Publications by authors named "Rongxiang Zheng"
Selective recovery of rare earth elements (REEs) from environmental waste is strategically significant. Herein, Ce(III) imprinted EDTA modified chitosan-magnetic graphene oxide (IIP-EDTA-CS-MGO) was prepared for selective recovery of Ce(III). Furthermore, adsorption mechanism was clarified based on versatile adsorption fittings and spectroscopic tests.
View Article and Find Full Text PDFReclamation of rare earths from secondary sources is in line with both environmental remediation and sustainable utilization of rare earth resources. Herein, neodymium Nd(III) imprinted polyethylene glycol-polyvinyl alcohol hybrid membrane (IIP-CS-PEG-PVA) with high selectivity, increased specific surface area, acid stability and easy recyclability was constructed using chitosan (CS) as functional monomer, polyethylene glycol (PEG) as porogenic agent, polyvinyl alcohol (PVA) as filmogen, and Nd(III) as template ion. Batch adsorption indicates, adsorption of IIP-CS-PEG-PVA for Nd(III) is induced by electrostatic interaction, reaching rapid equilibration in 35 min at pH = 5.
View Article and Find Full Text PDFHigh efficiency removal of methyl blue using phytic acid modified graphene oxide and adsorption mechanism.
Spectrochim Acta A Mol Biomol Spectrosc
February 2024
Article Synopsis
- - Phytic acid modified graphene oxide (PGO) is developed as an effective adsorbent for removing methyl blue (MB) from wastewater, achieving efficient adsorption of 89.08 mg·g in just 22 minutes using a straightforward hydrothermal method.
- - The adsorption mechanism is analyzed using the hard-soft acid-base (HSAB) principle, which reveals that both covalent bonds and electrostatic interactions are involved in the process, particularly between the phytic acid moiety and MB.
- - Findings from FTIR and UV-Vis analyses confirm that modifying graphene oxide with phytic acid increases its ability to attract and hold onto contaminants, highlighting PGO's potential for environmental cleanup applications.