Conversion of organic waste into engineered metal-biochar composite is an effective way of enhancing biochar’s efficiency for adsorptive capture of phosphorus (P) from aqueous media. Thus, various strategies have been created for the production of metal-biochar composites; however, the complex preparation steps, high-cost metal salt reagent application, or extreme process equipment requirements involved in those strategies limited the large-scale production of metal-biochar composites. In this study, a novel biochar composite rich in magnesium oxides (MFBC) was directly produced through co-pyrolysis of magnesite with food waste; the product, MFBC was used to adsorptively capture P from solution and bio-liquid wastewater. The results showed that compared to the pristine food waste biochar, MFBC was a uniformly hybrid MgO biochar composite with a P capture capacity of 523.91 mg/g. The capture of P by MFBC was fitted using the Langmuir and pseudo-first-order kinetic models. The P adsorptive capture was controlled by MgHPO4 formation and electrostatic attraction, which was affected by the coexisting F− and CO32− ions. MFBC could recover more than 98% of P from the solution and bio-liquid wastewater. Although the P-adsorbed MFBC showed very limited reusability but it can be substituted for phosphate fertiliser in agricultural practices. This study provided an innovative technology for preparing MgO-biochar composite against P recovery from aqueous media, and also highlighted high-value-added approaches for resource utilization of bio-liquid wastewater and food waste.
Graphical Abstract
Temperature-sensing
media based on the fluorescence intensity ratio
(FIR) of upconversion materials that suffer from low sensitivity owing
to the small energy gap still have a need for new compounds with strong
upconversion luminescence (UCL). In this work, a series of MSc2O4:Er3+/Yb3+ (M = Mg, Ca,
Sr, and Ba) nanocrystals were prepared by a hydrothermal method using
NaOH alkaline solution. The structure, morphology, and UCL characteristics
of materials were investigated, and the red UCL of the CaSc2O4:Er3+/Yb3+ sample was dramatically
enhanced by a factor of ∼12, ∼23, and ∼2000 compared
with SrSc2O4, MgSc2O4,
and BaSc2O4 samples, respectively. By adjusting
alkali ions (Li+, Na+, K+), the UCL
intensities of CaSc2O4:Er3+/Yb3+ and SrSc2O4:Er3+/Yb3+ samples were further improved, especially in the presence
of Li+ ions. Excellent temperature-sensing behaviors are
realized for CaSc2O4:Er3+/Yb3+ and SrSc2O4:Er3+/Yb3+ samples in the presence of Li+ ions, in which
the maximum absolute sensitivity S
A values
are about 0.0041 and 0.0036 K–1 at 600 K and the
corresponding relative sensitivity S
R values
are expressed as 1197/T2 and 1129/T2 (the current
optimal S
R = 1289/T2), respectively.
The intense UCL and excellent S
A and S
R values indicate that CaSc2O4:Er3+/Yb3+ and SrSc2O4:Er3+/Yb3+ materials are promising candidates
for application in high-temperature sensors working under 980 nm excitation.
BiVO4 (BVO) is an excellent semiconductor material with suitable band gap for photocatalytic applications. The serious challenge is to solve the problem of electron-hole pairs recombination in pure BVO. Herein,...
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