Comprehensive two-dimensional gas chromatography using partial modulation via a pulsed flow valve with a short modulation period

Abstract

Partial modulation via a pulsed flow valve for comprehensive two-dimensional (2D) gas chromatography (GC × GC) is demonstrated, producing narrow peak widths, 2Wb, on the secondary separation dimension, 2D, coupled with short modulation periods, PM, thus producing a high peak capacity on the 2D dimension, 2nc. The GC × GC modulator is a pulse flow valve that injects a pulse of carrier gas at the specified PM, at the connection between the primary, 1D, column and the 2D column. Using a commercially available pulse flow valve, this injection technique performs a combination of vacancy chromatography and frontal analysis, whereby each pulse disturbance in the analyte concentration profile as it exits the 1D column results in data that is readily converted into a 2D separation. A three-step process converts the raw data into a format analogous to a GC × GC separation, incorporating signal differentiation, baseline correction and conversion to a GC × GC chromatogram representation. A 115-component test mixture with a wide range of boiling points (36–372°C) of nine compound classes is demonstrated using modulation periods of PM = 50, 100, 250, and 500ms, respectively. For the test mixture with a PM of 250ms, peak shapes on 2D are symmetric with apparent 2Wb ranging from 12 to 45ms producing a 2nc of ~ 10. Based on the average peak width of 0.93s on the 1D separation for a time window of 400s, the 1D peak capacity is 1nc ∼ 430. Thus, the ideal 2D peak capacity nc,2D is 4300 or a peak capacity production of 650 peaks/min using the PM of 250ms. Additionally, for a PM of 50, 100 and 500ms, the 2nc are 4, 7, and 12, respectively. Retention times on 2D, 2tR, are reproducible having standard deviations less than 1ms. Finally, the processed data is shown to be quantitative, with an average RSD of 4.7% for test analytes.