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Argentina Solar Encapsulation Market Overview, 2030

Published Aug 31, 2025
Length 76 Pages
SKU # BORM20367454

Description

The solar energy sector in Argentina features a wide range of climate types, necessitating encapsulant materials that can adapt to both dry and humid settings. The nation's project development includes the arid, elevated Andean areas, where high levels of solar radiation, substantial UV exposure, and significant temperature fluctuations impose considerable challenges on photovoltaic panels, as well as the moist pampas, where water infiltration, rust, and mold can impact the long-lasting performance of the modules. Traditionally, many initiatives depended on imported encapsulants, mainly the conventional ethylene-vinyl acetate (EVA), which delivered basic adhesion and visual clarity but were not specifically designed to meet Argentina’s varied climate challenges. Over time, there has been a transition in the market towards locally suited materials, such as UV-resistant EVA and polyolefin elastomer (POE) films, which provide enhanced protection against photodegradation, thermal stress, and moisture-related complications. In terms to these material advancements, engineering innovations like improved edge-seal designs have been introduced to safeguard modules from water ingress and environmental pollutants, ensuring long-term performance across different climates. These enhancements are especially vital for large-scale installations in areas with high sunlight exposure, where severe temperature variations can speed up the degradation of encapsulants, as well as for initiatives in humid or coastal regions, where the risks of rust and PID (potential-induced degradation) are heightened. By integrating climate-sensitive films with refined lamination techniques and protective seals, Argentine developers can sustain high energy yields and extend the lifespan of modules across the diverse geographical and climatic solar landscapes of the country. This emphasis on customized encapsulation indicates a larger trend within the Argentine solar industry utilizing local materials, engineering, and design approaches to optimize performance, lower maintenance expenses, and guarantee steady power generation in both extremely dry and moisture-prone areas.

According to the research report, ""Argentina Solar Encapsulation Market Overview, 2030,"" published by Bonafide Research, the Argentina Solar Encapsulation market is anticipated to add to more than USD 30 Million by 2025–30. Argentina's solar sector is witnessing a burgeoning yet gradually increasing demand, primarily influenced by power purchase agreements and rooftop projects in various industries. While large utility-scale initiatives are developing at a slow pace, the adoption of solar energy in commercial and industrial rooftop settings has emerged as a significant factor, offering businesses benefits such as cost efficiency, energy autonomy, and environmental sustainability. This rising interest has led to trends that emphasize localized assembly of solar modules, enabling developers to tailor products for local climatic conditions, minimize transportation costs, and strengthen the supply chain's resilience. Moreover, there is a growing fascination with glass-glass module designs, celebrated for their superior durability, enhanced mechanical strength, and extended lifespans, especially in sites with high sunlight exposure, variable temperatures, or high humidity levels. The supply chain in Argentina integrates imported modules and encapsulating materials with local companies that assemble, tailor, and set up modules for industrial and rooftop usage. This blended strategy optimizes access to cutting-edge materials and technologies while offering the advantages of local customization and customer service. Adherence to compliance and certification is pivotal for fostering market trust, with IRAM and IEC testing benchmarks ensuring safety, performance, and longevity of modules for lenders, insurers, and end users. Such certifications are crucial for power purchase agreements and industrial projects, as financial and insurance entities demand verified proof of product integrity prior to financing. Argentina's solar landscape showcases an alignment between growing demand, localized manufacturing and assembly, and compliance with international and national standards. By capitalizing on these trends, developers and integrators can provide effective, reliable, and long-lasting solar solutions for commercial and industrial rooftops, thereby enhancing investor trust and supporting ongoing growth in renewable energy capacity.

In Argentina's solar energy sector by materials is divided into Ethylene Vinyl Acetate (EVA), Thermoplastic Polyurethane (TPU), Polyvinyl Butyral (PVB), Polydimethylsiloxane (PDMS), Ionomer and Polyolefin, the choice of encapsulants is tailored to fit both local climate traits and specific project needs. Ethylene-vinyl acetate (EVA) is the predominant encapsulant for the majority of installations, especially for large-scale utility projects and industrial rooftops in moderate climate zones like the pampas and central regions. EVA is preferred due to its affordability, reliable performance, clarity of optics, and compatibility with traditional lamination techniques, establishing it as the common option for high-volume module manufacturing. Its established supply chain and dependability also align with the increasing demand spurred by power purchase agreements (PPAs) and the rising adoption of solar energy for commercial use. On the other hand, in higher elevation areas such as the Andean solar fields in northern Argentina, environmental factors are considerably more challenging. These locations face extreme UV radiation, significant temperature variations, and harsh irradiation, which can speed up potential-induced degradation (PID) and the deterioration of encapsulants. To tackle these obstacles, polyolefin elastomer (POE) encapsulants are gaining popularity in high-altitude areas because of their enhanced resistance to heat, moisture entry, and PID. POE films offer improved durability under severe conditions, ensuring sustained energy production and module reliability over many years. The distinction between EVA and POE highlights a thoughtful method to balancing cost, efficiency, and adaptation to environmental challenges EVA acts as an economical, high-volume option in moderate climates, whereas POE is selectively used in areas where climatic factors may threaten module lifespan. By choosing encapsulants based on geographical and environmental factors, developers in Argentina can enhance solar energy output, decrease maintenance requirements, and prolong the lifespan of modules.

In Argentina by technology is divided into Crystalline Silicon Solar and Thin-Film Solar, the predominant technology for photovoltaics is crystalline silicon (c-Si), which holds a significant share of both large-scale and commercial installations. Crystalline panels, consisting of both monocrystalline and Multi crystalline silicon, are preferred due to their superior efficiency, lasting reliability, and well-developed manufacturing process. These qualities make c-Si the go-to option for extensive projects throughout the country's various climate zones, ranging from the moist pampas to the elevated areas of the Andes, where consistent performance and resilience are crucial. The well-established supply network, uniform module designs, and familiar operational features further solidify the leading role of crystalline silicon, allowing developers to achieve cost-effective energy production on a large scale. In comparison, thin-film solar technologies, such as cadmium telluride (CdTe) and new perovskite cells, are mainly tested in particular applications, especially in desert ventures in northern Argentina. These areas face extreme solar radiation, elevated temperatures, and strong UV light, which can create issues for traditional crystalline panels. Thin-film panels are lighter and more flexible, frequently showing better performance in high-temperature situations and lower light conditions, making them well-suited for test or pilot projects in challenging settings. The testing of thin-film technologies enables developers and scientists to assess their performance, longevity, and economic feasibility under local desert conditions while seeking termsal options alongside crystalline silicon. Although thin-film uptake is still minimal compared to c-Si, these pilot initiatives illustrate its promise to tackle specific deployment difficulties, particularly in isolated or environmentally harsh locations. By keeping crystalline silicon as the primary technology while investigating thin-film options in desert areas, Argentina's solar industry can enhance energy generation across varied landscapes, merging reliability with versatility and gradually incorporating innovative technologies to promote long-term growth and sustainability in renewable energy.

Argentina's solar energy landscape by application is divided into Ground-mounted, Building-integrated photovoltaic, Floating photovoltaic and Others (Automotive, Construction, and Electronics) showcases a variety of projects and regional differences, influenced by geographical factors and the maturity of the market. In utility-scale projects, ground-mounted solar farms are prevalent, especially in San Juan province. These extensive solar facilities utilize the area's high sun exposure and ample land to produce energy efficiently and cost-effectively, primarily employing crystalline silicon technology due to its well-documented effectiveness, durability, and reliability. Concurrently, floating photovoltaic (FPV) initiatives are being explored on reservoirs, irrigation ponds, and other bodies of water, providing innovative ways to overcome land limitations while gaining from natural cooling that can potentially improve the performance of solar panels. Although still in their infancy, these FPV projects indicate how solar technology can adapt to unconventional settings. In Argentina, the uptake of rooftop solar is relatively low, mostly found in commercial and industrial buildings that have suitable space and infrastructure for limited distributed energy generation. In urban settings, building-integrated photovoltaics (BIPV) are being tested in Buenos Aires, integrating solar panels into building structures like façades and roofs to enhance energy production while maintaining visual appeal. These trials demonstrate an increasing interest in incorporating solar power into urban construction, although broader acceptance is hampered by cost and design challenges. These different sectors represent a layered method to solar deployment large ground-mounted farms optimize energy production in areas with high sunlight, floating PV investigates water-based alternatives, rooftop systems furnish distributed power for commercial and industrial sectors, and BIPV initiatives promote integration in cityscapes. By diversifying its deployment strategies, Argentina can enhance energy output, tackle land and spatial challenges, and encourage the gradual growth of both centralized and decentralized renewable energy systems, creating a flexible and robust solar market that aligns with regional demands and national renewable energy goals.

Considered in this report
• Historic Year: 2019
• Base year: 2024
• Estimated year: 2025
• Forecast year: 2030

Aspects covered in this report
• Solar Encapsulation Market with its value and forecast along with its segments
• Various drivers and challenges
• On-going trends and developments
• Top profiled companies
• Strategic recommendation

By Materials
• Ethylene Vinyl Acetate (EVA)
• Thermoplastic Polyurethane (TPU)
• Polyvinyl Butyral (PVB)
• Polydimethylsiloxane (PDMS)
• Ionomer
• Polyolefin

By Technology
• Crystalline Silicon Solar
• Thin-Film Solar

By Application
• Ground-mounted
• Building-integrated photovoltaic
• Floating photovoltaic
• Others (Automotive, Construction, and Electronics)

Table of Contents

76 Pages
1. Executive Summary
2. Market Structure
2.1. Market Considerate
2.2. Assumptions
2.3. Limitations
2.4. Abbreviations
2.5. Sources
2.6. Definitions
3. Research Methodology
3.1. Secondary Research
3.2. Primary Data Collection
3.3. Market Formation & Validation
3.4. Report Writing, Quality Check & Delivery
4. Argentina Geography
4.1. Population Distribution Table
4.2. Argentina Macro Economic Indicators
5. Market Dynamics
5.1. Key Insights
5.2. Recent Developments
5.3. Market Drivers & Opportunities
5.4. Market Restraints & Challenges
5.5. Market Trends
5.6. Supply chain Analysis
5.7. Policy & Regulatory Framework
5.8. Industry Experts Views
6. Argentina Solar Encapsulation Market Overview
6.1. Market Size By Value
6.2. Market Size and Forecast, By Materials
6.3. Market Size and Forecast, By Technology
6.4. Market Size and Forecast, By Application
6.5. Market Size and Forecast, By Region
7. Argentina Solar Encapsulation Market Segmentations
7.1. Argentina Solar Encapsulation Market, By Materials
7.1.1. Argentina Solar Encapsulation Market Size, By Ethylene Vinyl Acetate (EVA), 2019-2030
7.1.2. Argentina Solar Encapsulation Market Size, By Thermoplastic Polyurethane (TPU), 2019-2030
7.1.3. Argentina Solar Encapsulation Market Size, By Polyvinyl Butyral (PVB), 2019-2030
7.1.4. Argentina Solar Encapsulation Market Size, By Polydimethylsiloxane (PDMS), 2019-2030
7.1.5. Argentina Solar Encapsulation Market Size, By Ionomer, 2019-2030
7.1.6. Argentina Solar Encapsulation Market Size, By Polyolefin, 2019-2030
7.2. Argentina Solar Encapsulation Market, By Technology
7.2.1. Argentina Solar Encapsulation Market Size, By Crystalline Silicon Solar, 2019-2030
7.2.2. Argentina Solar Encapsulation Market Size, By Thin-Film Solar, 2019-2030
7.3. Argentina Solar Encapsulation Market, By Application
7.3.1. Argentina Solar Encapsulation Market Size, By Ground-mounted, 2019-2030
7.3.2. Argentina Solar Encapsulation Market Size, By Building-integrated photovoltaic, 2019-2030
7.3.3. Argentina Solar Encapsulation Market Size, By Floating photovoltaic, 2019-2030
7.3.4. Argentina Solar Encapsulation Market Size, By Others (Automotive, Construction, and Electronics), 2019-2030
7.4. Argentina Solar Encapsulation Market, By Region
7.4.1. Argentina Solar Encapsulation Market Size, By North, 2019-2030
7.4.2. Argentina Solar Encapsulation Market Size, By East, 2019-2030
7.4.3. Argentina Solar Encapsulation Market Size, By West, 2019-2030
7.4.4. Argentina Solar Encapsulation Market Size, By South, 2019-2030
8. Argentina Solar Encapsulation Market Opportunity Assessment
8.1. By Materials, 2025 to 2030
8.2. By Technology, 2025 to 2030
8.3. By Application, 2025 to 2030
8.4. By Region, 2025 to 2030
9. Competitive Landscape
9.1. Porter's Five Forces
9.2. Company Profile
9.2.1. Company 1
9.2.1.1. Company Snapshot
9.2.1.2. Company Overview
9.2.1.3. Financial Highlights
9.2.1.4. Geographic Insights
9.2.1.5. Business Segment & Performance
9.2.1.6. Product Portfolio
9.2.1.7. Key Executives
9.2.1.8. Strategic Moves & Developments
9.2.2. Company 2
9.2.3. Company 3
9.2.4. Company 4
9.2.5. Company 5
9.2.6. Company 6
9.2.7. Company 7
9.2.8. Company 8
10. Strategic Recommendations
11. Disclaimer
List of Figures
Figure 1: Argentina Solar Encapsulation Market Size By Value (2019, 2024 & 2030F) (in USD Million)
Figure 2: Market Attractiveness Index, By Materials
Figure 3: Market Attractiveness Index, By Technology
Figure 4: Market Attractiveness Index, By Application
Figure 5: Market Attractiveness Index, By Region
Figure 6: Porter's Five Forces of Argentina Solar Encapsulation Market
List of Table
Table 1: Influencing Factors for Solar Encapsulation Market, 2024
Table 2: Argentina Solar Encapsulation Market Size and Forecast, By Materials (2019 to 2030F) (In USD Million)
Table 3: Argentina Solar Encapsulation Market Size and Forecast, By Technology (2019 to 2030F) (In USD Million)
Table 4: Argentina Solar Encapsulation Market Size and Forecast, By Application (2019 to 2030F) (In USD Million)
Table 5: Argentina Solar Encapsulation Market Size and Forecast, By Region (2019 to 2030F) (In USD Million)
Table 6: Argentina Solar Encapsulation Market Size of Ethylene Vinyl Acetate (EVA) (2019 to 2030) in USD Million
Table 7: Argentina Solar Encapsulation Market Size of Thermoplastic Polyurethane (TPU) (2019 to 2030) in USD Million
Table 8: Argentina Solar Encapsulation Market Size of Polyvinyl Butyral (PVB) (2019 to 2030) in USD Million
Table 9: Argentina Solar Encapsulation Market Size of Polydimethylsiloxane (PDMS) (2019 to 2030) in USD Million
Table 10: Argentina Solar Encapsulation Market Size of Ionomer (2019 to 2030) in USD Million
Table 11: Argentina Solar Encapsulation Market Size of Polyolefin (2019 to 2030) in USD Million
Table 12: Argentina Solar Encapsulation Market Size of Crystalline Silicon Solar (2019 to 2030) in USD Million
Table 13: Argentina Solar Encapsulation Market Size of Thin-Film Solar (2019 to 2030) in USD Million
Table 14: Argentina Solar Encapsulation Market Size of Ground-mounted (2019 to 2030) in USD Million
Table 15: Argentina Solar Encapsulation Market Size of Building-integrated photovoltaic (2019 to 2030) in USD Million
Table 16: Argentina Solar Encapsulation Market Size of Floating photovoltaic (2019 to 2030) in USD Million
Table 17: Argentina Solar Encapsulation Market Size of Others (Automotive, Construction, and Electronics) (2019 to 2030) in USD Million
Table 18: Argentina Solar Encapsulation Market Size of North (2019 to 2030) in USD Million
Table 19: Argentina Solar Encapsulation Market Size of East (2019 to 2030) in USD Million
Table 20: Argentina Solar Encapsulation Market Size of West (2019 to 2030) in USD Million
Table 21: Argentina Solar Encapsulation Market Size of South (2019 to 2030) in USD Million
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