![]() ![]() For the example of Figure 2, as the amount of sample on column is reduced, we would see the progression of peaks from left to right until the retention time and peak shape stabilize. The test to confirm column overload is obvious-reduce the amount of sample on column, and if the retention time increases and peak width is reduced, overload is confirmed. In either case, the result is the same, with shorter retention times and broader peaks. When an active site is “busy” interacting with one sample molecule, a new molecule may displace it or may continue traveling in the mobile phase until a free active site is available for interaction. Of course, the column doesn’t really contain beakers, but it does have “active sites,” where chemical interaction between the solute and the stationary phase can take place. This is analogous to column overload-the band on the column is considerably wider (broader peaks) and the center of mass travels faster than normal (shorter retention). Similarly, the second goes to number 6, 3 to 7, and so forth. When we pick up the first beaker to transfer it down the column, we have to skip to the fifth beaker before we can find room. Now the sample fills four 250-mL beakers. If, on the other hand, we have a 1000-mL sample, it completely fills the first 250-mL beaker, so we move to the next one and fill it, and the next and the next. This situation is analogous to normal sample loading on an LC column. The entire sample is still contained in a single beaker, ignoring minor losses along the way because of incomplete transfers. ![]() If we have a 100-mL sample, we can pour the entire sample into the first beaker, then pick up the first beaker and pour it into the second, the second into the third, and so forth until we get to the end of the column, perhaps 100 beakers later. To conceptually illustrate column overload, I like to consider an imaginary column that comprises a series of 250-mL beakers lined up side by side. We won’t consider preparative separations further here.Ĭolumn Overload Let’s first consider column overload in more detail, because it is more commonly encountered by most workers than detector overload is. This combination is rare in analytical separations, but can be common for preparative separations, where column overload is intentional so as to increase the throughput in terms of mass of sample per hour in such cases, detector overload may not be of much concern, either. Of course, a combination of column and detector overload can occur, where column overload, as in Figure 2, occurs first, but at some point, detector overload will occur and the right-triangle peaks of Figure 2 would take on the additional characteristic of flat tops. This is referred to as detector overload. When the sample concentration exceeds the range of the detector, the detector cannot generate a larger response, and typically a flat-topped peak is observed, as for the largest peak of Figure 1b. With ultraviolet (UV) absorbance detectors, for example, we expect the peak area and height to increase in proportion to the sample size, as seen for the four smaller nested peaks of Figure 1b. LC detectors are designed so that an increase in peak height and peak area are seen with an increase in the concentration of sample injected onto the column. However, perfectly symmetric peaks are rare in LC separations, with most peaks tailing a bit. What Are the Symptoms? An ideal chromatographic peak is Gaussian in shape, as seen in Figure 1a. This month’s “LC Troubleshooting” article looks at these two overload types, their causes, and possible solutions to correct the problem. Overload most commonly occurs as column overload or detector overload. This situation usually is referred to as overload. However, problems at the other end of the scale exist when more of an analyte is present than can be accommodated by the LC system. In such cases, the problems associated with too much sample rarely are encountered. How to distinguish between liquid chromatography (LC) column overload and detector overload.įor many applications of liquid chromatography (LC), the goal is to measure very small quantities of the analytes of interest. ![]()
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