Introduction
The global cellulose acetate market is set for significant growth, with the market size projected to reach approximately USD 8.9 billion by 2033, up from USD 5.6 billion in 2023. This represents a compound annual growth rate (CAGR) of 4.8% from 2023 to 2033. This expansion is driven by increased demand across various industries, particularly in the production of filters, textiles, and photographic films.
Cellulose acetate’s versatility and biodegradability make it an attractive alternative to synthetic materials, contributing to its growing adoption. Recent developments, such as advancements in production technologies and new applications in biodegradable plastics, are also fueling market growth. However, the industry faces challenges including fluctuations in raw material prices and stringent environmental regulations.
The need for sustainable production methods and effective waste management strategies are critical for maintaining growth. Overall, while the market is poised for expansion, stakeholders must navigate these challenges to capitalize on emerging opportunities and drive future success.
Recent Developments in the Cellulose Acetate Market:-
The cellulose acetate market has seen notable recent developments with major industry players actively advancing their positions. Eastman Chemical Company recently announced an investment of USD 100 million to enhance its cellulose acetate production facilities, aimed at meeting the growing demand for sustainable materials.
Celanese Corporation has expanded its cellulose acetate product line with new high-performance grades tailored for medical and industrial applications, reflecting a strategic move to capture niche markets. Daicel Corporation has embarked on a significant merger with Mitsubishi Chemical, forming a new entity focused on expanding cellulose acetate production capacities and technological innovation.
This merger, valued at approximately USD 1.2 billion, aims to consolidate resources and streamline operations to better serve global markets. Additionally, Mitsubishi Chemical has launched a new line of biodegradable cellulose acetate products, which aligns with the increasing consumer and regulatory push towards sustainable materials. These developments underscore the industry’s commitment to growth and adaptation in response to market demands for advanced and eco-friendly solutions.
Statistics
- Degradation of CA tow and film was the fastest in NaOH solution; the weight loss rates after 16 weeks were 40.29% and 39.63%, respectively, followed by HCl solution, and the degradation performance of CA tow was better than that of film.
- Conducted a composting experiment on CA-based cigarette holder waste for six months and found that the mass loss rate of cigarette holders was only 20% after six months.
addition of CDs accelerated the deacetylation of CA, after being irradiated in air and simulated seawater for 30 days, the weightlessness of CA + CD was 53% and 43%. - The prepared membranes rejected up to 94.94 % methyl violet, 91.28 % methyl orange, 88.28 % methylene blue, 89.91 % cresol red, and 91.70 % malachite green dye. Along with the dyes, the membranes showed ∼40.40 % and ∼ 42.97 % rejection of NaCl and Na2SO4 salts.
- Cigarette butts are a type of litter in an urban area with an annual discarded amount of approximately 4.5 trillion, which implies about 47 % of raw litter. Approximately 76 % of smoked cigarettes by the public are littered instead of disposed of in the right place.
- About 95 % of microscopic-sized fibrous cellulose acetate consists of cigarette Butts. Cellulose acetate is the first polymer pioneered by Leob and Sourirajan to prepare the RO/NF membranes.
- Eastman Chemical announced a 70% increase in cellulose triacetate output at its Kingsport, Tennessee manufacturing site to meet the increasing demand for the chemical’s use as an intermediate in the production of polarized films for liquid crystal displays.
- Demonstrated remarkable properties of the synthesized nanofiber as an adsorbent for methylene blue from aqueous solutions with a removal efficiency of 95.37% and maximum methylene blue (MB) adsorption capacity of 940.76 mg g−1 under optimized conditions.
- A thermodynamic study of the dye removal indicated that the process was spontaneous and favorable at higher temperatures. Also, the reusability study shows a favorable dye removal efficiency of 80.67% even after 4 cycles.
- The highest yields of cellulose fiber and α-cellulose contents were obtained using 3.0% and 6.0% v/v NaClO, respectively. The C–O acetyl bond detected by Fourier Transform Infrared (FTIR) analysis indicates the formation of the CAM.
- Cellulose content on a dry weight basis was found to be about 40% in untreated khat waste and about 90% in as-obtained cellulose fibers. The degree of substitution of cellulose acetate ranged from 1.4 to 2.1 with weight gains from 133 to 146%.
- The elimination of noncellulosic components, notably hemicellulose and lignin, was demonstrated by an increase in the crystallinity index (CrI) of extracted cellulose (73%) after chemical treatment of untreated khat waste (56%).
- The performance prediction models all achieved a fit of 90% or higher. The best parameters recommended by Design-Expert were WCA content of 0.201%, WCA shearing time of 11.847 min, and asphalt-aggregate ratio of 5.683%, and the WCA-reinforced asphalt mixture 𝑅dry, 𝑅saturated, and TSR values were 1.38 MPa, 1.24 MPa, and 89.86%
- Permeate flux and contact angle measurements were considered to estimate their water content (96%) capacity and NOM rejection (96%) using 0.1 ppm humic acid solution.
- The price of Cellulose Acetate (Europe) declined slightly throughout April 2019, reaching 2,510 USD per metric ton. The price is 4% lower than the average price in the previous month and 1% lower than the average price one year before.
- The main forms of Cellulose Acetate are filtered/unfiltered; plastic (52–54% acetic acid); lacquer (54–56% acetic acid); film (55.5–56.6% acetic acid); water resisting (56.5–59% acetic acid); and triacetate (60.0–62.5% acetic acid). When commercialized, Cellulose Acetate is transported in one of the following forms: powder, granules, and mixed.
- The optimized results showed that 20 wt. % of PCL loading has improved the overall properties of the nanofibers. At this concentration, the spinning of the fibers started than the usual Electrospraying.
- A composite crystal size of 24.14 nm and a crystallinity percentage of 34.05% were found using XRD data. S. aureus bacteria are more inhibited by all evaluated substances antibacterial properties than E. coli germs. ZnO/Cellulose Acetate composite is categorized as strong inhibition, while ZnO nanoparticles are categorized as medium inhibition.
- The optimal spinning condition with the bore fluid (water + NMP (85%)), air gap (25 mm), flow rate of bore fluid (40% of dope rate), and temperature of quench bath (50 ◦C) was identified to make high PVP content, symmetric cross-section and highly cross-linked CA hollow fibers.
- Synthesis and characterization of cellulose acetate and nitrocellulose acetate have been carried out. Cellulose was isolated from sengon wood powder waste using 6% NaOH solution and bleached with NaOCl. The cellulose was hydrolyzed with 60% formic acid to obtain nanocellulose.
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Emerging Trends
- The cellulose acetate market is witnessing several emerging trends that are shaping its future. Firstly, there is a growing shift towards sustainability, with increasing demand for biodegradable and eco-friendly materials. This trend is driven by heightened environmental awareness and regulatory pressures, leading companies to develop new grades of cellulose acetate that offer enhanced biodegradability and reduced environmental impact.
- Another significant trend is the expansion of applications beyond traditional uses. Cellulose acetate is increasingly being employed in the medical and pharmaceutical industries, particularly for drug delivery systems and medical devices. This diversification is opening new growth avenues for the material, as it demonstrates versatility in various high-value applications.
- Technological advancements are also playing a crucial role, with innovations in production processes improving the efficiency and quality of cellulose acetate. Companies are investing in research and development to enhance product performance and meet specific market needs, such as higher strength and better clarity for applications in optical films and packaging.
- Additionally, there is a notable rise in mergers and acquisitions among major industry players. These strategic moves are aimed at expanding production capacities and leveraging synergies to better compete in the global market. For example, recent mergers, such as the one between Daicel Corporation and Mitsubishi Chemical, are expected to streamline operations and boost innovation.
Use Cases
- Textiles: Cellulose acetate is widely used in the textile industry for manufacturing fabrics and apparel. It is valued for its softness, drape, and ability to hold vibrant dyes. In 2023, cellulose acetate textiles represented approximately 20% of the global market, with an increasing trend towards sustainable fabrics driving further growth.
- Filters: The material is essential in producing cigarette filters and industrial filtration products. Its high absorbency and ability to capture particles make it ideal for these applications. The filter segment is expected to grow at a CAGR of 5.2% through 2033, reflecting rising demand for efficient filtration solutions.
- Photographic Films: Historically, cellulose acetate has been used in the film industry for photographic films and X-rays. Despite the shift to digital media, cellulose acetate films remain in demand for specialty applications, contributing significantly to the market.
- Medical Devices: Recent advancements have expanded cellulose acetate’s use into the medical field, where it is employed in drug delivery systems, surgical instruments, and wound dressings. The medical applications segment is growing rapidly, driven by innovations and increased demand for biocompatible materials.
- Packaging: Cellulose acetate is increasingly used in packaging solutions, including biodegradable food wrappers and films. This use case is growing as the push for eco-friendly packaging solutions intensifies, with the market segment projected to reach USD 1.5 billion by 2033.
Key Players Analysis
Eastman Chemical Company is a major player in the cellulose acetate sector, focusing on advanced production and product development. They have invested over USD 100 million to enhance their cellulose acetate facilities, aiming to meet rising demand for sustainable and high-performance materials. Eastman’s innovations include new grades of cellulose acetate for diverse applications such as filters and textiles.
Celanese Corporation is a key contributor to the cellulose acetate market, expanding its product offerings with new high-performance grades. These innovations cater to medical, industrial, and consumer applications, reflecting the company’s focus on meeting specific market needs. Celanese is committed to sustainability and technological advancements, reinforcing its position in the global cellulose acetate market.
Daicel Corporation is a prominent player in the cellulose acetate sector, focusing on high-quality production and innovation. The company specializes in manufacturing cellulose acetate used in various applications such as films, fibers, and medical devices. Daicel’s commitment to advancing technology and sustainability in cellulose acetate production underscores its strategic position in the market.
Mitsubishi Chemical is a key contributor to the cellulose acetate market, offering a range of products for applications including films, textiles, and industrial materials. The company is actively involved in enhancing production processes and developing sustainable solutions, such as biodegradable cellulose acetate products. Mitsubishi Chemical’s efforts reflect its focus on innovation and meeting the growing demand for eco-friendly materials.
Rayonier Advanced Materials, Inc. is a key player in the cellulose acetate market, focusing on producing high-quality acetate products used in textiles, filters, and industrial applications. The company operates advanced manufacturing facilities and invests in innovative technologies to enhance product performance and sustainability. Rayonier’s strategic initiatives aim to expand its market share and meet growing demand for eco-friendly and versatile materials
Biosynth Carbosynth is actively involved in the cellulose acetate sector, specializing in the development and supply of high-purity cellulose derivatives for various industrial applications. The company focuses on producing advanced cellulose acetate for uses in pharmaceuticals, diagnostics, and specialty chemicals. Biosynth Carbosynth’s expertise and innovations are driving growth in the sector, catering to increasing demand for high-performance and sustainable materials.
Carbomer, Inc. is a key player in the cellulose acetate sector, focusing on the development and production of high-quality cellulose acetate products for various applications. The company’s expertise includes creating cellulose acetate for use in medical devices, filters, and specialty films. Carbomer, Inc. is noted for its commitment to innovation and quality, enhancing its market position.
Cardia International is a prominent manufacturer in the cellulose acetate industry, specializing in producing advanced cellulose acetate products for use in films, fibers, and industrial applications. The company’s focus on high-performance materials supports its role in various markets, including packaging and filtration. Cerdia International’s ongoing research and development efforts aim to drive innovation and sustainability in the cellulose acetate sector.
Chemos is a notable player in the cellulose acetate sector, specializing in the production of high-quality cellulose acetate products for diverse applications, including textiles and industrial uses. The company focuses on innovation and efficiency to meet the growing demand for sustainable and performance-driven materials. Chemos’s strategic investments in R&D and state-of-the-art manufacturing facilities support its competitive edge in the global market.
China National Tobacco Corporation is a major entity in the cellulose acetate sector, particularly known for its production of cigarette filters. The company leverages advanced technology to produce high-performance cellulose acetate fibers that enhance filter efficiency. As the world’s largest tobacco manufacturer, its significant investment in cellulose acetate helps maintain its market dominance and meet the increasing demand for quality filtration solutions.
Dongguan He-Hong Plastic Co Ltd is a key player in the cellulose acetate sector, specializing in the production of high-quality cellulose acetate films and sheets. Their products cater to various applications, including packaging and textiles. The company emphasizes innovation and quality control to meet the growing demand for sustainable and durable materials.
Sichuan Push Acetati Co., Ltd is a prominent manufacturer in the cellulose acetate industry, known for its production of cellulose acetate fibers and films. The company focuses on advancing technology to enhance product performance and sustainability. Their offerings are widely used in textiles, filters, and other applications requiring high-quality, eco-friendly materials.
Conclusion
The cellulose acetate market is experiencing robust growth, driven by increasing demand for sustainable and versatile materials across various sectors. With the market expected to reach approximately USD 8.9 billion by 2033, up from USD 5.6 billion in 2023, the industry is expanding at a CAGR of 4.8%. Key drivers include the rising adoption of eco-friendly products in textiles, medical devices, and packaging, alongside technological advancements in production processes. Despite challenges such as fluctuating raw material prices and environmental regulations, the market’s positive outlook reflects a strong shift towards innovative and sustainable solutions.
Sources :
- https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10707985/
- https://wifitalents.com/statistic/cellulose-acetate-industry/
- https://en.wikipedia.org/wiki/Cellulose_triacetate
- https://www.nature.com/articles/s41598-023-32097-3
- https://scholarhub.ui.ac.id/science/vol25/iss3/4/
- https://www.ajol.info/index.php/epj/article/view/253138
- https://ascelibrary.org/doi/abs/10.1061/JMCEE7.MTENG-15269
- https://www.cell.com/heliyon/fulltext/S2405-8440(23)00943-X
- https://www.intratec.us/chemical-markets/cellulose-acetate-price
- https://papers.ssrn.com/sol3/papers.cfm?abstract_id=4022530
- https://sciencetechindonesia.com/index.php/jsti/article/view/923
- https://ntnuopen.ntnu.no/ntnu-xmlui/handle/11250/2473994
- https://jpacr.ub.ac.id/index.php/jpacr/article/view/644
- https://www.eastman.com/en
- https://www.celanese.com/
- https://www.daicel.com/
- https://mitsubishichemicals.com/
- https://www.rayonieram.com/
- https://www.biosynth.com/
- https://carbomer.com/
- https://www.cerdia.com/
- https://www.chemos.de/
- http://www.tobacco.gov.cn/
- https://www.hehongplastic.com/
- http://www.pushacetati.com/