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Olefin constants

To a 250-ml not-partitioned electrochemical cell, 135 ml of CH3CN, 15 ml ofHiO, 6.20 g of NaBr and 2.82 g of olefin ( ) is added. The mixture, kept at 2(f C, is electrolysed by using the same electrodes as of Example 1, but with a constant current density of 1.7 A being used,until through the cell 4,000 Coulombs have been passed. The reaction mixture is then processed as described in Example 4.2.56 g is obtained of ketone (III), with a yield of 83.2%, as computed relatively to the olefin (I) used as the starting material. [Pg.192]

Polar solvents shift the keto enol equilibrium toward the enol form (174b). Thus the NMR spectrum in DMSO of 2-phenyl-A-2-thiazoline-4-one is composed of three main signals +10.7 ppm (enolic proton). 7.7 ppm (aromatic protons), and 6.2 ppm (olefinic proton) associated with the enol form and a small signal associated with less than 10% of the keto form. In acetone, equal amounts of keto and enol forms were found (104). In general, a-methylene protons of keto forms appear at approximately 3.5 to 4.3 ppm as an AB spectra or a singlet (386, 419). A coupling constant, Jab - 15.5 Hz, has been reported for 2-[(S-carboxymethyl)thioimidyl]-A-2-thiazoline-4-one 175 (Scheme 92) (419). This high J b value could be of some help in the discussion on the structure of 178 (p. 423). [Pg.422]

As can be seen from Figure 4, LBVs for these components are not constant across the ranges of composition. An iateraction model has been proposed (60) which assumes that the lack of linearity results from the iateraction of pairs of components. An approach which focuses on the difference between the weighted linear average of the components and the actual octane number of the blend (bonus or debit) has also been developed (61). The iadependent variables ia this type of model are statistical functions (averages, variances, etc) of blend properties such as octane, olefins, aromatics, and sulfur. The general statistical problem has been analyzed (62) and the two approaches have been shown to be theoretically similar though computationally different. [Pg.188]

Analytical and test methods for the characterization of polyethylene and PP are also used for PB, PMP, and polymers of other higher a-olefins. The C-nmr method as well as k and Raman spectroscopic methods are all used to study the chemical stmcture and stereoregularity of polyolefin resins. In industry, polyolefin stereoregularity is usually estimated by the solvent—extraction method similar to that used for isotactic PP. Intrinsic viscosity measurements of dilute solutions in decahn and tetraHn at elevated temperatures can provide the basis for the molecular weight estimation of PB and PMP with the Mark-Houwiok equation, [rj] = KM. The constants K and d for several polyolefins are given in Table 8. [Pg.431]

The olefin distribution in the catalytic processes, on the other hand, tends to foUow the Schultz-Flory equation, where equals the number of moles of olefins having carbon number N, X equals the moles of olefins having two carbon numbers lower, andis a constant depending on the reaction conditions can range from 0.4—0.9 but usually equals 0.6—0.8. [Pg.437]

Butylene isomers also can be expected to show significant differences in reaction rates for metaHation reactions such as hydroboration and hydroformylation (addition of HCo(CO). For example, the rate of addition of di(j -isoamyl)borane to cis-2-huX.en.e is about six times that for addition to trans-2-huX.en.e (15). For hydroformylation of typical 1-olefins, 2-olefins, and 2-methyl-l-olefins, specific rate constants are in the ratio 100 31 1, respectively. [Pg.364]

The combination of low residence time and low partial pressure produces high selectivity to olefins at a constant feed conversion. In the 1960s, the residence time was 0.5 to 0.8 seconds, whereas in the late 1980s, residence time was typically 0.1 to 0.15 seconds. Typical pyrolysis heater characteristics are given in Table 4. Temperature, pressure, conversion, and residence time profiles across the reactor for naphtha cracking are illustrated in Figure 2. [Pg.435]

Many researchers have correlated the overall decomposition as an nxh. order reaction, with most paraffins following the first order and most olefins following a higher order. In general, isoparaffin rate constants are lower than normal paraffin rate constants. The rate constants are somewhat dependent on conversion due to inhibition effects that is, the rate constant often decreases with increasing conversion, and the order of conversion is not affected. This has been explained by considering the formation of aHyl radicals (38). To predict the product distribution, yields are often correlated as a function of conversion or other severity parameters (39). [Pg.437]

Taft s Terminal olefins, synthesis of 629 Tertiary alcohols, allylic, epimerization of 736... [Pg.1208]

Effect of di monosulfonate ratio on IOS and VOS calcium tolerance. Similar trends were observed when studying internal olefinsulfonates (IOS) and vinylideneolefinsulfonates (VOS). These data are given in Table 7. The average carbon number of the olefins used to synthesize AOS 2024, IOS 2024, and VOS 2024 was nearly constant (21.2-21.6). Increasing the disulfonate content of IOS 2024 and VOS 2024 substantially increased the calcium ion tolerance. [Pg.380]

FIG. 18 The effect of chain length on the pseudo rate constants (Km (100 90)) of n-hexadecane solubilization by olefinsulfonates/dobanol 45-3 solutions at 40°C. AOS, a-olefinsulfonate IOS a, aged I-olefinsulfonate IOS d, directly hydrolyzed I-olefin-sulfonate. [Pg.414]

The observation (Porter ef a ., 1972) that added BrCCla almost completely suppresses the polarization of the olefin, while leaving the polarization of trans-4 unalfected, points to the secondary radical pair as the principal immediate precursor of a-methylstyrene. A rate constant for the decomposition of thediazenyl radical of 10 -10 sec has been estimated. Cage collapse and free-radical formation are also thought to occur and appropriately polarized products have been identified (see above). [Pg.98]

Table 4 Structural Effects on 1 1 CTC Formation Constants (Kf) Between Br2 and Olefins and the Respective Bromination Rates. Table 4 Structural Effects on 1 1 CTC Formation Constants (Kf) Between Br2 and Olefins and the Respective Bromination Rates.
If return occurs during the bromination of cw-stilbenes and rotation around the C-C bond is faster than collapse of the intermediates to dibromides, this process will lead to fra j-stilbene (Scheme 9). We used this test to check the possibility of return in the bromination of unsubstimted, 4-methyl, 4-trifluoromethyl-, and 4,4 -bis(trifluoromethyl)-stilbenes in DCE (ref. 24). All these olefins gave clean third-order rate constants spanning 7 powers of 10. For each cis-trans couple the cis olefin was brominated 3.5 to 5.5 times faster than the trans isomer. Reactions for products analysis were performed at initial molar ratios of Br2 to olefin of 1 to 2, so that products arose only from the cis olefin, the trans isomer being accumulated in the reaction medium. [Pg.145]

Relative Second-Order Rate Constants for Ozonations of Selected Olefins in CCI4 at Room Temperature... [Pg.472]

See other pages where Olefin constants is mentioned: [Pg.113]    [Pg.191]    [Pg.191]    [Pg.165]    [Pg.1326]    [Pg.410]    [Pg.561]    [Pg.566]    [Pg.373]    [Pg.77]    [Pg.213]    [Pg.265]    [Pg.21]    [Pg.28]    [Pg.522]    [Pg.620]    [Pg.67]    [Pg.114]    [Pg.115]    [Pg.116]    [Pg.116]    [Pg.1097]    [Pg.249]    [Pg.51]    [Pg.415]    [Pg.263]    [Pg.144]    [Pg.231]    [Pg.130]    [Pg.257]    [Pg.82]    [Pg.117]    [Pg.129]    [Pg.131]    [Pg.135]    [Pg.144]   
See also in sourсe #XX -- [ Pg.94 ]



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