Naphthenic acids,NAs,are a major contaminant of concern and a focus of much research around remediation of oil sand process affected waters,OSPW.Using activated carbon adsorbents are an attractive option given their l...Naphthenic acids,NAs,are a major contaminant of concern and a focus of much research around remediation of oil sand process affected waters,OSPW.Using activated carbon adsorbents are an attractive option given their low cost of fabrication and implementation.A deeper evaluation of the effect NA structural differences have on uptake affinity is warranted.Here we provide an in-depth exploration of NA adsorption including many more model NA species than have been assessed previously with evaluation of adsorption kinetics and isotherms at the relevant alkaline pH of OSPW using several different carbon adsorbents with pH buffering to simulate the behaviour of real OSPW.Uptake for the NA varied considerably regardless of the activated carbon used,ranging from 350 mg/g to near zero highlighting recalcitrant NAs.The equilibrium data was explored to identify structural features of these species and key physiochemical properties that influence adsorption.We found that certainNAwill be resistant to adsorptionwhen hydrophobic adsorbents are used.Adsorption isotherm modelling helped explore interactions occurring at the interface between NA and adsorbent surfaces.We identified the importance of NA hydrophobicity for activated carbon uptake.Evidence is also presented that indicates favorable hydrogen bonding between certain NA and surface site hydroxyl groups,demonstrating the importance of adsorbent surface functionality for NA uptake.This research highlights the challenges associated with removing NAs from OSPW through adsorption and also identifies howadsorbent surface chemistry modification can be used to increase the removal efficiency of recalcitrant NA species.展开更多
文摘Naphthenic acids,NAs,are a major contaminant of concern and a focus of much research around remediation of oil sand process affected waters,OSPW.Using activated carbon adsorbents are an attractive option given their low cost of fabrication and implementation.A deeper evaluation of the effect NA structural differences have on uptake affinity is warranted.Here we provide an in-depth exploration of NA adsorption including many more model NA species than have been assessed previously with evaluation of adsorption kinetics and isotherms at the relevant alkaline pH of OSPW using several different carbon adsorbents with pH buffering to simulate the behaviour of real OSPW.Uptake for the NA varied considerably regardless of the activated carbon used,ranging from 350 mg/g to near zero highlighting recalcitrant NAs.The equilibrium data was explored to identify structural features of these species and key physiochemical properties that influence adsorption.We found that certainNAwill be resistant to adsorptionwhen hydrophobic adsorbents are used.Adsorption isotherm modelling helped explore interactions occurring at the interface between NA and adsorbent surfaces.We identified the importance of NA hydrophobicity for activated carbon uptake.Evidence is also presented that indicates favorable hydrogen bonding between certain NA and surface site hydroxyl groups,demonstrating the importance of adsorbent surface functionality for NA uptake.This research highlights the challenges associated with removing NAs from OSPW through adsorption and also identifies howadsorbent surface chemistry modification can be used to increase the removal efficiency of recalcitrant NA species.
