.9 |
Power plants on oil derivatives | 0.1–0.6 |
Biomass power plant (from crops) | 450 |
PV Technologies | Life Cycle Excl. Use Stage | Use Stage | Total |
---|---|---|---|
(gCO2 eq/kWh) | (gCO2 eq/kWh) | (gCO2 eq/kWh) | |
Micromorphous silicon | 43.0 | 0.015 | 43.02 |
Polycrystalline silicon | 48.8 | 0.010 | 48.81 |
Monocrystalline silicon | 80.4 | 0.010 | 80.41 |
CdTe | 19.9 | 0.011 | 19.91 |
CIGS | 35.9 | 0.014 | 35.91 |
PV System Part | Min. | Max. | Median |
---|---|---|---|
PV module | 9.13 | 14.4 | 11.6 |
Mounting structure | 1.49 | 7.66 | 1.71 |
Inverter | 0.39 | 1.11 | 0.69 |
Cabling | 0.04 | 0.05 | 0.04 |
Total | 11.1 | 23.3 | 14.0 |
Component/Material | Content (kg/kWp) | Share in Panel (%) | Remark |
---|---|---|---|
Frame—Al | 12.771 | 18 | Al scrap suitable for producing secondary Al |
Poly c-Si chips | 3.101 | 4 | Recovery rate of silicon ~95% |
Silver bar line—Ag | 0.03 | 0.05 | Recovered through electrolysis or precipitation in leaching solution |
Cu Bushbar and tabbing | 0.451 | 2 | Recovery from cable scrap (~97%) |
Top surface—tempered glass | 54.721 | 70 | Glass cullet for glass production |
Back-sheet layer—Polyvinyl fluoride | 17.091 | 1.5 | Energy recovery from incineration process |
Encapsulation layer—EVA | 5 | Energy recovery from incineration process |
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Bošnjaković, M.; Santa, R.; Crnac, Z.; Bošnjaković, T. Environmental Impact of PV Power Systems. Sustainability 2023, 15, 11888. https://doi.org/10.3390/su151511888
Bošnjaković M, Santa R, Crnac Z, Bošnjaković T. Environmental Impact of PV Power Systems. Sustainability. 2023; 15(15):11888. https://doi.org/10.3390/su151511888
Chicago/Turabian StyleBošnjaković, Mladen, Robert Santa, Zoran Crnac, and Tomislav Bošnjaković. 2023. "Environmental Impact of PV Power Systems" Sustainability 15, no. 15: 11888. https://doi.org/10.3390/su151511888
APA StyleBošnjaković, M., Santa, R., Crnac, Z., & Bošnjaković, T. (2023). Environmental Impact of PV Power Systems. Sustainability, 15(15), 11888. https://doi.org/10.3390/su151511888