Cellulose acetate

Last updated November 25, 2023

In biochemistry, cellulose acetate refers to any acetate ester of cellulose, usually cellulose diacetate. It was first prepared in 1865.^[1] A bioplastic, cellulose acetate is used as a film base in photography, as a component in some coatings, and as a frame material for eyeglasses;^[2] it is also used as a synthetic fiber in the manufacture of cigarette filters and playing cards. In photographic film, cellulose acetate film replaced nitrate film in the 1950s, being far less flammable and cheaper to produce.

History

In 1865, French chemist Paul Schützenberger discovered that cellulose reacts with acetic anhydride to form cellulose acetate. The German chemists Arthur Eichengrün and Theodore Becker invented the first soluble forms of cellulose acetate in 1903.^[3]

In 1904, Camille Dreyfus and his younger brother Henri performed chemical research and development on cellulose acetate in a shed in their father's garden in Basel, Switzerland, which was then a center of the dye industry. For five years, the Dreyfus brothers studied and experimented in a systematic manner in Switzerland and France. By 1910, they were producing film for the motion picture industry, and a small but constantly growing amount of acetate lacquer, called "dope", was sold to the expanding aircraft industry to coat the fabric covering wings and fuselage.^[4]

In 1913, after some twenty thousand separate experiments, they produced excellent laboratory samples of continuous filament yarn, something that had eluded the cellulose acetate industry to this time.^[4] Unfortunately, the outbreak of World War I postponed commercial development of this process.

In November 1914, the British Government invited Dr. Camille Dreyfus to come to England to manufacture acetate dope, and the "British Cellulose and Chemical Manufacturing Co" was set up. In 1917, after the United States had entered the war, the U.S. War Department invited Dr. Dreyfus to establish a similar factory in the U.S. Both operations were run successfully throughout the war.

After the war, attention returned to the production of acetate fibers. The first yarn was of fair quality, but sales resistance was heavy, and silk associates worked zealously to discredit acetate and discourage its use. However, the thermoplastic nature of acetate made it an excellent fiber for moiré because the pattern was permanent and did not wash away. The same characteristic also made permanent pleating a commercial fact for the first time, and gave great style impetus to the whole dress industry.^[4]

The mixing of silk and acetate in fabrics was accomplished at the beginning, and almost at once cotton was also blended, thus making possible low-cost fabrics by means of a fiber which then was cheaper than silk or acetate. Today, acetate is blended with silk, cotton, wool, nylon, etc. to give fabrics excellent wrinkle recovery, good heft, handle, draping quality, quick drying, proper dimensional stability, cross-dye pattern potential, at a very competitive price.^[4]

Uses

Fiber

Cellulose acetate fiber, one of the earliest synthetic fibers, is based on cotton or tree pulp cellulose ("biopolymers"). These "cellulosic fibers" have been replaced in many applications by cheaper petro-based fibers (nylon and polyester) in recent decades.^[5]

Trade names for acetate include Acele, Avisco, Celanese, Chromspun, and Estron.^[6]

Acetate shares many similarities with rayon, and was formerly considered as the same textile. Acetate differs from rayon in the employment of acetic acid in production. The two fabrics are now required to be listed distinctly on garment labels.^[7]

Rayon resists heat while acetate is prone to melting. Acetate must be laundered with care either by hand-washing or dry cleaning. ^[8]^[9]

The breathable nature of the fabric suits it for use as a lining. Acetate fabric is used frequently in wedding gowns and other bridal attire.^[10] Its lustrous sheen and smooth, satiny texture make it a good alternative to silk.^[8]

Properties

Acetate is a low cost, manufactured fiber, which has good draping qualities^{[ attribution needed ]}. Acetate is used in fabrics such as satins, brocades, knit fabrics, and taffetas to accentuate luster, body, drape, and beauty.

Hand: soft, smooth, dry, crisp, resilient
Comfort: breathes, wicks, dries quickly, no static cling
Drape: linings move with the body linings conform to the garment
Color: deep brilliant shades with atmospheric dyeing meet colorfastness requirements
Luster: light reflection creates a signature appearance
Performance: colorfast to perspiration staining, colorfast to dry cleaning, air and vapor permeable
Tenacity: weak fiber with breaking tenacity of 1.2 to 1.4 g/d; rapidly loses strength when wet
Abrasion: poor resistance
Heat retention: poor thermal retention; no allergenic potential (hypoallergenic)
Dyeability: (two methods) cross-dying method where yarns of one fiber and those of another fiber are woven into a fabric in a desired pattern; solution-dying method provides excellent color fastness under the effects of sunlight, perspiration, air contaminants and washing^[2]^[11]

Characteristics

cellulosic and thermoplastic
selective absorption and removal of low levels of certain organic chemicals
easily bonded with plasticizers, heat, and pressure
acetate is soluble in many common solvents (especially acetone and other organic solvents) and can be modified to be soluble in alternative solvents, including water
hydrophilic: acetate wets easily, with good liquid transport and excellent absorption; in textile applications, it provides comfort and absorbency, but also loses strength when wet
acetate fibers are hypoallergenic
high surface area
made from wood pulp, a renewable resource
can be composted or incinerated
can be dyed, however special dyes and pigments are required since acetate does not accept dyes ordinarily used for cotton and rayon (this also allows cross-dyeing)
resistant to mold and mildew
easily weakened by strong alkaline solutions and strong oxidizing agents
can usually be washed or dry cleaned; generally does not shrink

Confusion with cellulose triacetate

Cellulose diacetate and cellulose triacetate are mistakenly referred to as the same fiber; although they are similar, their chemical identities differ. Triacetate is known as a generic description or primary acetate containing no hydroxyl group. Acetate fiber is known as modified or secondary acetate having two or more hydroxyl groups. Triacetate fibers, although no longer produced in the United States, contain a higher ratio of acetate-to-cellulose than do acetate fibers.^[2]

Film

Cellulose acetate film, made from cellulose diacetate and later cellulose triacetate, was introduced in 1934 as a replacement for the cellulose nitrate film stock that had previously been standard. When exposed to heat or moisture, acids in the film base begin to deteriorate to an unusable state, releasing acetic acid with a characteristic vinegary smell, causing the process to be known as "vinegar syndrome". Acetate film stock is still used in some applications, such as camera negative for motion pictures. Since the 1980s, polyester film stock (sometimes referred to under Kodak's trade name "ESTAR Base") has become more commonplace, particularly for archival applications. Acetate film was also used as the base for magnetic tape, prior to the advent of polyester film.

Magnetic tape

Cellulose acetate magnetic tape was introduced by IBM in 1952 for use on their IBM 726 tape drive in the IBM 701 computer. It was much lighter and easier to handle than the metal tape introduced by UNIVAC in 1951 for use on their UNISERVO tape drive in the UNIVAC I computer. In 1956, cellulose acetate magnetic tape was replaced by the more stable PET film magnetic tape for use on their IBM 727 tape drive.

Other products

Apparel: buttons, linings, blouses, dresses, wedding and party attire, home furnishings, draperies, upholstery and slip covers.
Eyeglass frames are commonly made with cellulose acetate.
Industrial uses: cigarette filters and other filters, ink reservoirs for fiber tip pens.
High absorbency products: diapers and medical aid products.
The original Lego bricks were manufactured from cellulose acetate from 1949 to 1963.
Award Ribbon: Rosettes for equestrian events, dog/cat shows, corporate awards, advertising and identification products all use cellulose acetate ribbon.
Playing cards may be made of cellulose acetate.
Toys
Transparencies for overhead projection

Production

The Federal Trade Commission definition for acetate fiber is: "A manufactured fiber in which the fiber-forming substance is cellulose acetate. Where not less than 92 percent of the hydroxyl groups are acetylated, the term triacetate may be used as a generic description of the fiber."

Acetate is derived from cellulose by initially deconstructing wood pulp into a purified fluffy white cellulose. To manufacture a good product, special qualities of pulps, such as dissolving pulps, are used. The uneven reactivity of cellulose presents a common problem affecting the quality of the cellulose acetate product. The cellulose is reacted with acetic acid and acetic anhydride in the presence of sulfuric acid. It is subjected to a controlled, partial hydrolysis to remove the sulfate and a sufficient number of acetate groups to give the product the desired properties. The anhydroglucose unit is the fundamental repeating structure of cellulose and has three hydroxyl groups which can react to form acetate esters. The most common form of cellulose acetate fiber has an acetate group on approximately two of every three hydroxyls. This cellulose diacetate is known as secondary acetate, or simply as "acetate".

After it is formed, cellulose acetate is dissolved in acetone, forming a viscous solution for extrusion through spinnerets (which resemble a shower head). As the filaments emerge, the solvent is evaporated in warm air via dry spinning, producing fine cellulose acetate fibers.

The first U.S. commercial acetate fiber was produced by the Celanese Corporation in 1924. Current U.S. acetate fiber producers are Celanese, and Eastman Chemical Company.

Method

To this day, no process for the direct production of cellulose acetates has been discovered. As attempts to produce a partial esterification of cellulose result only in a mixture of non-acetylated and fully acetylated cellulose, a two-step synthesis is applied: Cellulose is always completely converted first to cellulose triacetate and then by hydrolysis into cellulose acetates with low degrees of esterification.

Purified cellulose from wood pulp or cotton linters is mixed with glacial acetic acid, acetic anhydride, and a catalyst. The mixture is aged 20 hours during which partial hydrolysis occurs and acid resin precipitates as flakes. These are dissolved in acetone and the solution is purified by filtering. The solution is extruded by spinning in a column of warm air. Solvent is recovered. Filaments are stretched and wound onto beams, cones, or bobbins ready for use. Filaments are finally spun into fiber.

The production is divided into the following process stages:^[12]^[13]^[14]

Mechanical conditioning of the pulp: The pulp, which is usually provided as roll or sheet pulp, is fibrillated by means of different types of shredders, such as hammermills and disk refiners, whereby the successive arrangement of both types of shredder ensures optimum dissolving.
Chemical pre-treatment: The fibrillated cellulose is treated with acetic acid (if necessary with the addition of small quantities of sulphuric acid) with moderate stirring at 25 °C to 50 °C for about 1 h, resulting in continuous evaporation and condensation of the acetic acid in the spaces between the fibre particles. This causes the cellulose particles to swell, which facilitates the diffusion of the solvent particles into these particles during the following process stage. In addition to this acetic acid vapour pretreatment, there is also a pretreatment in a thin-pulp state. In this process, the cellulose is introduced into large quantities of water or diluted acetic acid and intensively stirred. Subsequent process steps such as pressing or centrifuging constantly increase the concentration of cellulose in the pulp. At the same time, acetic acid is added in ever higher concentrations. The advantage of this process is the saving of shredding, as the cellulose layers can be added directly into the stirred tank.
Acetylating the cellulose: In the commercial production of cellulose acetates, the acetic acid process or the methylene chloride process are usually used for acetylation. In acetic acid processes, the pre-treated cellulose mass is reacted in an acetylation mixture of the solvent acetic acid with an excess of acetic anhydride, which serves as an esterification agent, and with sulphuric acid as a catalyst under vigorous mechanical mixing. The reaction is highly exothermic and therefore intensive cooling of the reaction vessels is required. The esterification process is terminated by adding water when a highly viscous clear reaction mixture has formed from the fibrous pulp. This solution must be gel-free and have the desired viscosity. In the methylene chloride process, methylene chloride is used in the acetylation mixture as a solvent instead of acetic acid. Since the low-boiling methylene chloride can be easily removed by distillation, process control is achieved even with highly viscous solutions. Even at low temperatures it can dissolve cellulose triacetate very well. A small amount of sulfuric acid can used as a catalyst, but often also perchloric acid. However, acetic acid is usually also formed as a by-product of the reaction, so that the solvent is ultimately a mixture of methylene chloride, acetic anhydride and acetic acid. A very rare heterogeneous process is the fiber acetate process, which is only used for the production of cellulose triacetate as an end product. In this process, the cellulose is suspended in a non-solvent (such as benzene) and esterified with acetic anhydride in the presence of perchloric acid as catalyst.
Partial hydrolysis: To obtain the desired secondary cellulose acetate types, the cellulose triacetate is obtained by hydrolysis. For this purpose, the triacetate solution is heated to usually 60 to 80 °C in the presence of an acid catalyst (usually sulfuric acid) by adding water upon stirring and heating. The hydrolysis is controlled by the concentration of the sulfuric acid, the amount of water and the temperature in such a way that the desired molecular degradation (chain scission) is achieved. The hydrolysis process is then stopped by adding basic salts (e.g. sodium or magnesium acetate) which neutralize the acid catalyst.
Precipitation of the cellulose acetate: When precipitating cellulose acetate from the reaction solution using dilute acetic acid, it is important to obtain uniform and easily washable cellulose acetate flakes. Before precipitation, any methylene chloride present must be completely distilled off. The acetic acid is then recovered.
Washing and drying: By intensive washing, which is usually done in countercurrent, the acetic acid must be removed from the flakes down to the smallest traces, otherwise damage ("charring") will occur during the drying process. After the washing liquid has been pressed off, the flakes are dried on a conveyor belt dryer through which hot air flows to a residual moisture content of approx. 2-5%. For the subsequent production of very high-quality, thermally stable, brightly colored and color-stable thermoplastic molding compounds, the cellulose acetate flakes are also bleached and stabilized in additional process steps (to minimize thermal degradation and discoloration) before final drying.
Mixing of the flakes: The final steps are similar to the processing of other plastics: Before the cellulose acetate flakes are transported to a collection container from where they are transported to the appropriate processing plants, the flakes are mixed in a precisely controlled manner. This is to compensate for deviations of the cellulose acetates from different production batches. For many further processing steps the flakes are usually ground into fine powders beforehand. In order to be able to use the cellulose acetate in plastics processing methods such as injection moulding, the powder must also be mixed with suitable plasticisers and other additives, such as functional additives for thermal, weathering, UV and IR stabilisation.^[15] The mixtures can be adapted to the corresponding subsequent processing requirements. From the compound produced by melting, granules are produced which can be delivered to the plastics processors.

Disposal and degradation

The global production of CA materials was over 800,000 tonnes (790,000 long tons; 880,000 short tons) per year in 2008. While it was initially believed that CA was virtually non-biodegradable, it has been shown that after initial partial deacetylation, the polymer's cellulose backbone is readily biodegraded by cellulase enzymes. In biologically highly active soil, CA fibers are completely destroyed after 4–9 months. Photodegradation is optimal with 280 nm or shorter wavelength UV-irradiation and enhanced by TiO₂ pigment.^[16] CA cigarette filters take years to be broken down in the open.^[17]^[18]

Trade names

Cellulose acetate is marketed under various trade names, such as Tenite by the Eastman Chemical Company, zyl and zylonite,^[2] Cellon, manufactured by Deutsche Celluloid Fabrik, Eilenburg, Germany,^[19] and Rhodoid, manufactured by Soc. des Usines Chim. Rhone-Poulenc, Paris, France, and May & Baker Ltd., London, UK.^[19] Cast film of cellulose acetate is manufactured in Spondon (Derbyshire, UK) by Celanese, and sold as Clarifoil. ^[20]^{[ citation needed ]}

Other cellulose esters

Cellulose acetate butyrate (CAB, Tenite II) and cellulose acetate propionate are related derivatives of cellulose, which are both used in inks and coatings. The chief difference between these and cellulose acetate is their solubility in a wider range of solvents.

Related Research Articles

In chemistry, a salt is a chemical compound consisting of an ionic assembly of positively charged cations and negatively charged anions, which results in a compound with no net electric charge. A common example is table salt, with positively charged sodium ions and negatively charged chloride ions.

<span class="mw-page-title-main">Nitrocellulose</span> Highly flammable compound

Nitrocellulose is a highly flammable compound formed by nitrating cellulose through exposure to a mixture of nitric acid and sulfuric acid. One of its first major uses was as guncotton, a replacement for gunpowder as propellant in firearms. It was also used to replace gunpowder as a low-order explosive in mining and other applications. In the form of collodion it was also a critical component in an early photographic emulsion, the use of which revolutionized photography in the 1860s.

Rayon, also called viscose and commercialised in some countries as sabra silk or cactus silk, is a semi-synthetic fiber, made from natural sources of regenerated cellulose, such as wood and related agricultural products. It has the same molecular structure as cellulose. Many types and grades of viscose fibers and films exist. Some imitate the feel and texture of natural fibers such as silk, wool, cotton, and linen. The types that resemble silk are often called artificial silk. It is used to make textiles for clothing and other purposes.

Phthalic anhydride is the organic compound with the formula C₆H₄(CO)₂O. It is the anhydride of phthalic acid. Phthalic anhydride is a principal commercial form of phthalic acid. It was the first anhydride of a dicarboxylic acid to be used commercially. This white solid is an important industrial chemical, especially for the large-scale production of plasticizers for plastics. In 2000, the worldwide production volume was estimated to be about 3 million tonnes per year.

Lyocell is a semi-synthetic fiber used to make textiles for clothing and other purposes. It is a form of regenerated cellulose made by dissolving pulp and dry jet-wet spinning. Unlike rayon made by some of the more common viscose processes, Lyocell production does not use carbon disulfide, which is toxic to workers and the environment. Lyocell was originally trademarked as Tencel in 1982.

In chemistry, acetylation is an organic esterification reaction with acetic acid. It introduces an acetyl group into a chemical compound. Such compounds are termed acetate esters or simply acetates. Deacetylation is the opposite reaction, the removal of an acetyl group from a chemical compound.

Acetic anhydride, or ethanoic anhydride, is the chemical compound with the formula (CH₃CO)₂O. Commonly abbreviated Ac₂O, it is the simplest isolable anhydride of a carboxylic acid and is widely used as a reagent in organic synthesis. It is a colorless liquid that smells strongly of acetic acid, which is formed by its reaction with moisture in the air.

Cellulose triacetate, triacetate, CTA or TAC is a chemical compound produced from cellulose and a source of acetate esters, typically acetic anhydride. Triacetate is commonly used for the creation of fibres and film base. It is chemically similar to cellulose acetate. Its distinguishing characteristic is that in triacetate, at least "92 percent of the hydroxyl groups are acetylated." During the manufacture of triacetate, the cellulose is completely acetylated; whereas in normal cellulose acetate or cellulose diacetate, it is only partially acetylated. Triacetate is significantly more heat resistant than cellulose acetate.

Vinegar syndrome, also known as acetic acid syndrome, is a condition created by the deacetylation of cellulose acetates and cellulose triacetate. This deacetylation produces acetic acid, giving off a vinegar odor that gives the condition its name; as well, objects undergoing vinegar syndrome often shrink, become brittle, and form crystals on their surface due to the migration of plasticizers. Vinegar syndrome widely affects cellulose acetate film as used in photography. It has also been observed to affect older magnetic tape, where cellulose acetate is used as a base, as well as polarizers used in liquid-crystal display units and everyday plastics such as containers and tableware. High temperatures and fluctuations in relative humidity have been observed to accelerate the process. The process is autocatalytic, and the damage done by vinegar syndrome is irreversible.

<span class="mw-page-title-main">Dimethylacetamide</span> Chemical compound

Dimethylacetamide (DMAc or DMA) is the organic compound with the formula CH₃C(O)N(CH₃)₂. This colorless, water-miscible, high-boiling liquid is commonly used as a polar solvent in organic synthesis. DMA is miscible with most other solvents, although it is poorly soluble in aliphatic hydrocarbons.

Aluminium acetate or aluminium ethanoate (also "aluminum ~"), sometimes abbreviated AlAc in geochemistry, can refer to a number of different salts of aluminium with acetic acid. In the solid state, three salts exist under this name: basic aluminium monoacetate, (HO)₂AlCH₃CO_2, basic aluminium diacetate, HOAl(CH₃CO₂)₂, and neutral aluminium triacetate, Al(CH₃CO₂)_3. In aqueous solution, aluminium triacetate hydrolyses to form a mixture of the other two, and all solutions of all three can be referred to as "aluminium acetate" as the species formed co-exist and inter-convert in chemical equilibrium.

<span class="mw-page-title-main">Cellulose acetate phthalate</span> Chemical compound

Cellulose acetate phthalate (CAP), also known as cellacefate (INN) and cellulosi acetas phthalas, is a commonly used polymer phthalate in the formulation of pharmaceuticals, such as the enteric coating of tablets or capsules and for controlled release formulations. It is a cellulose polymer where about half of the hydroxyls are esterified with acetyls, a quarter are esterified with one or two carboxyls of a phthalic acid, and the remainder are unchanged. It is a hygroscopic white to off-white free-flowing powder, granules, or flakes. It is tasteless and odorless, though may have a weak odor of acetic acid. Its main use in pharmaceutics is with enteric formulations. It can be used together with other coating agents, e.g. ethyl cellulose. Cellulose acetate phthalate is commonly plasticized with diethyl phthalate, a hydrophobic compound, or triethyl citrate, a hydrophilic compound; other compatible plasticizers are various phthalates, triacetin, dibutyl tartrate, glycerol, propylene glycol, tripropionin, triacetin citrate, acetylated monoglycerides, etc.

Cellulose acetate film, or safety film, is used in photography as a base material for photographic emulsions. It was introduced in the early 20th century by film manufacturers and intended as a safe film base replacement for unstable and highly flammable nitrate film.

Acetic acid, systematically named ethanoic acid, is an acidic, colourless liquid and organic compound with the chemical formula CH₃COOH. Vinegar is at least 4% acetic acid by volume, making acetic acid the main component of vinegar apart from water and trace elements.

Dissolving pulp, also called dissolving cellulose, is bleached wood pulp or cotton linters that has a high cellulose content. It has special properties including a high level of brightness and uniform molecular-weight distribution. This pulp is manufactured for uses that require a high chemical purity, and particularly low hemicellulose content, since the chemically similar hemicellulose can interfere with subsequent processes. Dissolving pulp is so named because it is not made into paper, but dissolved either in a solvent or by derivatization into a homogeneous solution, which makes it completely chemically accessible and removes any remaining fibrous structure. Once dissolved, it can be spun into textile fibers, or chemically reacted to produce derivatized celluloses, such cellulose triacetate, a plastic-like material formed into fibers or films, or cellulose ethers such as methyl cellulose, used as a thickener.

Aluminium diacetate, also known as basic aluminium acetate, is a white powder with the chemical formula C₄H₇AlO₅. It is one of a number of aluminium acetates and can be prepared in a reaction of sodium aluminate (NaAlO₂) with acetic acid.

Cellulose diacetate, sometimes called diacetate, is a synthetic polymer made by treating cellulose with acetic acid. It consists of two acetyl functional groups on each unit of D-anhydroglucopyranose of the cellulose molecule. It was first developed in the United States.

Wet Processing Engineering is one of the major streams in Textile Engineering or Textile manufacturing which refers to the engineering of textile chemical processes and associated applied science. The other three streams in textile engineering are yarn engineering, fabric engineering, and apparel engineering. The processes of this stream are involved or carried out in an aqueous stage. Hence, it is called a wet process which usually covers pre-treatment, dyeing, printing, and finishing.

<span class="mw-page-title-main">Camille Dreyfus (chemist)</span> Swiss chemist (1878–1956)

Camille Edouard Dreyfus was a Swiss chemist. He and his brother Henri Dreyfus invented Celanese, an acetate yarn. He founded The Camille and Henry Dreyfus Foundation in honour of his brother.

Aluminium triacetate, formally named aluminium acetate, is a chemical compound with composition Al(CH^₃CO^₂)^₃. Under standard conditions it appears as a white, water-soluble solid that decomposes on heating at around 200 °C. The triacetate hydrolyses to a mixture of basic hydroxide / acetate salts, and multiple species co-exist in chemical equilibrium, particularly in aqueous solutions of the acetate ion; the name aluminium acetate is commonly used for this mixed system.

References

↑ ^{[ citation needed ]}
1 2 3 4 Morgan, Erinn (May 2018). "Eyeglass Frame Materials". All About Vision. Retrieved August 7, 2013.
↑ Meade, Richard Kidder; McCormack, Harry; Clark, Laurance T.; Sclater, Alexander G.; Lamborn, Lloyd (1905). Chemical Age. Vol. 3. McCready Publishing Company.
1 2 3 4 Morris, Peter John Turnbull (1989). The American Synthetic Rubber Research Program. University of Pennsylvania Press. p. 258. ISBN 978-0-8122-8207-8.
↑ Fabric Information: Acetate & Viscose, NY Fashion Center Fabrics. Archived August 26, 2013, at the Wayback Machine
↑ trade names Archived October 28, 2008, at the Wayback Machine
↑ "Rayon and Acetate Fabrics to be Separately Labelled in Future". The Southeast Missourian . February 12, 1952. Retrieved December 25, 2013.
1 2 "Synthetic Fabrics in Menswear – Rayon and Acetate". Real Men Real Style. 2010-09-20. Archived from the original on November 5, 2012.
↑ "Fiber Characteristics | Acetate". Fabric Link. Archived from the original on September 25, 2013.
↑ "Acetate Fabric". Wedding Shoppe, Inc.
↑ "Acetate". Swicofil. Retrieved October 10, 2011.
↑ Menachem Lewin (Hrsg.): Handbook of Fiber Chemistry. Third Edition. Taylor & Francis Group, Boca Raton 2007, ISBN 0-8247-2565-4, S. 778–784.
↑ Ludwig Bottenbruch (Hrsg.): Kunststoff-Handbuch 3/1 – Technische Thermoplaste: Polycarbonate, Polyacetate, Polyester, Celluloseester. Carl Hanser Verlag, München/Wien 1992. ISBN 3-446-16368-9, S. 404–408
↑ Zakhar Aleksandrovič Rogowin: Chemiefasern: Chemie – Technologie. Georg Thieme Verlag, Stuttgart / New York 1982, ISBN 3-13-609501-4, S. 182–186.
↑ Hans Domininghaus (Hrsg.): Die Kunststoffe und ihre Eigenschaften. 6., neu bearbeitete und erweiterte Auflage, Springer-Verlag, Berlin/Heidelberg 2005, ISBN 3-540-21410-0, S. 1461
↑ Puls, Juergen; Wilson, Steven A.; Hölter, Dirk (2011). "Degradation of Cellulose Acetate-Based Materials: A Review". Journal of Polymers and the Environment. 19 (1): 152–165. doi: 10.1007/s10924-010-0258-0 .
↑ Mulvihill, Marty; Hessler, Wendy (August 14, 2012). "No more butts: biodegradable filters a step to boot litter problem". Environmental Health News. Archived from the original on November 29, 2014. Retrieved November 25, 2014.
↑ Robertson, Raymond M.; Thomas, William C.; Suthar, Jitendrakumar N.; Brown, David M. (August 2012). "Accelerated degradation of cellulose acetate cigarette filters using controlled-release acid catalysis". Green Chemistry . 14 (8): 2266–2272. doi:10.1039/C2GC16635F.
1 2 "Welcome to The Plastics Historical Society". Plastics Historical Society . Retrieved 30 May 2018.
↑ JSC "DP acetate DP acetate produce cellulose acetate yarns from 1965 "

Schützenberger, P. "Action de l'acide acétique anhydre sur la cellulose, l'amidon, les sucres, la mannite et ses congénères, les glucosides et certaines matières colorantes végétales." Compt. Rend. Hebd. Séances Acad. Sci 61 (1865): 484-487.

External links

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[1] {[ citation needed ]}

[allaboutvision.com-2] 1 2 3 4 Morgan, Erinn (May 2018). "Eyeglass Frame Materials". All About Vision. Retrieved August 7, 2013.

[3] Meade, Richard Kidder; McCormack, Harry; Clark, Laurance T.; Sclater, Alexander G.; Lamborn, Lloyd (1905). Chemical Age. Vol. 3. McCready Publishing Company.

[:0-4] 1 2 3 4 Morris, Peter John Turnbull (1989). The American Synthetic Rubber Research Program. University of Pennsylvania Press. p. 258. ISBN 978-0-8122-8207-8.

[NYFashion-5] Fabric Information: Acetate & Viscose, NY Fashion Center Fabrics. Archived August 26, 2013, at the Wayback Machine

[6] trade names Archived October 28, 2008, at the Wayback Machine

[7] "Rayon and Acetate Fabrics to be Separately Labelled in Future". The Southeast Missourian . February 12, 1952. Retrieved December 25, 2013.

[:1-8] 1 2 "Synthetic Fabrics in Menswear – Rayon and Acetate". Real Men Real Style. 2010-09-20. Archived from the original on November 5, 2012.

[9] "Fiber Characteristics | Acetate". Fabric Link. Archived from the original on September 25, 2013.

[10] "Acetate Fabric". Wedding Shoppe, Inc.

[11] "Acetate". Swicofil. Retrieved October 10, 2011.

[12] Menachem Lewin (Hrsg.): Handbook of Fiber Chemistry. Third Edition. Taylor & Francis Group, Boca Raton 2007, ISBN 0-8247-2565-4, S. 778–784.

[13] Ludwig Bottenbruch (Hrsg.): Kunststoff-Handbuch 3/1 – Technische Thermoplaste: Polycarbonate, Polyacetate, Polyester, Celluloseester. Carl Hanser Verlag, München/Wien 1992. ISBN 3-446-16368-9, S. 404–408

[14] Zakhar Aleksandrovič Rogowin: Chemiefasern: Chemie – Technologie. Georg Thieme Verlag, Stuttgart / New York 1982, ISBN 3-13-609501-4, S. 182–186.

[15] Hans Domininghaus (Hrsg.): Die Kunststoffe und ihre Eigenschaften. 6., neu bearbeitete und erweiterte Auflage, Springer-Verlag, Berlin/Heidelberg 2005, ISBN 3-540-21410-0, S. 1461

[16] Puls, Juergen; Wilson, Steven A.; Hölter, Dirk (2011). "Degradation of Cellulose Acetate-Based Materials: A Review". Journal of Polymers and the Environment. 19 (1): 152–165. doi: 10.1007/s10924-010-0258-0 .

[17] Mulvihill, Marty; Hessler, Wendy (August 14, 2012). "No more butts: biodegradable filters a step to boot litter problem". Environmental Health News. Archived from the original on November 29, 2014. Retrieved November 25, 2014.

[18] Robertson, Raymond M.; Thomas, William C.; Suthar, Jitendrakumar N.; Brown, David M. (August 2012). "Accelerated degradation of cellulose acetate cigarette filters using controlled-release acid catalysis". Green Chemistry . 14 (8): 2266–2272. doi:10.1039/C2GC16635F.

[PQ-19] 1 2 "Welcome to The Plastics Historical Society". Plastics Historical Society . Retrieved 30 May 2018.

[20] JSC "DP acetate DP acetate produce cellulose acetate yarns from 1965 "

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