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Increasing Mass Transfer Resistance of MOFs as a Reverse Tuning Strategy to Achieve High-Resolution Gas Chromatographic Separation.

Han YangJia-Jia LiuWen-Qi TangSha-Sha MengYuan-Xiao GaoWang LiHao ZhangMing XuZhi-Yuan Gu
Published in: Analytical chemistry (2023)
In separation science, precise control and regulation of the MOF stationary phase are crucial for achieving a high separation performance. We supposed that increasing the mass transfer resistance of MOFs with excessive porosity to achieve a moderate mass transfer resistance of the analytes is the key to conducting the MOF stationary phase with a high resolution. Three-dimensional UiO-67 (UiO-67-3D) and two-dimensional UiO-67 (UiO-67-2D) were chosen to validate this strategy. Compared with UiO-67-3D with overfast mass transfer and low retention, the reduced porosity of UiO-67-2D increased the mass transfer resistance of analytes in reverse, resulting in improved separation performance. Kinetic diffusion experiments were conducted to verify the difference in mass transfer resistance of the analytes between UiO-67-3D and UiO-67-2D. In addition, the optimization of the UiO-67-2D thickness for separation revealed that a moderate diffusion length of the analytes is more advantageous in achieving the equilibrium of absorption and desorption.
Keyphrases
  • metal organic framework
  • liquid chromatography
  • high resolution
  • mass spectrometry
  • tandem mass spectrometry
  • electron transfer
  • simultaneous determination
  • optical coherence tomography
  • weight gain
  • ionic liquid