
Europe Propylene Oxide Market Outlook, 2030
Description
Propylene oxide is a critical intermediate chemical, primarily used in the production of polyether polyols, which are essential for manufacturing flexible and rigid polyurethane foams. These foams find extensive applications across industries such as automotive, construction, furniture, and insulation, making them a major driver of PO consumption. In Europe, countries like Germany, France, and Italy dominate demand due to their well-established automotive and construction sectors, which are increasingly focused on lightweight and energy-efficient materials. The automotive industry, in particular, is adopting lightweight polyurethane components to improve fuel efficiency and reduce carbon emissions, while the construction sector is relying on polyurethane-based insulation materials to meet stringent energy efficiency standards. Despite this strong demand, the market faces challenges such as fluctuating feedstock costs, competition from alternative insulation materials, and global overcapacity pressures that can affect profitability. Regulatory frameworks in Europe further shape the market dynamics. The European Union’s Green Deal, targeting carbon neutrality by 2050, along with regulations like REACH (Registration, Evaluation, Authorization, and Restriction of Chemicals), mandate manufacturers to ensure the safety and environmental sustainability of chemical production, including propylene oxide. These regulatory pressures have prompted industry players to adopt greener production methods, reduce emissions, and improve process efficiency, aligning with broader sustainability goals. Technological innovations are also playing a crucial role in transforming the European PO market. December 2024, Lyondell Basell (Netherlands) completed a major turnaround at its propylene oxide facility in Channelview, Texas, incorporating upgraded catalysts and automation systems to enhance yield efficiency and process safety.
According to the research report, ""Europe Propylene Oxide Market Outlook, 2030,"" published by Bonafide Research, the Europe Propylene Oxide market is anticipated to add to more than USD 1.51 Billion by 2025–30. Similarly, processes such as PO/CO₂, which utilize carbon dioxide as a co-reactant, are emerging as promising alternatives to reduce greenhouse gas emissions while maintaining high process efficiency. These innovations are critical not only for regulatory compliance but also for enhancing competitiveness in a market increasingly focused on green chemistry. However, economic and operational challenges remain, including the closure of production units by major players like LyondellBasell and Covestro in the Netherlands, high production costs, and import competition from Asia. In September 2024, Shell Plc (UK) initiated a feasibility study for building a new PO plant using Smart PO technology in Saudi Arabia, in collaboration with local petrochemical partners, aligning with regional diversification and clean energy goals. Europe’s mature industrial base, particularly in Germany, France, and Italy, ensures strong consumption, while the market is simultaneously adapting to trends toward alternative materials and bio-based chemicals. Industry players are responding strategically by investing in renewable propylene oxide production facilities, exploring chemical recycling technologies, and implementing process optimization to maintain competitiveness amidst rising production costs and global overcapacity. For instance, European companies are increasingly emphasizing process innovations and sustainable supply chains to meet both regulatory requirements and the growing demand for environmentally responsible products. In January 2025, BASF SE (Germany) and Solvay SA (Belgium) entered into a joint development agreement to advance HPPO technology, aiming to lower carbon emissions and water usage across production cycles by 20% by 2027. The European Union’s Green Deal, which aims for carbon neutrality by 2050, alongside regulations like REACH (Registration, Evaluation, Authorization, and Restriction of Chemicals), mandates manufacturers to ensure chemical safety, minimize environmental hazards, and adopt cleaner production technologies.
Market Drivers
• Rising Demand from Sustainable Construction and Automotive Industries: In Europe, the propylene oxide market is primarily driven by strong demand for polyurethane foams used in insulation materials and lightweight automotive components. With the European Union’s stringent energy efficiency directives and push toward net-zero carbon emissions, construction companies are increasingly using rigid polyurethane foams for thermal insulation in residential and commercial buildings. Simultaneously, the automotive industry, particularly in Germany, France, and Italy, is leveraging flexible polyurethane foams to reduce vehicle weight and improve fuel efficiency. These sustainability-focused industries continue to fuel steady growth in propylene oxide consumption across the region.
• Growth in Specialty and Consumer-Oriented Applications: Europe has a well-established pharmaceutical, personal care, and food processing sector, all of which are major consumers of propylene oxide derivatives like propylene glycol and glycol ethers. Propylene glycol is widely used as a solvent and excipient in drug formulations, a humectant in cosmetics, and a stabilizer in food products. The growing demand for high-quality consumer goods, coupled with the rising focus on health and wellness products, ensures consistent growth in specialty applications. This diversified demand beyond industrial uses strengthens the region’s overall market stability.
Market Challenges
• Stringent Environmental and Safety Regulations: One of the biggest challenges in Europe is compliance with strict environmental and safety standards under the EU’s REACH (Registration, Evaluation, Authorisation, and Restriction of Chemicals) regulations. Propylene oxide is classified as hazardous, and producers must adhere to strict guidelines related to emissions, waste management, and worker safety. These regulatory requirements increase production costs and force companies to continually upgrade their processes to remain compliant. For smaller producers, this can be a major barrier to entry or expansion.
• High Energy Costs and Feedstock Dependency: Europe faces high energy costs compared to other regions, which significantly affects the economics of propylene oxide production. Additionally, the region relies heavily on imported crude oil and natural gas, both of which are critical feedstocks for producing propylene. Supply disruptions, geopolitical uncertainties, and price volatility create added pressure on producers, reducing cost competitiveness compared to players in Asia-Pacific and North America. This dependency poses a constant challenge for the European propylene oxide market.
Market Trends
• Shift Toward Green and Bio-Based Propylene Oxide: A major trend in Europe is the increasing investment in sustainable and bio-based alternatives to conventional propylene oxide. Companies are exploring renewable raw materials and bio-propylene production technologies to align with the EU’s circular economy and climate action goals. The adoption of the HPPO (hydrogen peroxide to propylene oxide) process is also gaining traction in Europe due to its reduced environmental footprint. This trend highlights the region’s commitment to eco-friendly production practices and long-term sustainability.
• Industry Consolidation and Strategic Partnerships: Another emerging trend in Europe is consolidation within the chemical sector, with major players forming strategic partnerships and joint ventures to strengthen their presence in the propylene oxide market. These collaborations are focused on technological innovation, feedstock security, and geographic expansion. For example, European companies are increasingly partnering with global chemical giants to build advanced facilities and ensure sustainable supply chains. This trend is shaping a more collaborative and competitive market landscape.
TBA (tert-Butyl Alcohol) Co-product process is leading in Europe’s propylene oxide industry due to its cost-efficiency, high propylene oxide yield, and alignment with stringent environmental and safety regulations.
The dominance of the TBA co-product process in Europe’s propylene oxide industry is driven by a combination of economic, technical, and regulatory factors that make it highly favorable compared to alternative production methods such as the chlorohydrin or hydrogen peroxide processes. One of the primary advantages is its cost-effectiveness; the TBA process allows producers to obtain propylene oxide while simultaneously generating tert-butyl alcohol as a valuable co-product, which can be marketed or used in downstream chemical industries. This dual output significantly improves overall profitability and resource utilization, reducing raw material waste and enhancing the economic feasibility of large-scale operations. From a technical perspective, the TBA process offers high propylene oxide yields with relatively mild reaction conditions. This not only ensures consistent product quality but also minimizes energy consumption and operational hazards, aligning well with Europe’s industrial focus on sustainability and efficiency. Furthermore, Europe has one of the strictest regulatory frameworks for chemical production, particularly concerning emissions, waste management, and worker safety. The TBA co-product route inherently produces fewer chlorinated by-products and hazardous effluents compared to the traditional chlorohydrin process, helping manufacturers comply with environmental and safety standards more easily. Additionally, the process integrates well with existing propylene oxide supply chains and downstream polyol and polyurethane production, which are significant end-user markets in Europe. The scalability and adaptability of the TBA co-product process also contribute to its leading position; it can be optimized for varying production capacities and feedstock availability, providing flexibility in a competitive and energy-conscious market. Finally, the strong industrial ecosystem in Europe, including advanced catalysts, process optimization technologies, and skilled labor, further supports the widespread adoption of the TBA process.
Glycol ethers application is moderately growing in Europe’s propylene oxide industry due to increasing demand in paints, coatings, and cleaning products driven by urbanization and industrialization.
The moderate growth of glycol ethers as an application type in Europe’s propylene oxide industry is largely influenced by the expanding demand for high-performance solvents across multiple industrial and consumer sectors. Glycol ethers, produced from propylene oxide, are versatile solvents widely used in paints, coatings, inks, adhesives, and cleaning products due to their excellent solvency, low volatility, and compatibility with water-based formulations. Europe’s construction, automotive, and electronics sectors are key contributors to this trend, as rising urbanization and industrial activities increase the consumption of coatings, paints, and maintenance chemicals. In particular, the growing preference for environmentally friendly and low-VOC (volatile organic compound) products in Europe has led manufacturers to adopt glycol ether-based solvents in waterborne and eco-friendly coatings, reinforcing steady demand growth. Additionally, the cleaning and personal care industries are also fueling moderate growth, as glycol ethers are essential in formulating detergents, degreasers, and household products that meet stringent European regulatory standards for safety and environmental impact. The moderate pace of growth, rather than rapid expansion, is a result of market maturity and strong regulatory oversight in the region. European markets are highly regulated under REACH (Registration, Evaluation, Authorization, and Restriction of Chemicals) and other environmental directives, which can slow the introduction of new solvent types and limit large-scale expansion. Furthermore, rising raw material costs and supply chain constraints for propylene feedstock contribute to measured growth in glycol ether applications, as producers balance cost-effectiveness with product availability.
The automotive end-user segment is moderately growing in Europe’s propylene oxide industry due to rising demand for lightweight materials and polyurethane-based components in vehicles.
The moderate growth of the automotive end-user segment in Europe’s propylene oxide industry is driven by the automotive sector’s gradual transition toward lightweight, fuel-efficient, and environmentally friendly vehicles. Propylene oxide is a critical feedstock in the production of polyurethanes, which are widely used in automotive interiors, seating, insulation, and coatings. These materials offer high durability, comfort, and weight reduction compared to conventional alternatives, directly supporting Europe’s stringent regulatory goals for vehicle emissions and fuel efficiency. The demand for polyurethanes in car manufacturing, particularly in seating foam, dashboards, door panels, and under-the-hood insulation, contributes to steady growth in propylene oxide consumption. The moderate pace of growth, rather than rapid expansion, is influenced by the mature nature of the European automotive market, where vehicle production is relatively stable and incremental improvements are emphasized over large-scale expansion. Additionally, the ongoing shift toward electric vehicles (EVs) is creating both opportunities and constraints. While EVs require lightweight materials to extend battery life and efficiency, the pace of EV adoption and the high costs associated with new material integration result in measured growth of propylene oxide usage. Another factor is the focus on sustainable and recyclable materials in the European automotive industry, which encourages the use of advanced polyurethane formulations but also imposes limits on overall volume growth due to recycling requirements and material substitution. Supply chain stability for propylene oxide and associated polyols also plays a role, as manufacturers prioritize efficiency and regulatory compliance over aggressive capacity expansion.
Germany is leading the European Propylene Oxide (PO) industry due to its well-established chemical manufacturing infrastructure, strong industrial base, and high demand from automotive, construction, and polyurethane sectors.
Germany has secured its position as the leading country in the European Propylene Oxide market, driven by a combination of industrial expertise, robust infrastructure, and strategic investments in chemical manufacturing. The nation boasts a highly developed chemical industry, characterized by advanced production facilities, research and development centers, and a skilled workforce, all of which ensure efficient and high-quality Propylene Oxide production. A key factor underpinning Germany’s dominance is the strong presence of end-use industries that rely heavily on PO derivatives. The automotive sector, one of Germany’s largest industrial pillars, consumes significant quantities of polyurethanes for lightweight components, seating, coatings, and insulation, while the construction and electronics industries drive demand for PO-based foams, adhesives, sealants, and elastomers. Germany’s strategic focus on technological innovation allows manufacturers to optimize production processes, improve yields, and reduce environmental impact, aligning with strict European regulations and sustainability goals. Access to high-quality raw materials and efficient logistics infrastructure further enhances the country’s production competitiveness, enabling smooth supply to domestic and European markets. Additionally, Germany benefits from its integration into the broader European chemical supply chain, facilitating collaborations, joint ventures, and knowledge exchange with regional and global companies. The country has also invested in the development of downstream products such as polyether polyols and propylene glycols, creating additional demand for PO and strengthening the overall market ecosystem.
***Please Note: It will take 48 hours (2 Business days) for delivery of the report upon order confirmation.
According to the research report, ""Europe Propylene Oxide Market Outlook, 2030,"" published by Bonafide Research, the Europe Propylene Oxide market is anticipated to add to more than USD 1.51 Billion by 2025–30. Similarly, processes such as PO/CO₂, which utilize carbon dioxide as a co-reactant, are emerging as promising alternatives to reduce greenhouse gas emissions while maintaining high process efficiency. These innovations are critical not only for regulatory compliance but also for enhancing competitiveness in a market increasingly focused on green chemistry. However, economic and operational challenges remain, including the closure of production units by major players like LyondellBasell and Covestro in the Netherlands, high production costs, and import competition from Asia. In September 2024, Shell Plc (UK) initiated a feasibility study for building a new PO plant using Smart PO technology in Saudi Arabia, in collaboration with local petrochemical partners, aligning with regional diversification and clean energy goals. Europe’s mature industrial base, particularly in Germany, France, and Italy, ensures strong consumption, while the market is simultaneously adapting to trends toward alternative materials and bio-based chemicals. Industry players are responding strategically by investing in renewable propylene oxide production facilities, exploring chemical recycling technologies, and implementing process optimization to maintain competitiveness amidst rising production costs and global overcapacity. For instance, European companies are increasingly emphasizing process innovations and sustainable supply chains to meet both regulatory requirements and the growing demand for environmentally responsible products. In January 2025, BASF SE (Germany) and Solvay SA (Belgium) entered into a joint development agreement to advance HPPO technology, aiming to lower carbon emissions and water usage across production cycles by 20% by 2027. The European Union’s Green Deal, which aims for carbon neutrality by 2050, alongside regulations like REACH (Registration, Evaluation, Authorization, and Restriction of Chemicals), mandates manufacturers to ensure chemical safety, minimize environmental hazards, and adopt cleaner production technologies.
Market Drivers
• Rising Demand from Sustainable Construction and Automotive Industries: In Europe, the propylene oxide market is primarily driven by strong demand for polyurethane foams used in insulation materials and lightweight automotive components. With the European Union’s stringent energy efficiency directives and push toward net-zero carbon emissions, construction companies are increasingly using rigid polyurethane foams for thermal insulation in residential and commercial buildings. Simultaneously, the automotive industry, particularly in Germany, France, and Italy, is leveraging flexible polyurethane foams to reduce vehicle weight and improve fuel efficiency. These sustainability-focused industries continue to fuel steady growth in propylene oxide consumption across the region.
• Growth in Specialty and Consumer-Oriented Applications: Europe has a well-established pharmaceutical, personal care, and food processing sector, all of which are major consumers of propylene oxide derivatives like propylene glycol and glycol ethers. Propylene glycol is widely used as a solvent and excipient in drug formulations, a humectant in cosmetics, and a stabilizer in food products. The growing demand for high-quality consumer goods, coupled with the rising focus on health and wellness products, ensures consistent growth in specialty applications. This diversified demand beyond industrial uses strengthens the region’s overall market stability.
Market Challenges
• Stringent Environmental and Safety Regulations: One of the biggest challenges in Europe is compliance with strict environmental and safety standards under the EU’s REACH (Registration, Evaluation, Authorisation, and Restriction of Chemicals) regulations. Propylene oxide is classified as hazardous, and producers must adhere to strict guidelines related to emissions, waste management, and worker safety. These regulatory requirements increase production costs and force companies to continually upgrade their processes to remain compliant. For smaller producers, this can be a major barrier to entry or expansion.
• High Energy Costs and Feedstock Dependency: Europe faces high energy costs compared to other regions, which significantly affects the economics of propylene oxide production. Additionally, the region relies heavily on imported crude oil and natural gas, both of which are critical feedstocks for producing propylene. Supply disruptions, geopolitical uncertainties, and price volatility create added pressure on producers, reducing cost competitiveness compared to players in Asia-Pacific and North America. This dependency poses a constant challenge for the European propylene oxide market.
Market Trends
• Shift Toward Green and Bio-Based Propylene Oxide: A major trend in Europe is the increasing investment in sustainable and bio-based alternatives to conventional propylene oxide. Companies are exploring renewable raw materials and bio-propylene production technologies to align with the EU’s circular economy and climate action goals. The adoption of the HPPO (hydrogen peroxide to propylene oxide) process is also gaining traction in Europe due to its reduced environmental footprint. This trend highlights the region’s commitment to eco-friendly production practices and long-term sustainability.
• Industry Consolidation and Strategic Partnerships: Another emerging trend in Europe is consolidation within the chemical sector, with major players forming strategic partnerships and joint ventures to strengthen their presence in the propylene oxide market. These collaborations are focused on technological innovation, feedstock security, and geographic expansion. For example, European companies are increasingly partnering with global chemical giants to build advanced facilities and ensure sustainable supply chains. This trend is shaping a more collaborative and competitive market landscape.
TBA (tert-Butyl Alcohol) Co-product process is leading in Europe’s propylene oxide industry due to its cost-efficiency, high propylene oxide yield, and alignment with stringent environmental and safety regulations.
The dominance of the TBA co-product process in Europe’s propylene oxide industry is driven by a combination of economic, technical, and regulatory factors that make it highly favorable compared to alternative production methods such as the chlorohydrin or hydrogen peroxide processes. One of the primary advantages is its cost-effectiveness; the TBA process allows producers to obtain propylene oxide while simultaneously generating tert-butyl alcohol as a valuable co-product, which can be marketed or used in downstream chemical industries. This dual output significantly improves overall profitability and resource utilization, reducing raw material waste and enhancing the economic feasibility of large-scale operations. From a technical perspective, the TBA process offers high propylene oxide yields with relatively mild reaction conditions. This not only ensures consistent product quality but also minimizes energy consumption and operational hazards, aligning well with Europe’s industrial focus on sustainability and efficiency. Furthermore, Europe has one of the strictest regulatory frameworks for chemical production, particularly concerning emissions, waste management, and worker safety. The TBA co-product route inherently produces fewer chlorinated by-products and hazardous effluents compared to the traditional chlorohydrin process, helping manufacturers comply with environmental and safety standards more easily. Additionally, the process integrates well with existing propylene oxide supply chains and downstream polyol and polyurethane production, which are significant end-user markets in Europe. The scalability and adaptability of the TBA co-product process also contribute to its leading position; it can be optimized for varying production capacities and feedstock availability, providing flexibility in a competitive and energy-conscious market. Finally, the strong industrial ecosystem in Europe, including advanced catalysts, process optimization technologies, and skilled labor, further supports the widespread adoption of the TBA process.
Glycol ethers application is moderately growing in Europe’s propylene oxide industry due to increasing demand in paints, coatings, and cleaning products driven by urbanization and industrialization.
The moderate growth of glycol ethers as an application type in Europe’s propylene oxide industry is largely influenced by the expanding demand for high-performance solvents across multiple industrial and consumer sectors. Glycol ethers, produced from propylene oxide, are versatile solvents widely used in paints, coatings, inks, adhesives, and cleaning products due to their excellent solvency, low volatility, and compatibility with water-based formulations. Europe’s construction, automotive, and electronics sectors are key contributors to this trend, as rising urbanization and industrial activities increase the consumption of coatings, paints, and maintenance chemicals. In particular, the growing preference for environmentally friendly and low-VOC (volatile organic compound) products in Europe has led manufacturers to adopt glycol ether-based solvents in waterborne and eco-friendly coatings, reinforcing steady demand growth. Additionally, the cleaning and personal care industries are also fueling moderate growth, as glycol ethers are essential in formulating detergents, degreasers, and household products that meet stringent European regulatory standards for safety and environmental impact. The moderate pace of growth, rather than rapid expansion, is a result of market maturity and strong regulatory oversight in the region. European markets are highly regulated under REACH (Registration, Evaluation, Authorization, and Restriction of Chemicals) and other environmental directives, which can slow the introduction of new solvent types and limit large-scale expansion. Furthermore, rising raw material costs and supply chain constraints for propylene feedstock contribute to measured growth in glycol ether applications, as producers balance cost-effectiveness with product availability.
The automotive end-user segment is moderately growing in Europe’s propylene oxide industry due to rising demand for lightweight materials and polyurethane-based components in vehicles.
The moderate growth of the automotive end-user segment in Europe’s propylene oxide industry is driven by the automotive sector’s gradual transition toward lightweight, fuel-efficient, and environmentally friendly vehicles. Propylene oxide is a critical feedstock in the production of polyurethanes, which are widely used in automotive interiors, seating, insulation, and coatings. These materials offer high durability, comfort, and weight reduction compared to conventional alternatives, directly supporting Europe’s stringent regulatory goals for vehicle emissions and fuel efficiency. The demand for polyurethanes in car manufacturing, particularly in seating foam, dashboards, door panels, and under-the-hood insulation, contributes to steady growth in propylene oxide consumption. The moderate pace of growth, rather than rapid expansion, is influenced by the mature nature of the European automotive market, where vehicle production is relatively stable and incremental improvements are emphasized over large-scale expansion. Additionally, the ongoing shift toward electric vehicles (EVs) is creating both opportunities and constraints. While EVs require lightweight materials to extend battery life and efficiency, the pace of EV adoption and the high costs associated with new material integration result in measured growth of propylene oxide usage. Another factor is the focus on sustainable and recyclable materials in the European automotive industry, which encourages the use of advanced polyurethane formulations but also imposes limits on overall volume growth due to recycling requirements and material substitution. Supply chain stability for propylene oxide and associated polyols also plays a role, as manufacturers prioritize efficiency and regulatory compliance over aggressive capacity expansion.
Germany is leading the European Propylene Oxide (PO) industry due to its well-established chemical manufacturing infrastructure, strong industrial base, and high demand from automotive, construction, and polyurethane sectors.
Germany has secured its position as the leading country in the European Propylene Oxide market, driven by a combination of industrial expertise, robust infrastructure, and strategic investments in chemical manufacturing. The nation boasts a highly developed chemical industry, characterized by advanced production facilities, research and development centers, and a skilled workforce, all of which ensure efficient and high-quality Propylene Oxide production. A key factor underpinning Germany’s dominance is the strong presence of end-use industries that rely heavily on PO derivatives. The automotive sector, one of Germany’s largest industrial pillars, consumes significant quantities of polyurethanes for lightweight components, seating, coatings, and insulation, while the construction and electronics industries drive demand for PO-based foams, adhesives, sealants, and elastomers. Germany’s strategic focus on technological innovation allows manufacturers to optimize production processes, improve yields, and reduce environmental impact, aligning with strict European regulations and sustainability goals. Access to high-quality raw materials and efficient logistics infrastructure further enhances the country’s production competitiveness, enabling smooth supply to domestic and European markets. Additionally, Germany benefits from its integration into the broader European chemical supply chain, facilitating collaborations, joint ventures, and knowledge exchange with regional and global companies. The country has also invested in the development of downstream products such as polyether polyols and propylene glycols, creating additional demand for PO and strengthening the overall market ecosystem.
***Please Note: It will take 48 hours (2 Business days) for delivery of the report upon order confirmation.
Table of Contents
99 Pages
- 1. Executive Summary
- 2. Market Dynamics
- 2.1. Market Drivers & Opportunities
- 2.2. Market Restraints & Challenges
- 2.3. Market Trends
- 2.4. Supply chain Analysis
- 2.5. Policy & Regulatory Framework
- 2.6. Industry Experts Views
- 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. Market Structure
- 4.1. Market Considerate
- 4.2. Assumptions
- 4.3. Limitations
- 4.4. Abbreviations
- 4.5. Sources
- 4.6. Definitions
- 5. Economic /Demographic Snapshot
- 6. Europe Propylene Oxide Market Outlook
- 6.1. Market Size By Value
- 6.2. Market Share By Country
- 6.3. Market Size and Forecast, By Production Process
- 6.4. Market Size and Forecast, By Application
- 6.5. Market Size and Forecast, By End-use industry
- 6.6. Germany Propylene Oxide Market Outlook
- 6.6.1. Market Size by Value
- 6.6.2. Market Size and Forecast By Production Process
- 6.6.3. Market Size and Forecast By Application
- 6.6.4. Market Size and Forecast By End-use industry
- 6.7. United Kingdom (UK) Propylene Oxide Market Outlook
- 6.7.1. Market Size by Value
- 6.7.2. Market Size and Forecast By Production Process
- 6.7.3. Market Size and Forecast By Application
- 6.7.4. Market Size and Forecast By End-use industry
- 6.8. France Propylene Oxide Market Outlook
- 6.8.1. Market Size by Value
- 6.8.2. Market Size and Forecast By Production Process
- 6.8.3. Market Size and Forecast By Application
- 6.8.4. Market Size and Forecast By End-use industry
- 6.9. Italy Propylene Oxide Market Outlook
- 6.9.1. Market Size by Value
- 6.9.2. Market Size and Forecast By Production Process
- 6.9.3. Market Size and Forecast By Application
- 6.9.4. Market Size and Forecast By End-use industry
- 6.10. Spain Propylene Oxide Market Outlook
- 6.10.1. Market Size by Value
- 6.10.2. Market Size and Forecast By Production Process
- 6.10.3. Market Size and Forecast By Application
- 6.10.4. Market Size and Forecast By End-use industry
- 6.11. Russia Propylene Oxide Market Outlook
- 6.11.1. Market Size by Value
- 6.11.2. Market Size and Forecast By Production Process
- 6.11.3. Market Size and Forecast By Application
- 6.11.4. Market Size and Forecast By End-use industry
- 7. Competitive Landscape
- 7.1. Competitive Dashboard
- 7.2. Business Strategies Adopted by Key Players
- 7.3. Key Players Market Positioning Matrix
- 7.4. Porter's Five Forces
- 7.5. Company Profile
- 7.5.1. Dow Inc.
- 7.5.1.1. Company Snapshot
- 7.5.1.2. Company Overview
- 7.5.1.3. Financial Highlights
- 7.5.1.4. Geographic Insights
- 7.5.1.5. Business Segment & Performance
- 7.5.1.6. Product Portfolio
- 7.5.1.7. Key Executives
- 7.5.1.8. Strategic Moves & Developments
- 7.5.2. BASF SE
- 7.5.3. LyondellBasell Industries N.V.
- 7.5.4. Shell Plc
- 7.5.5. Repsol S.A.
- 7.5.6. Merck KGaA
- 7.5.7. Sumitomo Chemical Co., Ltd.
- 7.5.8. AGC Inc.
- 7.5.9. Ineos Group Limited
- 7.5.10. Tokuyama Corporation
- 7.5.11. Tokyo Chemical Industry Co. Ltd.
- 7.5.12. Balchem Corporation
- 8. Strategic Recommendations
- 9. Annexure
- 9.1. FAQ`s
- 9.2. Notes
- 9.3. Related Reports
- 10. Disclaimer
- List of Figures
- Figure 1: Global Propylene Oxide Market Size (USD Billion) By Region, 2024 & 2030
- Figure 2: Market attractiveness Index, By Region 2030
- Figure 3: Market attractiveness Index, By Segment 2030
- Figure 4: Europe Propylene Oxide Market Size By Value (2019, 2024 & 2030F) (in USD Billion)
- Figure 5: Europe Propylene Oxide Market Share By Country (2024)
- Figure 6: Germany Propylene Oxide Market Size By Value (2019, 2024 & 2030F) (in USD Billion)
- Figure 7: United Kingdom (UK) Propylene Oxide Market Size By Value (2019, 2024 & 2030F) (in USD Billion)
- Figure 8: France Propylene Oxide Market Size By Value (2019, 2024 & 2030F) (in USD Billion)
- Figure 9: Italy Propylene Oxide Market Size By Value (2019, 2024 & 2030F) (in USD Billion)
- Figure 10: Spain Propylene Oxide Market Size By Value (2019, 2024 & 2030F) (in USD Billion)
- Figure 11: Russia Propylene Oxide Market Size By Value (2019, 2024 & 2030F) (in USD Billion)
- Figure 12: Porter's Five Forces of Global Propylene Oxide Market
- List of Tables
- Table 1: Global Propylene Oxide Market Snapshot, By Segmentation (2024 & 2030) (in USD Billion)
- Table 2: Influencing Factors for Propylene Oxide Market, 2024
- Table 3: Top 10 Counties Economic Snapshot 2022
- Table 4: Economic Snapshot of Other Prominent Countries 2022
- Table 5: Average Exchange Rates for Converting Foreign Currencies into U.S. Dollars
- Table 6: Europe Propylene Oxide Market Size and Forecast, By Production Process (2019 to 2030F) (In USD Billion)
- Table 7: Europe Propylene Oxide Market Size and Forecast, By Application (2019 to 2030F) (In USD Billion)
- Table 8: Europe Propylene Oxide Market Size and Forecast, By End-use industry (2019 to 2030F) (In USD Billion)
- Table 9: Germany Propylene Oxide Market Size and Forecast By Production Process (2019 to 2030F) (In USD Billion)
- Table 10: Germany Propylene Oxide Market Size and Forecast By Application (2019 to 2030F) (In USD Billion)
- Table 11: Germany Propylene Oxide Market Size and Forecast By End-use industry (2019 to 2030F) (In USD Billion)
- Table 12: United Kingdom (UK) Propylene Oxide Market Size and Forecast By Production Process (2019 to 2030F) (In USD Billion)
- Table 13: United Kingdom (UK) Propylene Oxide Market Size and Forecast By Application (2019 to 2030F) (In USD Billion)
- Table 14: United Kingdom (UK) Propylene Oxide Market Size and Forecast By End-use industry (2019 to 2030F) (In USD Billion)
- Table 15: France Propylene Oxide Market Size and Forecast By Production Process (2019 to 2030F) (In USD Billion)
- Table 16: France Propylene Oxide Market Size and Forecast By Application (2019 to 2030F) (In USD Billion)
- Table 17: France Propylene Oxide Market Size and Forecast By End-use industry (2019 to 2030F) (In USD Billion)
- Table 18: Italy Propylene Oxide Market Size and Forecast By Production Process (2019 to 2030F) (In USD Billion)
- Table 19: Italy Propylene Oxide Market Size and Forecast By Application (2019 to 2030F) (In USD Billion)
- Table 20: Italy Propylene Oxide Market Size and Forecast By End-use industry (2019 to 2030F) (In USD Billion)
- Table 21: Spain Propylene Oxide Market Size and Forecast By Production Process (2019 to 2030F) (In USD Billion)
- Table 22: Spain Propylene Oxide Market Size and Forecast By Application (2019 to 2030F) (In USD Billion)
- Table 23: Spain Propylene Oxide Market Size and Forecast By End-use industry (2019 to 2030F) (In USD Billion)
- Table 24: Russia Propylene Oxide Market Size and Forecast By Production Process (2019 to 2030F) (In USD Billion)
- Table 25: Russia Propylene Oxide Market Size and Forecast By Application (2019 to 2030F) (In USD Billion)
- Table 26: Russia Propylene Oxide Market Size and Forecast By End-use industry (2019 to 2030F) (In USD Billion)
- Table 27: Competitive Dashboard of top 5 players, 2024
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