Persulfate advanced oxidation process has gained increasing attentions in recent years due to its high capability to degrade organic contaminants. In addition to free radicals produced, studies suggested that the degradation of organic contaminants can be proceeded via the non-radical mechanism. In order to specifically investigate the electron transfer pathway of the non-radical mechanism, the galvanic oxidation process (GOP) was employed, in which the target contaminant 2,4-dichlorophenol (2,4-DCP) and peroxymonosulfate (PMS) were separated into two individual anodic and cathodic cells that were connected by a salt bridge and external copper wire. The separated cells can exclude the contributions of radicals and reactive surface complexes generated from the PMS activation toward the degradation of 2,4-DCP. Multi-walled carbon nanotube (MWCNT) was used as the PMS activator and was coated on the graphite sheet as electrodes. In the GOP control system that is connected or disconnected to salt bridge and external copper wire in the condition of 10 µM 2,4-DCP and 25 mM PMS, it was observed that 22% of 2,4-DCP removal could be attributed to adsorption on the electrode, while almost all of the 2,4-DCP was removed via the adsorption and direct electron transfer pathway in 7 h. The 2,4-DCP removal was enhanced by the increasing of PMS concentration, 2,4-DCP concentration, MWCNT coating and the pH of 2,4-DCP solution in the anodic cell. The magnitude of current measured was higher at a higher 2,4-DCP removal rate. In the electrode reusability test, the 2,4-DCP removal remained about 92% after 8 cycles, indicating the good reusability and stability of the MWCNT electrodes. X-ray photoelectron spectroscope (XPS) and Raman spectroscopy were applied to analyze the used MWCNT. The results of decreasing defects or disorders on MWCNT and the increasing of oxygen content suggested that the adsorption, activation and electron transfer did occur in the process and could gradually restrict the activation ability of MWCNT. These changes may affect the long term performance of the electrode and may require further investigation.