Because of flooding and microbial metabolism, humic acid in some natural reduction environments could be reduced and then interact with metal ions; moreover, the copper ion is easily to be reduced. To understand whether a reduced condition can facilitate the formation of zero valent Cu NPs and then interact with persistent organic pollutant (POP), HBCD, one of POP, is chosen as a target compound. First, Cu NPs were synthesized by sodium borohydride. The removal of HBCD by Cu NPs was increased with the Cu NPs dosage increased but with the initial HBCD concentration decreased. The highest rate constant presented in 3.5 g/L Cu NPs, moreover the mass-normalized rate constant was 14.4 min-1g-1. The removal of HBCD was also increased with the temperature increased. The estimated activation energy was about 32.21 kJ/mol, which is considered as surface controlled reaction. The removal of HBCD was decreased with the initial pH increased. However, with pH increased the passivation of Cu NPs such as copper (hydro)oxide was found and then contributed to the increase of HBCD adsorption efficiency. On the other hand, the pHzpc of Cu NPs is 8.1, the Cu NPs would aggregate with the increased pH and then reduce the rate constant. To understand the transformation of complexes of reduced humic acid and cupric ion, humic acid was chemically reduced by sodium borohydride, and cupric ion was well-mixed with the reduced humic acid (RHA) under different Cu(II) ion dosages and incubation period. The copper species of RHA-Cu were organic acid-copper complexes after the reacting time of 12 hours. Metallic copper was observed for the reacting time of 48 hours in the condition of 0.9 g/L RHA with 175 mmol/kg Cu(II) which were analyzed by X-ray adsorption near edge structure. The spatial distribution of zero valent copper in the humic acid were investigated by scanning photoemission microscopy. There were two peaks at 1384 and 1598 cm-1 owning to the carboxylate vibrations, indicating that the HA complexes with Cu(II) via chemical bonding which were investigated by Fourier transform infrared spectroscopy. The particle size of metallic copper of RHA-Cu was around 50 nm was analyzed by single particle-inductively coupled plasma-mass spectrometry. The removal efficiency of HBCD by RHA-Cu was 34.5% after 24 hours and bromide ions were detected, indicating a reduction and debromination reaction of HBCD. Our results demonstrate the metallic copper can be synthesized by humic substances in a redox condition, which could provide a potential for HBCD removal through this abiotic chemical process.