Styrenic thermoplastic elastomers.Styrenic block copolymers were first commercialized in 1965 by Shell Chemical (ref. 1). The first commercial market was footwear, but in the last 30+ years styrenic block copolymers have branched out into several different market areas. Today, over a billion pounds per year of styrenic block copolymers are manufactured worldwide by more than 15 different companies. Some of the application areas include modified asphalts (roads and roofing), adhesives/sealants, thermoplastic A polymer material that turns to liquid when heated and becomes solid when cooled. There are more than 40 types of thermoplastics, including acrylic, polypropylene, polycarbonate and polyethylene. rubber compounds and impact modification. Block copolymer copolymer: see polymer. synthesis Styrenic block copolymers owe their success to a unique block structure. The key to the structure is the "living" anionic an·i·on n. A negatively charged ion, especially the ion that migrates to an anode in electrolysis. [From Greek, neuter present participle of anienai, to go up : ana-, ana- synthesis chemistry used in the manufacturing process. Figure 1 shows the steps used to make a block copolymer (ref. 2). Typically, the polymerization polymerization Any process in which monomers combine chemically to produce a polymer. The monomer molecules—which in the polymer usually number from at least 100 to many thousands—may or may not all be the same. begins by adding a very pure styrene sty·rene n. A colorless oily liquid from which polystyrenes, plastics, and synthetic rubber are produced. Also called vinylbenzene. monomer monomer (mŏn`əmər): see polymer. monomer Molecule of any of a class of mostly organic compounds that can react with other molecules of the same or other compounds to form very large molecules (polymers). to an alkyl alkyl /al·kyl/ (al´k'l) the monovalent radical formed when an aliphatic hydrocarbon loses one hydrogen atom. al·kyl n. lithium catalyst in an appropriate solvent. This catalyst system has the property of polymerizing monomer units at a very uniform rate in each of the polymer chains. In addition, it does not die or undergo any side reactions. The catalyst site remains "living" at the end of the polymer chain as long as water and other chain terminating agents are excluded from the reactor. The reaction continues until all of the styrene monomer is consumed. Thus linear polymer chains of polystyrene (S) are formed which have the same molecular weight. Secondly, all of the chains have "living reactive chain ends." The next sequence of the reaction starts by adding a new monomer such as isoprene isoprene or 2-methyl-1,3-butadiene (ī`səprēn, by  'tədī`ēn), colorless liquid organic compound. (I) or butadiene (B). The diene Dienes are hydrocarbons which contain two double bonds. Dienes are intermediate between alkenes and polyenes. ClassesDienes can be divided into three classes:
[Figure 1 ILLUSTRATION OMITTED] The diene blocks, such as polyisoprene and polybutadiene are elastomeric and still contain unsaturated unsaturated /un·sat·u·rat·ed/ (un-sach´ur-at?ed) 1. not holding all of a solute which can be held in solution by the solvent. 2. denoting compounds in which two or more atoms are united by double or triple bonds. double bonds. The SIS and SBS See Small Business Server. polymers can then be subjected to a further chemical reaction that selectively hydrogenates the double bonds in the diene elastomer elastomer (ĭlăs`təmər), substance having to some extent the elastic properties of natural rubber. The term is sometimes used technically to distinguish synthetic rubbers and rubberlike plastics from natural rubber. and leaves the polystyrene endblocks unchanged. Thus, SEBS (styrene-ethylene/butylenestyrene) and SEPS SEPS Subfascial Endoscopic perforator Surgery SEPS Shortstop Electronic Protection System SEPS Styrene-Ethylene-Propylene-Styrene SEPS Southeastern Pharmacology Society SEPS Standard Electronic Processing System SEPS Sprint Email Protection Services (styrene-ethylene/propylene-styrene) polymers can be formed which have outstanding UV and thermal stability. The SEBS or SEPS polymers can be reacted further by grafting monomers such as maleic anhydride Maleic anhydride (cis-butenedioic anhydride, toxilic anhydride, dihydro-2,5-dioxofuran) is an organic compound with the formula C4H2O3 (C=OCH=CHC=O2). In its pure state it is a colourless or white solid with an acrid odour. onto the rubber block of the molecule. Physical properties The block structure is what creates the unique properties of these polymers. The polystyrene blocks are incompatible with the elastomeric diene segments and, therefore, they phase separate on a microscopic scale, like oil and water. The resulting structure looks like a meatballs and spaghetti structure with the styrene segments forming hard spherical domains and the elastomeric segments linking the styrene domains into a three-dimensional structure (ref. 3). The styrene domains are hard and glassy and form physical crosslinks for binding the molecules together to form a strong, elastic network. The tensile strength tensile strength Ratio of the maximum load a material can support without fracture when being stretched to the original area of a cross section of the material. When stresses less than the tensile strength are removed, a material completely or partially returns to its of the block copolymers can be as high as 20-35 MPa. This is greater than most chemically crosslinked elastomers. For many applications, this means the block copolymers can be very highly extended with oils, tackifying resins or other polymers and still have excellent strength. The beauty of the styrene blocks is that they retain their strength up to temperatures near the glass transition of polystyrene (about 95 [degrees] C). At this point, the domain softens and the copolymer will flow like any thermoplastic polymer. When the block copolymer is cooled, the hard polystyrene domains reform and the strength returns. The reforming process is so quick that hot melt adhesive coating lines can be run in excess of 5 m/sec. Processing can also be achieved by dissolving the block copolymer in a solvent that will solvate Noun 1. solvate - a compound formed by solvation (the combination of solvent molecules with molecules or ions of the solute) chemical compound, compound - (chemistry) a substance formed by chemical union of two or more elements or ingredients in definite proportion both phases. Since the block copolymers are only about 100,000 in molecular weight versus other conventional elastomers like natural rubber (1,000,000 molecular weight), the solution viscosity of the block copolymer is relatively low. Adhesive formulations with high solids levels (50%+) can easily be achieved. By comparison, natural rubber adhesive solutions are typically limited to 25-35% solids. In addition, the block copolymers will regain their strength once the solvent is evaporated. No time consuming and complicated chemical crosslinking steps are required as is commonly practiced with natural rubber or other elastomers. Formulating The uniqueness of the block copolymer structure extends beyond processing. The two-phase structure gives the formulator two phases to modify to achieve an appropriate balance of elastic properties. For instance, oils and resins can be added to the elastomeric midblock phase to soften or even tackify the polymer. Aromatic endblock resins can be added to the polystyrene endblock regions to harden and strengthen compounds. Other polymeric materials can also be blended with the block copolymers to form interpenetrating networks and technologically useful mixtures. Features of the block copolymers Besides being strong, highly extendible, cost effective, processable and easily formulated into a variety of compounds or adhesives, the styrenic block copolymers have other attributes that are very beneficial (table 1). The polymerization chemistry requires that the systems and chemicals are very clean and pure. This results in FDA FDA abbr. Food and Drug Administration FDA, n.pr See Food and Drug Administration. FDA, n.pr the abbreviation for the Food and Drug Administration. approval for many of the products. The polymers are clear (the styrene domains are too small to scatter light) and can be formulated into transparent elastomeric products. The specific gravity specific gravity, ratio of the weight of a given volume of a substance to the weight of an equal volume of some reference substance, or, equivalently, the ratio of the masses of equal volumes of the two substances. of the block copolymers is around 0.94 and is even less when formulated with appropriate ingredients. This can be important for paper recycling Paper recycling is the process of recovering waste paper and remaking it into new paper products. There are three categories of paper that can be used as feedstocks for making recycled paper: mill broke, pre-consumer waste, and post-consumer waste. processes that separate ingredients based on density (ref. 4). The polymers have good resistance to acids and bases and can even be used in dispensing systems for battery acid. For applications requiring good UV and oxidative resistance, the hydrogenated styrenic polymers are particularly useful. For increased adhesion or compatibility with polar materials such as polyamides or polyesters, maleated block copolymers such as SEBS-MA 1901 (table 2) can be employed (ref. 5). Table 1 - features and benefits
General styrenic block copolymers
No vulcanization required - high processing speeds
Precise molecules - wide range of structure
Clean - FDA approved
High strength - highly extendable
Low viscosity - high solids
Hot melt or solvent applied
Wide formulating latitude - two phases to modify
Clear
Aggressive adhesion to polyolefins
Low density - aids recycling
Cohesive strength adjustable with diblock content
Electrically insulating
Resistant to acids and bases
Free flowing pellets/powder - no mastication required
Table 2 - characteristics of various styrenic block copolymers
Polymer Commercial
designation
SBS 1101 Kraton D 1101(*)
SBS 1102 Kraton D 1102
SEBS 1650 Kraton G 1650
SEBS 1651 Kraton G 1651
SEBS 1652 Kraton G 1652
SEP 1702 Kraton G 1702
SEBS-MA 1901 Kraton FG 1901X
[(SB).sub.2]-x-[(B).sub.2] KX-222(*)
[(SEB).sub.2]-x-[(I).sub.2] RP-6919(*)
el-EB-OH L-207(*)
Polymer Description
SBS 1101 31% styrene, SBS
SBS 1102 28% styrene, SBS
SEBS 1650 30% styrene, SEBS
SEBS 1651 33% styrene, SEBS
SEBS 1652 30% styrene, SEBS
SEP 1702 28% styrene, SEP diblock
SEBS-MA 1901 30% styrene, SEBS with
1.7 wt% maleic anhydride
[(SB).sub.2]-x-[(B).sub.2] 18% styrene, dissimilar
arm styrene-butadiene
block copolymer where
the polybutadiene has
high levels of 1,2 polybutadiene
[(SEB).sub.2]-x-[(I).sub.2] 18% styrene, 36% isoprene,
dissimilar arm
styrene, ethylene/butylene,
isoprene block
copolymer
el-EB-OH Poly(ethylene/butylene)
rubber with 11 epoxy units
and a primary hydroxyl
(*) Shell Chemical Application areas Modified asphalts Asphalt materials are typically used in the roads and roofing industry. Asphalts are conventionally "oxidized oxidized having been modified by the process of oxidation. oxidized cellulose see absorbable cellulose. " or "blown" to improve their high temperature properties so they can be used on sloped roofs or roads that will not rut in hot climates. This process, however, compromises or severely limits the low temperature properties. The addition of 3-20% styrenic block copolymer to an unblown asphalt will significantly improve the high temperature flow properties and elasticity of the asphalt, while at the same time improving the low temperature properties (figure 2). Thus, the service temperature range of asphalts can be expanded. Rutting and low temperature cracking can be improved in roads, fatigue and low temperature cracking can be improved in roofing, and road crack sealants will have improved thermal cycling and seasonal durability. In addition, the modified asphalt can be processed like a conventional asphalt at 125-200 [degrees] C in roll roofing lines, road paving, mopping asphalts, road crack sealants or shingle manufacturing lines. [Figure 2 ILLUSTRATION OMITTED] Adhesives The high tensile strength and two phase structure of the styrenic block copolymers allow them to be formulated with tackifying resins, oils, aromatic endblock resins and fillers to make a wide spectrum of adhesive products. These products can vary from pressure sensitive tape or labels, to assembly adhesives, to construction adhesives for plywood paneling. The FDA clearances and high-speed thermoplastic processing makes them ideally suited for diaper assembly and adhesives for personal care products. The key to many adhesive applications is to carefully formulate the rheological rhe·ol·o·gy n. The study of the deformation and flow of matter. rhe  o·log properties of the adhesive or sealant SealantA thin plastic substance that is painted over teeth as an anti-cavity measure to seal out food particles and acids produced by bacteria. Mentioned in: Tooth Decay sealant see bone sealant. to achieve the correct balance of properties. Label and sealant applications can benefit from using diblock copolymers in combination with triblock copolymers to achieve higher peel values, better die cuttability and lower cohesive strength. Thus, sealants can be made to fail cohesively instead of adhesively. Oils can be modified with as little as 5-15% of hydrogenated block copolymers to make elastomeric water proofing sealants or cable filling oil gels. Compounds As mentioned previously, the styrenic block copolymers can be combined with oils, fillers, polyolefins and other polymeric materials to achieve a wide spectrum of elastomeric properties, while still maintaining good processability. Special FDA clearances allow it to be used in many food applications, such as milk tubing. The good electrical insulating properties and aging properties of the hydrogenated block copolymers allow them to be formulated into many different hardness grades, which can meet stringent UL wire and cable ratings. The low density, low temperature flexibility, high strength and the economical thermoplastic processing make SBS compounds ideal for thick soled shoes and casual sneakers sneakers Noun, pl US, Canad, Austral & NZ canvas shoes with rubber soles sneakers npl (US) → zapatos mpl de lona; zapatillas fpl . Because of the high strength of the styrenic block copolymers, highly extended and very soft elastomeric compounds are also possible. Polymer modification Styrenic block copolymers are ideally suited for impact modifying styrenics and polyphenylene ether polymers (figure 3). The hydrogenated block copolymers, because of their olefinic character (EB or EP rubber midblock), work well for modifying polyolefins (table 3), such as polyethylene, polypropylene or polybutylene, while maintaining good clarity and flow. Submicron interpenetrating network structures are possible with polyolefins and the hydrogenated block copolymers. Polycarbonate A category of plastic materials used to make a myriad of products, including CDs and CD-ROMs. even benefits from the addition of small amounts of block copolymer to improve thick section impact and annealing annealing (ənēl`ĭng), process in which glass, metals, and other materials are treated to render them less brittle and more workable. properties (figure 4). With the advent of maleated block copolymers, polyamide polyamide material used in the creation of nonabsorbable, synthetic, nylon sutures. and polyester engineering thermoplastics can now be modified to improve impact strength (figure 5) (ref. 6). [Figure 3-5 ILLUSTRATION OMITTED]
Table 3 - polypropylene/block copolymer blends (80/20)
Polymer Room temperature Flexural Spiral flow
notched Izod impact modulus (m)
(J/m) (GPa)
SEBS 1652 560 889 0.62
SEBS 1650 678 945 0.57
SEBS 1651 224 855 --
SEP 1702 577 758
New developments The microstructure mi·cro·struc·ture n. The structure of an organism or object as revealed through microscopic examination. microstructure Noun a structure on a microscopic scale, such as that of a metal or a cell of the midblock of SBS and SIS polymers can be adjusted to yield polymers which have lower viscosities, higher reactivity and improved sound dampening properties (higher Tgs). A new [(SB).sub.2]-x-[(B).sub.2] polymer can be formulated into a hot melt pressure sensitive adhesive Pressure sensitive adhesive (PSA, self adhesive, self stick adhesive) is adhesive that forms a bond when pressure is applied to marry the adhesive with the adherend. No solvent, water, or heat is needed to activate the adhesive. that can be cured with UV light and a photoinitiator even in the presence of air (ref. 7). A new partially hydrogenated block copolymer [(SEB Noun 1. SEB - a form of staphylococcal enterotoxin that has been used as an incapacitating agent in biological warfare staphylococcal enterotoxin B ).sub.2]-x-[(I).sub.2] has been developed which manifests a unique balance of aging properties, crosslinkability and softness that is useful for PSA (Professional Services Automation) An information system designed to organize, track and manage all opportunities, work, resources, costs, revenues and invoices to improve the productivity and efficiency of the workforce. or compound applications (ref. 8). The newest generation of anionically synthesized block copolymers is opening opportunities in liquid reactive systems (figure 6). The polymer shown in figure 6 is less than 10,000 molecular weight and is an epoxidized polyisoprene-poly(ethylene/butylene) block copolymer with a terminal hydroxyl group hydroxyl group (hīdrŏk`sĭl), in chemistry, functional group that consists of an oxygen atom joined by a single bond to a hydrogen atom. An alcohol is formed when a hydroxyl group is joined by a single bond to an alkyl group or aryl group. (eI-EB-OH). The functional groups offer a host of new reactive possibilities and cationic cationic having qualities dependent on having free cations available. cationic detergents are wetting agents that disrupt or damage cell membranes, denature proteins and inactivate enzymes. curing mechanisms, which are useful in adhesive and polymer modification applications (refs. 9 and 10). [Figure 6 ILLUSTRATION OMITTED] Summary Styrenic block copolymers are an important segment of the elastomer industry. Their unique and precisely controlled molecular structure allows these elastomers to be tailored to a variety of applications. No other elastomer services such a wide diversity of application areas. From formulating, to processing, to choosing the appropriate molecular structure, styrenic block copolymers offer a wide vista of new properties and processing possibilities. References (1.) U.S. Patent 3,265,765. (2.) N.R. Legge, S. Davison, H.E. DeLaMare, G. Holden, M.K. Martin, Applied Polymer Science Polymer science or macromolecular science is the subfield of materials science concerned with polymers, primarily synthetic polymers such as plastics. The field of polymer science includes researchers in multiple disciplines including chemistry, physics, and engineering. , 2nd Ed. R.W. Tess and G.W. Poehlein, Eds. ACS (Asynchronous Communications Server) See network access server. Symposium Series No. 285, ch. 9, American Chemical Society The American Chemical Society (ACS) is a learned society (professional association) based in the United States that supports scientific inquiry in the field of chemistry. Founded in 1876 at New York University, the ACS currently has over 160,000 members at all degree-levels and in , Washington, D. C., 1985. (3.) J.T. Harlan, L.A. Petershagen, E.E. Ewins, G.A. Davies, Handbook of Adhesives, Irving Skeist, Ed., p. 239, Van Nostrand Reinhold, New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of , 1990. (4.) E.M. Wise, J.M. Arnold, Tappi Hot Melt Symposium, Tappi Press, 131 (1992). (5.) S.H. Dillman, A. Sanders, Tappi Hot Melt Symposium, Tappi Press, 39 (1989). (6.) R. Gelles, M. Modic, J. Kirkpatrick, Conference Proceedings for Society of Plastic Engineers 46th Annual Technical Conference, 513 (1988). (7.) M. DuPont, The Journal of the Adhesives and Sealants Council (Spring Symposium), 229 (1997). (8.) G.R. Himes, E.M. Loveday, Tappi Hot Melt Symposium, Tappi Press, 1 (1994). (9.) J.R. Erickson, E.M. Zimmermann, J.G. Southwick, K.S. Kiibler, Adhesives Age, November, 18 (1995). (10.) J.R. Erickson, P.A. Mancinelli, Proceedings of Pressure Sensitive Tape Council, 25 (1998).3 |
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