Perfluorinated chemicals (PFCs) are compounds composed of hydrogen substituted by fluorine in the carbon chain to form a highly stable C-F bond and hydrophilic functional groups, so that they are both hydrophilic and hydrophobic. They are widely used in various products and processes. PFCs with long carbon chains were widely used in the industry, but recently they were found to the environmental persistent with bioaccumulative toxicities. Countries began to formulate policies to replace long-chain PFCs with short-chain PFCs, such as perfluorobutanoic acid (PFBA). However, information about the toxicity and bioaccumulation of short-chain PFCs is scarce; studies have shown that short-chain PFCs might also pose human and ecological risks. Therefore, development of effective technologies for removal of short-chain PFCs from environmental media of importance. In this study, activated carbon (AC) was used for removal of PFBA from water through adsorption. First, basic properties of activated carbon, such as zeta potential, specific surface area, constituent elements, and surface structure, were analyzed. Effects of the initial PFBA concentration, pH value, AC dose and stirring rate were then compared to find out the optimal parameters for removal. Further, best experimental parameters were used to modify AC (cationic surfactant, polyvinylideneamine, sulfuric acid) to investigate the effectiveness of the modified ACs on the adsorption removal of PFBA.The results showed that after six hours of reaction at room temperature, initial PFBA concentration of 200 ppm, pH 3.0, AC dose = 8 g/L, stirring speed = 600 rpm ,a stir bar = 2.5 cm, in a 250 mL buffer solution (KH2PO4 = 2.0 mM; H3BO3= 2.0 mM; KCl= 2.0 mM), the best adsorption effect was achieved by AC modified by tetrabutyl-ammonium bromide (TBAB), a cationic surfactant, with a removal rate of 96.72% and an adsorption capacity of 24.23 mg/g. In addition, modifications of AC with other cationic surfactants at various pH values also increased the adsorption removal of PFBA. However, the removal effectiveness of AC modified with polyvinylideneamine or sulfuric acid decreased. The adsorption processes were mostly in accordance with the the pseudo-second-order adsorption kinetics model, and the adsorption processes of the AC and the TBAB-modified AC were in accordance with the Langmuir isothermal adsorption model. This study also investigated the competitive adsorption behavior by testing the adsorption of PFBA, undecafluorohexanoic acid (PFHxA), and perfluorobutanesulfonic acid (PFBS) by the AC. When the AC was used in synthetic wastewater, the extents of adsorption were PFHxA > PFBS > PFBA. When the TBAB-modified AC was used in synthetic wastewater, the extents of adsorption were PFBS> PFHxA > PFBA. In addition, the adsorption capacities of the TBAB-modified AC for PFBA, PFBS, and PFHxA were higher than those of the AC. Finally, in order to verify the applicability of the TBAB-modified AC, a comparison was made between real wastewater and synthetic wastewater. The results showed that the presence of organic matter and salts in the real wastewater might compete with PFCs for the adsorption sites, resulting in poorer adsorption. This study confirmed that the TBAB-modified AC could adsorb PFBA more effectively than the AC. However, its applications for removal of PFBA in real wastewaters need to be further investigated.