Overview of the Current State of Flexible Solar Panels and Photovoltaic Materials
<p>Different types of solar photovoltaic technology.</p> "> Figure 2
<p>Areas of the solar radiation spectrum which are absorbed in the layers of an amorphous silicon (a-Si:H) and microcrystalline silicon (μc-Si:H) doped hydrogen cell [<a href="#B135-materials-16-05839" class="html-bibr">135</a>,<a href="#B138-materials-16-05839" class="html-bibr">138</a>].</p> ">
Abstract
:1. Introduction
2. Current State, Market Shares, and Future Outlook
3. Classification of Solar Panel Types
- (1)
- Thin-film solar panels consist of stretched films that can be easily installed in any convenient place. They are not afraid of dust and can work even in adverse conditions. In cloudy weather, their effectiveness is reduced by 20%. They are inexpensive, but require a large area for installation.
- (2)
- Monocrystalline batteries are made from a large number of individual cells, which are filled with silicone. Thanks to their waterproofing, they are effectively used in shipping. Monocrystalline batteries are relatively light in weight and compact in size. They are distinguished by flexibility, light weight, compactness, reliability, and durability. They are easy to install and dependent on direct sunlight. In this case, even light cloud cover can lead to a cessation of energy production.
- (3)
- Polycrystalline solar panels contain cells composed of crystals pointed in different directions. This makes it possible to capture diffused light and be less dependent on direct illumination. They are successfully used to illuminate houses, office buildings, and even streets.
- Mechanical: geometric parameters; weight; size; number of cells; type and width of connectors.
- Temperature: one of the key factors is the change in efficiency when the temperature rises (in extreme conditions) by a certain unit of magnitude (usually 1 degree).
- Electrical or current-voltage: (CVC) power; open-circuit voltage; rate of change in current strength at maximum load; efficiency of individual cells and the panel as a whole.
- Functional: ease of use; performance; maintenance.
- High quality: service life; degree of degradation of cells; efficiency; versatility; environmental friendliness.
- PERC (Passivated Emitter Rear Cell): dielectric layer on the reverse side of the cell.
- Bifacial: bilateral.
- Multi busbar: multiline.
- Split panels: half.
- Dual glass: frameless, with double glass.
- Shingled cells: inseparable elements.
- IBC (interdigitated back contact cells): interlaced contacts at the back of the cell.
- HJT (heterojunction cells): heterostructural cells.
- (1)
- Single-crystal: 15–16% (up to 24% on prototypes).
- (2)
- Polycrystalline: 12–13% (up to 16% on prototypes).
- (3)
- Amorphous: 8–10% (up to 14% on prototypes).
4. Classification of Photovoltaic Materials and Manufacture Technologies
- (1)
- SILICON-BASED
- Monocrystalline (semi-flexible modifications)
- Polycrystalline
- Amorphous
- CZTS—sulfide of copper, zinc, tin, and derivatives of CZTSe and CZTSSe
- DSSC, DSC, DISC: dye-sensitized solar cell (“Grätzel cell”)
- (2)
- TELLURIUM-CADMIUM BASED
- (3)
- BASED ON INDIUM-COPPER-GALLIUM SELENIDE
- (4)
- BASED ON GALLIUM ARSENIDE
- (5)
- COMBINED AND MULTILAYER
- (6)
- POLYMERIC
- (7)
- ORGANIC
- Quantum Dot Solar Cells (QDSC)
- Tunable bandgap: quantum dots’ size can be engineered to control their bandgap, allowing for absorption of a wider range of solar wavelengths and improved light absorption.
- Multiple exciton generation (MEG): quantum dots can exhibit MEG, a phenomenon where multiple electron–hole pairs (excitons) are generated from a single photon. This increases the photocurrent and efficiency.
- Reduced thermalization losses: quantum dots can reduce thermalization losses by rapidly transferring excitons to interfaces before they lose energy as heat.
- Compatibility: quantum dots can be integrated into various solar cell architectures, including thin films and traditional silicon-based devices.
- Quantum Well Solar Cells (QWSC)
- Enhanced carrier separation: quantum wells promote efficient charge separation due to the confined energy levels, reducing recombination losses.
- Improved current generation: quantum wells facilitate the generation of multiple electron–hole pairs, similar to quantum dots, increasing the photocurrent.
- Wide wavelength coverage: quantum wells can be designed to absorb specific wavelengths of light, enhancing the effective use of the solar spectrum.
- Quantum Superlattice Solar Cells
- Combined benefits: quantum superlattices leverage the advantages of quantum wells and quantum dots to achieve enhanced light absorption, charge carrier separation, and efficient collection.
- Wavelength control: by engineering the thickness and composition of layers, the absorption can be fine-tuned for optimal solar spectrum coverage.
- Overall Advantages of Quantum-Based Solar Cells
- Enhanced efficiency: quantum confinement effects and the ability to generate multiple excitons from a single photon contribute to higher conversion efficiencies.
- Tailored absorption: quantum-based solar cells can be designed to efficiently absorb specific portions of the solar spectrum.
- Reduced thermalization losses: the rapid separation of excitons in quantum-based structures reduces thermalization losses.
- Potential for low-cost fabrication: quantum dots and wells can be integrated into existing solar cell technologies, potentially allowing for low-cost fabrication methods.
- Versatility: quantum-based structures can be combined with other advanced materials and technologies to further improve solar cell performance.
- While these quantum-based solar cell technologies offer intriguing advantages, they also present challenges related to material synthesis, stability, and scalability. Ongoing research aims to address these challenges and unlock the full potential of quantum-based approaches for more efficient and sustainable solar energy conversion.
5. Perovskite and Kesterite Solar Cells
- Abundance of elements: kesterite solar cells are advantageous because they use earth-abundant and non-toxic elements, such as copper and zinc, in contrast to some other thin-film technologies that might rely on rarer or more expensive elements.
- Tunable bandgap: the bandgap of kesterite materials can be engineered by adjusting the composition of sulfur and selenium. This tunability allows the solar cells to absorb different portions of the solar spectrum and enhances their potential for efficient energy conversion.
- Multinary composition: kesterite solar cells are part of the family of chalcogenide-based photovoltaic materials, which includes various combinations of elements from Group I and Group II of the periodic table. These multinary compounds offer a degree of flexibility in bandgap engineering.
- Efficiency potential: kesterite solar cells have shown potential to achieve moderate energy conversion efficiencies, with records continuing to improve as research advances.
- Processing techniques: kesterite solar cells can be manufactured using techniques like co-evaporation or solution-based methods. These methods offer possibilities for cost-effective and large-scale production.
- Challenges: despite their promise, kesterite solar cells face challenges related to achieving high efficiency, ensuring material stability, minimizing defects, and addressing issues of grain boundaries and non-radiative recombination.
- Carrier recombination:
- Carrier lifetime:
- Voc bottleneck:
- Effective use of solar spectrum:
- Stability and reliability:
6. Current Advances in the Flexible Solar Panel Industry
- Current strength;
- High efficiency;
- Additional features (models with suction cups, with fastening on a backpack);
- Reliable functioning;
- Efficient work.
- -
- Increased the conversion efficiency of the infrared part of the spectrum, while there were no losses in the absorption coefficient in the visible part;
- -
- Allowed for the minimization of the overall thickness of the film;
- -
- Reduced the rate of degradation by 20–25%.
- Reliability (the product is protected from mechanical damage, moisture, and high temperatures, many designs are equipped with covers).
- Impact resistance (the panel remains intact when dropped from a height of many meters. The elements are relatively insensitive to overheating and are suitable for creating installations of any power).
- Thin and pliable structure (sufficiently large bending radius allows installation of buildings with a non-linear roof shape, dismantling of surfaces of any configuration, and versatility, i.e., the ability to fold and roll into a roll).
- Lightness (selenium, silicon, etc., are used to create semiconductors. Polymer sputtering and aluminum conductors lighten the panel by reducing the load on the supporting structures of structures).
- Environmental friendliness (materials can be recycled and reused. The source of energy is environmentally friendly, silent, and renewable. The daily influx of sunlight to the Earth is 120 thousand terawatts, which exceeds the need of earthly civilization for energy more than 20 thousand times).
- Availability and ease of operation (easy to install, simple equipment maintenance, do not require highly qualified personnel).
- Profitability (high overall energy production as power efficiency is maintained in cloudy weather), and a high level of optical absorption of photons increases the efficiency of batteries, simplifies production technology, reduces energy payback time for modules, has a favorable cost, and allows for energy supply to a country (providing autonomous control of heating, ventilation, and lighting, with an energy efficiency index from 14% to 30% and excellent maintainability as it is enough to cut out the damaged area, replace it with a new one and reconnect it to the circuit).
- Performance characteristics (wide range of applications, significant working life due to high ability to capture various spectra of solar radiation, high-quality operation in low light conditions, performance drop with significant temperature fluctuations is not critical, and a snug fit to the surface guarantees resistance to wind loads). Versatility and simplicity, i.e., the ability to increase power by adding new modules.
- Aesthetics. Modules can become part of the design idea, be part of the architectural decoration of houses, and play the role of home decoration.
- -
- Manufactured using silicon-free technology;
- -
- Based on amorphous silicon;
- -
- Based on nanoheteroepitaxial structures with quantum dots.
- Primary sector: mining and collection of minerals (in particular: copper, silicon, tellurium, cadmium, etc.)
- Secondary sector: manufacturing industry (aerospace, construction, etc.)
- Tertiary sector: the service sector in all sectors of the economy.
- Quaternary sector: intellectual services (technological progress).
7. Key Findings and Future Implications
- Solar panel diversity: the review paper revealed a diverse landscape of solar panel technologies, including monocrystalline, polycrystalline, thin-film, and emerging third-generation solar cells. Each technology exhibited distinct advantages and limitations, impacting factors such as efficiency, cost, and manufacturing complexity.
- Material influence on efficiency: the study underscored how the choice of photovoltaic material profoundly influences solar panel efficiency. Monocrystalline silicon exhibited high conversion efficiencies due to its uniform crystal structure, while thin-film materials like cadmium telluride and copper indium gallium selenide demonstrated cost advantages but comparatively lower efficiencies.
- Bandgap engineering: photovoltaic materials with tunable bandgaps, such as perovskites and tandem solar cells, showcased the potential to optimize energy absorption across the solar spectrum. The manipulation of bandgaps allowed for enhanced performance in various lighting conditions.
- Material stability and durability: the review highlighted the importance of material stability in solar panel longevity. Emerging materials like perovskites demonstrated impressive efficiency gains but often faced challenges related to degradation under environmental stressors. Extensive research focused on enhancing stability to ensure long-term performance.
- Defect management and passivation: effective passivation techniques were identified as essential for minimizing defects at material surfaces and interfaces. Silicon-based solar cells employed techniques like hydrogenation, while emerging materials leveraged tunnel oxide passivated contacts (TOPCon) to reduce recombination losses and improve charge carrier extraction.
- Multijunction and tandem solar cells: multijunction and tandem solar cells were identified as effective strategies to improve overall efficiency by stacking different materials with complementary absorption spectra. These configurations demonstrated the potential to exceed the efficiency limits of single-junction solar cells.
- Cost reduction and scalability: the study emphasized the significance of advancing photovoltaic materials with abundant and non-toxic constituents, fostering cost-effective production and widespread scalability. The integration of advanced manufacturing techniques like roll-to-roll processing showcased potential for reducing material and production costs.
- Environmental impact: the environmental impact of photovoltaic materials was a central concern. The review paper discussed the importance of sustainable sourcing, recycling methods, and reducing toxic components to align with broader environmental goals.
- Advancements in material stability and durability: As the adoption of flexible solar panels continues to expand, the need for enhanced durability and long-term stability becomes paramount. Future research efforts should concentrate on developing materials that can withstand a variety of environmental stressors, such as UV radiation, temperature fluctuations, and moisture exposure. By engineering materials with improved stability, solar panels can maintain their performance over extended lifetimes, leading to greater economic viability and reduced maintenance requirements.
- Integration into urban infrastructure: The concept of solar-integrated urban landscapes holds immense promise for decentralized energy generation. Future research should focus on optimizing flexible solar panels for integration into existing and new architectural structures, facades, and even wearable devices. This integration not only presents opportunities to generate energy from underutilized surfaces but also contributes to sustainable urban planning, making clean energy generation a ubiquitous part of daily life.
- Innovations in manufacturing techniques: achieving cost-effective production methods without compromising efficiency is a persistent challenge in the solar industry. Researchers and engineers should explore novel manufacturing techniques, such as roll-to-roll printing, additive manufacturing, and continuous deposition processes, to enable large-scale production of flexible solar panels. By streamlining production processes, the cost barriers associated with these advanced materials can be reduced, making them more accessible for widespread deployment.
- Environmental impact and circular economy: as the world embraces renewable energy, considerations of the environmental impact of solar panel materials, production, and end-of-life management become increasingly relevant. Future research should delve into the development of sustainable material alternatives and explore recycling methods to ensure a circular economy approach. Addressing the environmental aspects of flexible solar panel technology will be instrumental in minimizing its ecological footprint and aligning with broader sustainability goals.
- Multi-functionality and energy storage integration: The integration of energy storage capabilities within flexible solar panels holds promise for a more seamless energy supply, enabling power generation even when sunlight is unavailable. Future research should explore ways to incorporate energy storage technologies, such as flexible batteries or supercapacitors, directly into the panel structure. This integration would enhance the versatility and reliability of solar panels, making them even more attractive for diverse applications.
- Global accessibility and energy equity: to truly harness the potential of flexible solar panels, research should not only focus on technological advancements but also on making these technologies accessible to underserved communities and remote regions. Future efforts should prioritize the development of low-cost, easy-to-install solar solutions that can provide clean energy to areas with limited infrastructure. Bridging the energy gap through innovative solar technologies has the potential to empower communities and contribute to global energy equity.
- In conclusion, the future of flexible solar panels and photovoltaic materials is teeming with possibilities and challenges that require multidisciplinary collaboration and innovative thinking. By addressing issues related to durability, scalability, cost, integration, sustainability, and accessibility, researchers and industry stakeholders can drive the transformation of solar energy from a niche technology to a pervasive and integral part of our sustainable energy landscape.
8. Conclusions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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---|---|---|---|---|---|---|
ss/ITO/CdS/CdTc//Cu/Au | 0.191 | 790 | 20.10 | 69.4 | 11.0 | IEC |
ss/SnO2/CdS/CdTe | 0.824 | 840 | 20.66 | 74.0 | 12.8 | NREL |
ss/SnO2/CdS/CdTe | 0.313 | 783 | 24.98 | 62.7 | 12.3 | Photon Energy |
ss/SnO2/CdS/CdTe | 0.3 | 788 | 26.18 | 61.4 | 12.7 | Photon Energy |
ss/SnO2/CdS/HgTeGa | 1.022 | 736 | 21.9 | 65.7 | 10.6 | SMU |
MgF2/ss/SnO2/CdS//CdTe/C/Ag | 1.047 | 843 | 25.09 | 74.5 | 15.8 | Univ. South Florida |
ss/SnO2/CdS/CdTe/Ni | 1.068 | 767 | 20.93 | 69.6 | 11.2 | AMETEX |
ss/SnO2/CdS/CdTe | 0.08 | 745 | 22.1 | 66.0 | 10.9 | Georgia Tech. |
MgF2/ss/SnO2/CdS/CdTe | 1.115 | 828 | 20.9 | 74.6 | 12.9 | Solar Cells Inc. |
Ss/SnO2/CdS/CdTe/Cu/Au | 0.114 | 815 | 17.61 | 72.8 | 10.4 | Univ. Toledo |
CdTe | 807 | 12.7 | BP Solar |
Full Name | Designation | Description |
---|---|---|
Efficiency | η | Efficiency is a crucial parameter and represents the ability of a solar cell to convert sunlight into electricity. It is the ratio of the electrical power output to the incident solar power. Higher efficiency means more effective energy conversion. |
Open-Circuit Voltage | Voc | The voltage across the terminals of a solar cell when no external load is connected. It indicates the maximum voltage the solar cell can generate under illumination, and it is a key factor in determining the cell’s efficiency. |
Short-Circuit Current | Isc | The current through the solar cell when its terminals are short-circuited. It represents the maximum current the cell can produce under full sunlight exposure. |
Fill Factor | FF | The ratio of the maximum power output of the solar cell to the product of Voc and Isc. It gives insight into how effectively the solar cell utilizes its maximum power point. |
Maximum Power Point | Pmax | This is the point on the current–voltage curve of the solar cell where the product of current and voltage is at its highest value. Pmax represents the maximum electrical power output the solar cell can generate. |
Voltage at Maximum Power | Vmpp | The voltage at which the solar cell operates to produce the maximum power output. |
Current at Maximum Power | Impp | The current at which the solar cell operates to produce the maximum power output. |
Shunt Resistance | Rsh | Represents the resistance in parallel with the solar cell, which allows some current to bypass the cell. Higher Rsh values indicate lower leakage current and improved efficiency. |
Series Resistance | Rs | Represents the resistance in series with the solar cell, reducing the voltage across the terminals. Lower Rs values lead to better performance. |
Temperature Coefficient | - | Solar cell performance is influenced by temperature changes. The temperature coefficient describes how much the efficiency or other parameters change with temperature variations. |
Spectral Response | - | Solar cells respond differently to different wavelengths of light. The spectral response curve shows how efficiently a solar cell converts light of various wavelengths into electricity. |
Bandgap | Eg | The energy difference between the valence and conduction bands of the material. It determines the range of wavelengths that a solar cell can absorb and convert into electricity. |
External Quantum Efficiency | EQE | Quantifies the efficiency with which a solar cell converts photons of different wavelengths into electrons. It provides insight into the solar cell’s performance across the solar spectrum. |
Degradation and Stability | - | Over time, solar cells can experience performance degradation due to environmental factors, such as exposure to sunlight, temperature, and humidity. Understanding the stability and degradation mechanisms is crucial for long-term performance. |
Material Structure | S, cm2 | Uoc, mB | Jsc, mA/cm2 | FF, % | Eff-cy | Date | Company |
---|---|---|---|---|---|---|---|
c-Si | 4.00 | 709 | 40.9 | 82.7 | 24.0 | 9/94 | UNSW |
c-Si | 45.7 | 694 | 39.4 | 78.1 | 21.6 | 4/94 | UNSW |
c-Si | 22.1 | 702 | 41.6 | 80.3 | 23.4 | 5/96 | UNSW |
mc-Si | 1.00 | 636 | 36.5 | 80.4 | 18.6 | 12/91 | Georgia Tech. |
mc-Si | 100 | 610 | 36.4 | 77.7 | 17.2 | 3/93 | Sharp |
tf-Si | 240 | 582 | 27.4 | 76.5 | 12.2 | 3/95 | Astro Power |
tf-Si | 4.04 | 699 | 379 | 81.1 | 21.1 | 8/95 | UNSW |
a-Si:H | 1.06 | 864 | 16.66 | 71.7 | 103 | 10/90 | Chronar |
a-Si:H | 0.99 | 886 | 17.46 | 70.4 | 10.9 | 9/89 | Glass tech. |
a-Si:H | 1.0 | 887 | 19.4 | 74.1 | 12.7 | 4/92 | Sanyo |
a-Si:H | 1.08 | 879 | 18.8 | 70.1 | 1 1.5 | 4/87 | Solarex |
ITO/c-Si/a-Si | 1.0 | 644 | 39.4 | 79.0 | 20.0 | 9/94 | Sanyo |
a-Si:H | 1.0 | 891 | 19.13 | 70.0 | 12.0 | 9/94 | Solarex |
a-Si:H | 1.0 | 923 | 18.4 | 72.5 | 12.3 | 9/94 | Fuji-Elect. |
a-Si/a-Si/a-SiGe | 2320 | 7.3 | 73.0 | 12.4 | 9/94 | Sumitomo | |
a-Si:H | 1.0 | 887 | 19.4 | 74.1 | 12.7 | 9/94 | Sanyo |
a-C/a-SiML/a-SiC/a-Si | 1.0 | 936 | 19.6 | 71.8 | 13.2 | 9/94 | MutsuiToatsu |
a-C/a-Si/a-SiC/a-Si | 1.0 | 909 | 19.8 | 73.3 | 13.2 | 9/94 | MutsuiToatsu |
ITO/a-Si:H/a-SiGe:H | 0.28 | 1621 | 1 1.72 | 65.8 | 12.5 | 1/92 | USSC/Cannon |
a-Si/k-Si | 0.03 | 1480 | 16.2 | 63.0 | 15.0 | 9/94 | Osaka Univ. |
a-SiC/a-Si | 1.0 | 1750 | 8.16 | 71.2 | 10.2 | 9/94 | Solarex |
a-Si/a-Si | 1.0 | 1 800 | 9.03 | 74. I | 12.0 | 9/94 | Fuji |
a-SiC/a-SiGe/a-SiGe | 1.0 | 2290 | 7.9 | 68.5 | 12.4 | 9/94 | Sharp |
a-Si/a-Si/a-siGe | 1.0 | 2550 | 7.66 | 70.1 | 13.7 | 9/94 | ECD/Sovonics |
p-a-SiO:H/a-Si:H/n-a-Si:H | 1.0 | 899 | 18.8 | 74.0 | 12.5 | 9/94 | Fuji-Elect. |
ITO/a-Si:H/Si:H/a-siGe | 0.27 | 2541 | 6.96 | 70 | 12.4 | 2/88 | ECD |
a-Si:H/a-Si:H/a-SiGc:H | 1.00 | 2289 | 7.9 | 68.5 | 12.4 | 12/92 | Sharp |
a-Si/CuInSe2 | 871 432 | 16.4 17.4 | 72.0 68.0 | 10.3 5.3 | 9/94 | ARCO | |
a-Si/mc-Si | 917 575 | 10.4 30.2 | 76.0 79.2 | 7.25 13.75 | 9/94 | Osaka Univ. |
PVM Types | MSW-180 | Pramac Luce MCPH P7LM | BYD | Stion SN 130 |
---|---|---|---|---|
Technology | Mono-Si, bilateral | α-Si/µ-Si | Multi-Si | CIGS |
Voltage Temperature Coefficient, B/°C | −0.152 | −0.004 | −0.0034 | - |
Current Temperature Coefficient, AKC | 0.00044 | 0.0006 | 0.00045 | - |
Temperature Coefficient of Power, Bt/°C | −0.005 | −0.0025 | −0.0047 | −0.0045 |
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Dallaev, R.; Pisarenko, T.; Papež, N.; Holcman, V. Overview of the Current State of Flexible Solar Panels and Photovoltaic Materials. Materials 2023, 16, 5839. https://doi.org/10.3390/ma16175839
Dallaev R, Pisarenko T, Papež N, Holcman V. Overview of the Current State of Flexible Solar Panels and Photovoltaic Materials. Materials. 2023; 16(17):5839. https://doi.org/10.3390/ma16175839
Chicago/Turabian StyleDallaev, Rashid, Tatiana Pisarenko, Nikola Papež, and Vladimír Holcman. 2023. "Overview of the Current State of Flexible Solar Panels and Photovoltaic Materials" Materials 16, no. 17: 5839. https://doi.org/10.3390/ma16175839
APA StyleDallaev, R., Pisarenko, T., Papež, N., & Holcman, V. (2023). Overview of the Current State of Flexible Solar Panels and Photovoltaic Materials. Materials, 16(17), 5839. https://doi.org/10.3390/ma16175839