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Broad molecular weight

Three 7.5 mm i.d. X 300 mm PLgel 5 )iim Mixed-C columns (Polymer Laboratories, Amherst, MA) were thermostated to 30.0°C. Uninhibited tet-rahydrofuran (THF) at a nominal flowrate of 1.0 mL/min was used as the eluent. Narrow distribution polystyrene standards (Polymer Laboratories) were injected in a volume of 100 ijlL with concentrations ranging from 0.1 to 2.5 mg/mL, depending on molecular weight. Broad molecular-weight-distribution polystyrene 18,242-7 was obtained from Aldrich Chemical Company (Milwaukee, WI). Acetone, added to each sample at a concentration of 0.1%, was used as a flow marker. [Pg.129]

High molecular weight, broad MWD polymer—used primarily for blow moulding and pipe. [Pg.242]

As a result. In the anionic polymerization of lactones, low pol3rmer yield, uncontrollable molecular weight, broad distribution, coupling linkage, and cyclic ester oligomers contamination have been frequently encountered O In this paper, a new Improved process was revealed to eliminate such trensesterlflcatlons has been developed. Block copolymers with styrene and butadiene have been prepared and characterized by different techniques. [Pg.162]

Boiling-point separation of broad molecular weight range of compounds nonpolar phases ... [Pg.1098]

Polydisperse polymers do not yield sharp peaks in the detector output as indicated in Fig. 9.14. Instead, broad bands are produced which reflect the polydispersity of synthetic polymers. Assuming that suitable calibration data are available, we can construct molecular weight distributions from this kind of experimental data. An indication of how this is done is provided in the following example. [Pg.644]

These normal stresses are more pronounced for polymers with a very broad molecular weight distribution. Viscosities and viscoelastic behavior decrease with increasing temperature. In some cases a marked viscosity decrease with time is observed in solutions stored at constant temperature and 2ero shear. The decrease may be due to changes in polymer conformation. The rheological behavior of pure polyacrylamides over wide concentration ranges has been reviewed (5). [Pg.140]

Narrow, regular, and broad refer to molecular weight distribution. [Pg.316]

AH three processes give perfluoropolyethers with a broad distribution of molecular weights. They are typically separated into fractions by vacuum distillation. [Pg.298]

Hydrocarbon resin is a broad term that is usually used to describe a low molecular weight thermoplastic polymer synthesized via the thermal or catalytic polymerization of coal-tar fractions, cracked petroleum distillates, terpenes, or pure olefinic monomers. These resins are used extensively as modifiers in the hot melt and pressure sensitive adhesive industries. They are also used in numerous other appHcations such as sealants, printing inks, paints, plastics, road marking, carpet backing, flooring, and oil field appHcations. They are rarely used alone. [Pg.350]

Most hydrocarbon resins are composed of a mixture of monomers and are rather difficult to hiUy characterize on a molecular level. The characteristics of resins are typically defined by physical properties such as softening point, color, molecular weight, melt viscosity, and solubiHty parameter. These properties predict performance characteristics and are essential in designing resins for specific appHcations. Actual characterization techniques used to define the broad molecular properties of hydrocarbon resins are Fourier transform infrared spectroscopy (ftir), nuclear magnetic resonance spectroscopy (nmr), and differential scanning calorimetry (dsc). [Pg.350]

Molecular Weight Distribution. In industry, the MWD of PE resins is often represented by the value of the melt flow ratio (MER) as defined in Table 2. The MER value of PE is primarilly a function of catalyst type. Phillips catalysts produce PE resins with a broad MWD and their MER usually exceeds 100 Ziegler catalysts provide resins with a MWD of a medium width (MFR = 25-50) and metallocene catalysts produce PE resins with a narrow MWD (MFR = 15-25). IfPE resins with especially broad molecular weight distributions are needed, they can be produced either by using special mixed catalysts or in a series of coimected polymerization reactors operating under different reaction conditions. [Pg.369]

A wide variety of chromium oxide and Ziegler catalysts was developed for this process (61,62). Chromium-based catalysts produce HDPE with a relatively broad MWD other catalysts provide HDPE resins with low molecular weights (high melt indexes) and resins with a narrower MWD (63,64). [Pg.384]

Processes for HDPE with Broad MWD. Synthesis of HDPE with a relatively high molecular weight and a very broad MWD (broader than that of HDPE prepared with chromium oxide catalysts) can be achieved by two separate approaches. The first is to use mixed catalysts containing two types of active centers with widely different properties (50—55) the second is to employ two or more polymerization reactors in a series. In the second approach, polymerization conditions in each reactor are set drastically differendy in order to produce, within each polymer particle, an essential mixture of macromolecules with vasdy different molecular weights. Special plants, both slurry and gas-phase, can produce such resins (74,91—94). [Pg.387]

Molecular Weight. The range of molecular weights of commercial LLDPE resias is relatively narrow, usually from 50,000 to 200,000. One accepted parameter that relates to the resin molecular weight is the melt index, a rheological parameter which, broadly defined, is inversely proportional to molecular weight. A typical melt index range for LLDPE resias is from 0.1 to 5.0, but can reach over 30 for some appHcations. [Pg.394]

The width of molecular weight distribution (MWD) is usually represented by the ratio of the weight—average and the number—average molecular weights, MJM. In iadustry, MWD is often represented by the value of the melt flow ratio (MER), which is calculated as a ratio of two melt indexes measured at two melt pressures that differ by a factor of 10. Most commodity-grade LLDPE resias have a narrow MWD, with the MJM ratios of 2.5—4.5 and MER values in the 20—35 range. However, LLDPE resias produced with chromium oxide-based catalysts have a broad MWD, with M.Jof 10—35 and MER of 80-200. [Pg.394]

Chromium Oxide-Based Catalysts. Chromium oxide-based catalysts were originally developed by Phillips Petroleum Company for the manufacture of HDPE resins subsequendy, they have been modified for ethylene—a-olefin copolymerisation reactions (10). These catalysts use a mixed sihca—titania support containing from 2 to 20 wt % of Ti. After the deposition of chromium species onto the support, the catalyst is first oxidised by an oxygen—air mixture and then reduced at increased temperatures with carbon monoxide. The catalyst systems used for ethylene copolymerisation consist of sohd catalysts and co-catalysts, ie, triaLkylboron or trialkyl aluminum compounds. Ethylene—a-olefin copolymers produced with these catalysts have very broad molecular weight distributions, characterised by M.Jin the 12—35 and MER in the 80—200 range. [Pg.399]

See other pages where Broad molecular weight is mentioned: [Pg.253]    [Pg.38]    [Pg.181]    [Pg.597]    [Pg.246]    [Pg.25]    [Pg.412]    [Pg.397]    [Pg.111]    [Pg.253]    [Pg.38]    [Pg.181]    [Pg.597]    [Pg.246]    [Pg.25]    [Pg.412]    [Pg.397]    [Pg.111]    [Pg.34]    [Pg.81]    [Pg.640]    [Pg.644]    [Pg.121]    [Pg.129]    [Pg.316]    [Pg.316]    [Pg.206]    [Pg.288]    [Pg.434]    [Pg.264]    [Pg.357]    [Pg.237]    [Pg.262]    [Pg.372]    [Pg.379]    [Pg.383]    [Pg.383]    [Pg.395]    [Pg.397]    [Pg.397]    [Pg.401]    [Pg.413]   
See also in sourсe #XX -- [ Pg.257 ]



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