Due to the special characteristics of dense non-aqueous phase liquids (DNAPLs), singnificant solubility and low mobility, the contamination of soil and groundwater by DNAPLs is still an intractable problem for environmental engineers. Even more, if DNAPLs were transported to impermeable boundary, they would form DNAPL pools and become continuous contamination sources. The application of nano zero-valent iron (nZVI) in soil and groundwater treatment is given increasing attention because of its high surface reactivity and transportation ability in the underground. However, the researches about the reaction of chlorinated aliphatic hydrocarbons with nZVI were mostly conducted in aqueous phase instead of in non-aqueous phase. The purpose of this research is to investigate the reaction rates and pathways of trichloroethene reduction by different nZVI with different water content and to shed light on the theory and values of the empirical parameters of the reaction. The results show that nZVI and bimetallic nZVI could reduce trichloroethene in non-aqueous phase. The trichloroethene reduction by physical vapor deposition (PVD) iron (F), PVD bimetallic iron (DF) and surface modified bimetallic iron (ADF) in non-aqueous phase were better to explained by zero-order reaction kinetics. The zero-order reaction rate, kSA, are 1.891×10-5，6.272×10-5，5.066×10-5 (mmol∙L∙h-1∙m-2). In this research, the molar equivalent of trichloroethene was higher than that of nZVI, so that the hydrogen ion produced was consumed immediately and its activity was low in the microcosm systems. The reduction rates of trichloroethene in non-aqueous phase are much slower than the rates in aqueous phase. Under the same nZVI dosage with different water content, the kSA with higher water content is higher in DF group, but with no significant difference in F and ADF groups.