Adsorption performance and mechanism of polyamidoxime-coated glucose derived biochar for separation of uranium from nuclear wastewater

Background

Efficient removal of uranium from uranium-containing nuclear wastewater is of great significance for national defense security and environmental protection.

Methods

We synthesized a polyamidoxime-coated glucose-derived biochar (GC-PAO) adsorbent and systematically investigated its adsorption mechanism using Scanning electron microscopy (SEM), Brunauer-Emmett-Teller (BET), Fourier-transform infrared spectroscopy (FTIR), Raman spectroscopy (Raman), Synchronous thermal analyzer (STA) and X-ray photoelectron spectroscopy (XPS).

Significant findings

The optimized adsorbent, GC-850/3.6-PAO, has a pore structure suitable for adsorption with a high content of amidoxime functional groups through careful selection of the carbonization precursor, chemical catalyst and pyrolysis temperature. By adsorption experiments at pH = 6, the maximum adsorption by GC-850/3.6-PAO adsorbent in 32 ppm uranium spiked solution was 565.36 mg·g^-1. Meanwhile, GC-PAO also has good reusability. The adsorption capacity of Uranium (VI) remained at 402.63 mg·g^-1 after 5 repetitions. Kinetics, thermodynamics and XPS research revealed the surface complexation mechanism between the uranium (VI) ions and the amidoxime groups. It has demonstrated good adsorption capacity in simulated nuclear wastewater containing various ions. Under the enhancement of photothermal effect, the uranium adsorption capacity of GC-PAO for nuclear wastewater reached 512.96 mg·g^-1 within 4 h. Therefore, the GC-PAO composite adsorbent can be considered as a potential candidate for the treatment of radioactive nuclear wastewater.