Separation with solvent peaks

These columns make the elution of low molecular weight components slower and can he used to separate a solvent peak or other troublesome peaks to realize accurate measurements of the molecular weight distribution. The use of this column with 805L, 806L, 806M, and 807L columns is recommended. 

Figures 6.6 and 6.7 show the effect of a solvent separation column. In the case of Fig. 6.7, the upper part of the figure shows the chromatogram of polyvinyl chrolide, which contains dioctyl phthalate (DOP), using KF-806L. In this case, DOP is not separated from a solvent peak. However, DOP can be separated from the solvent peak using KF-800D in conjunetion with KF-806L (Table 6.6).

Modifiers can be used very effectively in on-line SFE-GC to determine the concentration levels of the respective analytes. This presents an advantage in terms of the use of modifiers in SFE, since they appear as solvent peaks in GC separations and do not interfere with the target analyte determination. Although online SFE-GC is a simple technique, its applicability to real-life samples is limited compared to off-line SFE-GC. As a result, on-line SFE-GC requires suitable sample selection and appropriate setting of extraction conditions. If the goal is to determine the profile or matrix composition of a sample, it is required to use the fluid at the maximum solubility. For trace analysis it is best to choose a condition that separates the analytes from the matrix without interference. However, present SFE-GC techniques are not useful for samples... 

If solvent B is too strong, then the middle or later peaks may be poorly resolved. In extreme cases of this, the solvent B may itself be strongly held at the top of the column (the column is now separating the solvent mixture, the effect being called solvent demixing). If this occurs then pure A will pass through the column until the column is saturated with solvent B. 

Figure 4.7 shows the structures of important carotenoids (all-E) lutein, (all-E) zeaxanthin, (all-E) canthaxanthin, (all-E) p-carotene, and (all-E) lycopene. Employing a self-packed C30 capillary column, the carotenoids can be separated with a solvent gradient of acetone water=80 20 (v/v) to 99 1 (v/v) and a flow rate of 5 pL min, as shown in Figure 4.8 (Putzbach et al. 2005). The more polar carotenoids (all-E) lutein, (all-E) zeaxanthin, and (all-E) canthaxanthin elute first followed by the less polar (all-E) p-carotene and the nonpolar (all-E) lycopene. Figure 4.9 shows the stopped-flow II NMR spectra of these five carotenoids. The chromatographic run was stopped when the peak maximum of the compound of interest reached the NMR probe detection volume.

By a method similar to that described in the last section phenylazide in cyclohexene was irradiated with ultraviolet radiation and unreacted cyclohexene was distilled off with evaporation. The residue was extracted with n-hexane. The extract was separated into several products by gas and liquid chromatography. The gas chromatogram and the liquid chromatogram are shown in Figures 7 and 8, which give five peaks from A to E, and four peaks from A to D, respectively in addition to the peak due to the solvent. Peaks A and A were determined to be aniline by their retention times. Peaks B and C are due to 3,3 -bicyclohexenyl. Peaks C and D are those of aziridine[9] and the product which was formed by the insertion of phenylnitrene to C-H bond of cyclohexene. ... 

Typical NP conditions involve mixtures of n-hexane or -heptane with alcohols (EtOH and 2-propanol). In many cases, the addition of small amounts (<0.1%) of acid and/or base is necessary to improve peak efficiency and selectivity. Usually, the concentration of alcohols tunes the retention and selectivity the highest values are reached when the mobile phase consists mainly of the nonpolar component (i.e., n-hexane). Consequently, optimization in NP mode simply consists of finding the ratio n-hexane/alcohol that gives an adequate separation with the shortest possible analysis time [30]. Normally, 20% EtOH gives a reasonable retention factor for most analytes on vancomycin and TE CSPs, while 40% is more appropriate for ristocetin A-based CSPs. Ethanol normally gives the best efficiency and resolution with reasonable backpressures. Other combinations of organic solvents (ACN, dioxane, methyl tert-butyl ether) have successfully been used in the separation of chiral sulfoxides on five differenf glycopepfide CSPs, namely, ristocetin A, teicoplanin, TAG, vancomycin, and VAG CSPs [46]. 

Dimethyl bromosuccinate was prepared from bromosuccinic acid by the diazomethane method (26) using the procedure of Eisenbraun, Morris, and Adolphen (27). It was distilled under vacuum (0.08-0.1 Torr) at 45°-49°C to yield a clear colorless oil. Thin layer chromatography with benzene as the solvent on SiC>2 yielded a symmetrical single spot, indicating either a pure compound or no separation with this particular solvent. Its mass spectrum had a very small peak corresponding to the parent compound, but none to a dibromo compound. The mass spectrum for dimethyl bromosuccinate was not found in the literature, but that for dimethyl succinate also has a small peak corresponding to the parent compound (25). 

Retention times of molecules separated over mesoporous silica are much longer than those obtained by using commercially available silica, this is due to the increased surface area of mesoporous silica, which in turn increases molecular capacity factors. Differences between capacity factors are also enhanced Thus, molecules which elute with similar retention times on commercial HPLC columns, with overlapping peaks, can be successfully separated by using HPLC columns slurry packed with mesoporous silica. The long retention times are somewhat of a drawback in that large amounts of solvent must be used and the peak shapes of molecules with long retention times can be broad. Mesoporous silica may not be ideal for routine analytical separations but provides an excellent and cost-effective preparative separation medium. 

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