Liquid chromatography is a powerful separation method that finds applications to all branches of science. There are, however, some mistaken statements in chromatographic theory caused owing to the limitation of using conventional detection techniques. We designed a whole-column detection (WCD) system which enabled monitoring of whole on-column chromatographic peaks during the elution process on both spatial and time coordinate in order to clarify the shortcomings. In the first part, a single-compound sample was eluted under mobile phases of fifteen different compositions, generating chromatograms of 15 different retention factors (k). The bandwidth of the peak (k=7.27) increased by almost 4.6 folds compared with the peak (k=0.54). However, the bandwidths of these two peaks remained almost the same on the spatial coordinate in the column. The peak width was found linearly dependent on the solute releasing speed from the column outlet to the attached post-column detector. In other words, the peak widths obtained using the post-column detector cannot reflect the true widths in the column. In the second part, stepwise gradient elutions were carried out. The theoretical plate number and the plate height were erroneously obtained using the traditional equations. It revealed the incompetence of the theoretical plate number and plate height definition while non-linear chromatographies are performed. In the third part, solute migrations were clearly monitored in the column. Peak crossover phenomenon was observed during the entire migration course using the WCD system. In conclusion, we fabricated a WCD system in this study to comprehensively observe the elution process in liquid chromatography. Several misconceptions were clarified by the spatial data. The detailed on-column observations obtained using the WCD system may further provide useful information to uncover hidden aspects which may have been ignored by chromatographers.