Multi-walled carbon nanotubes (CNTs) were grown on silicon nanoporous pillar array (Si-NPA) by thermal chemical vapor deposition method, and the structural and capacitive humidity sensing properties of CNT/Si-NPA were studied. It was found that with the relative humidity (RH) changing from 11% to 95%, a device re-sponse of ~480% was achieved at the frequency of 50000 Hz, and a linear device response curve could be obtained by adopting longitudinal logarithmic coordinate. The response/recovery times were measured to be ~20 s and ~10 s, respectively, which indicated a rather fast response/recovery rate. The adsorption-desorption dynamic cycle experiments demonstrated the high measurement reproducibility of CNT/Si-NPA sensors. These excellent performances were attributed to the unique surface structure, morphology and chemical inertness of CNT/Si-NPA. Multi-walled carbon nanotubes (CNTs) were grown on silicon nanoporous pillar arrays (Si-NPA) by thermal chemical vapor deposition method, and the structural and capacitive humidity sensing properties of CNT / Si-NPA were studied. It was found that with the relative humidity (RH) changing from 11% to 95%, a device re-sponse of ~ 480% was achieved at the frequency of 50000 Hz, and a linear device response curve could be obtained by adopting longitudinal logarithmic coordinate. These were played to 20 s and ~ 10 s, respectively, which indicated a rather fast response / recovery rate. The adsorption-desorption dynamic cycle tests demonstrated the high measurement reproducibility of CNT / Si-NPA sensors. These excellent performances were attributed to the unique surface structure, morphology and chemical inertness of CNT / Si-NPA.