Core Viewpoint - The article discusses the current status, trends, and future prospects of the n-Butyl Methacrylate (n-BMA) industry, highlighting its applications, market dynamics, and the impact of regulations on its development [5][8][19]. Group 1: Industry Current Status - n-Butyl Methacrylate is primarily produced by companies such as Röhm, Mitsubishi Chemical Group, and LX MMA, with stable supply from regions including Germany, the USA, South Korea, Japan, and China [5][18]. - The production process of n-BMA is sensitive to the price fluctuations of upstream materials like MAA and MMA, which significantly affect market prices [6][19]. - The main applications of n-BMA include coatings, adhesives, sealants, and plastic modification, where it serves as a "low Tg soft monomer" to enhance properties like weather resistance and adhesion [4][7]. Group 2: Development Trends - The demand for n-BMA is expected to grow steadily, driven by its applications in coatings, adhesives, and sealants [8][19]. - Production processes are evolving towards low-carbon solutions in response to environmental policies, with a focus on low-carbon MMA and n-BMA [9][20]. - The presence of alternative products in the market poses a challenge, as other methacrylate products can effectively substitute n-BMA in certain applications [10][11]. Group 3: Market Size Analysis - According to QYResearch, the global n-BMA market is projected to reach $207 million in sales by 2024 and $281 million by 2031, with a compound annual growth rate (CAGR) of 4.81% from 2025 to 2031 [16]. - The Chinese market is rapidly growing, expected to account for approximately 41.88% of the global market by 2024, increasing to 44.94% by 2031 [16]. Group 4: Opportunities and Driving Factors - The strong demand from downstream industries such as coatings and adhesives is a key driver for the stable development of the n-BMA industry [19]. - Innovations in low-carbon production processes and compliance with stricter VOC regulations are expected to create growth opportunities for n-BMA [20][21].

Core Insights - Chinese researchers have achieved nearly 100% utilization of precious metal atoms in catalytic reactions, paving the way for the design and preparation of new generation efficient and low-cost catalysts, contributing to low-carbon, efficient, and sustainable chemical production [1][5] Group 1: Research Breakthrough - The breakthrough was made by the New Energy Chemical team at Tianjin University, with results published in the journal "Science" on September 26 [1][5] - The research addresses the challenge of maximizing precious metal utilization efficiency, which is a focal point in the international chemical industry [3][5] Group 2: Technological Innovation - The team developed an "atom extraction" technology that significantly enhances the catalytic efficiency of propane dehydrogenation for propylene production, reducing precious metal usage by approximately 90% compared to traditional catalysts [5] - This innovation resolves key bottlenecks in the propylene industry, such as high catalyst costs and strong reliance on precious metal resources, providing a low-cost and sustainable technological pathway for the chemical industry [5] Group 3: Collaborative Efforts - The research involved collaboration with Tianjin Normal University, Peking University, and Zhejiang University of Technology [5] - The team leader emphasized the importance of integrating fundamental research with practical applications to support the green and low-carbon transformation of the chemical industry [5]