In order to understand the capacity of water vapor to transport copper and its mechanism, using the solubility method, the solubility of copper in undersaturated water vapor was investigated experimentally at temperatures from 310 ℃ to 350 ℃ and pressures from 42×10~5 to 100×10~5 Pa. Results of these experiments show that the presence of water vapor increases the concentration of Cu in the gas. At a constant temperature, the solubility of copper increases with increasing water vapor pressure. Copper may exist as hydrated gaseous particles in the vapor phase, and the dissolution process can be described by the following reaction: CuCl~ solid _m+nH_2O~ gas =CuCl_m·(H_2O)~ gas _n(m=1, 2). The hydration number decreases with increasing temperature, varying from ～6 at 310 ℃, to ～5 at 330 ℃, and ～4 at 350 ℃. The results show that interactions between gas-solvent H_2O and copper will significantly enhance the dissolution and transport capacity of copper in the gas phase. In order to understand the capacity of water vapor to transport copper and its mechanism, using the solubility method, the solubility of copper in undersaturated water vapor was investigated experimentally at temperatures from 310 ℃ to 350 ℃ and pressures from 42 × 10 ~ 5 to 100 × 10 ~ 5 Pa. Results of these experiments show that the presence of water vapor increases the concentration of Cu in the gas. At a constant temperature, the solubility of copper increases with increasing water vapor pressure. the vapor phase, and the dissolution process can be described by the following reaction: CuCl ~ solid _m + nH_2O ~ gas = CuCl_m · (H_2O) ~ gas_n (m = 1, 2) from ~ 6 at 310 ° C to ~ 5 at 330 ° C and ~ 4 at 350 ° C. The results show that interactions between gas-solvent H_2O and copper will significantly enhance the dissolution and transport capacity of copper in the gas phase.