Novel nanoporous magnetic cellulose−chitosan composite microspheres (NMCMs) were prepared by sol−gel transition method using ionic liquids as solvent for the sorption of Cu(II). The composite microspheres were studied by scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR), thermogravimetric analysis (TGA), X-ray diffraction (XRD), and vibrating sample magnetometry (VSM). Subsequelty, the adsorption of Cu(II) to NMCMs was investigated systematically with varried parameters such as pH, contact time, and initial concentration. Results revealed that the composite microspheres exhibited efficient adsorption capacity of Cu(II) from aqueous solution, due to their favorable chelating groups in structure. The adsorption process was best described by a pseudo-second-order kinetic model, while isotherm modeling revealed that the Langmuir equation better describe the adsorption of Cu(II) on NMCMs as compared to Freundlich model. Moreover, the loaded NMCMs can be easily regenerated with HCl and reused repeatedly for Cu(II) adsorption up to five cycles. The environmental friendly microspheres were expected to be a promising candidate for future practical use in heavy metal ions removal.
Highlights▪ A simple in-situ oxidation approach was developed to prepare MnO2/NCNT. ▪ Prepared samples showed boosted activity for HCHO degradation at low temperature.▪ MnO2/NCNT exhibited better activity and selectivity than MnO2/CNT. ▪ Mechanism of improved HCHO oxidation by MnO2/NCNT was revealed.
Solar vapor generation is a renewable
and hopeful technology for
obtaining freshwater from underground water, dyeing wastewater, and
seawater. Herein, hierarchical MnO2 nanosheets grown on
cotton fabric (Mn-CF) have been developed for solar-driven water evaporation.
Black MnO2 nanosheets and nanoflowers are in situ chemically
deposited on cotton fabric (CF), which leads to a solar absorption
ability as high as 95% from 300 to 2500 nm. Due to the synergistic
effect of the super-hydrophilic CF and hierarchical MnO2 nanosheets, Mn-CF results in a water evaporation rate of 1.40 kg
m–2 h–1 with the photothermal
conversion efficiency of 87.48% under 1 sun illumination (1 kW m–2). During the desalination test, Mn-CF can be renewed
by washing off the steamed salts through a simple ultrasonication
or hand-washing. Moreover, Mn-CF remains stable after 40 cycles, each
lasting 1 h under 1 sun irradiation. A Mn-CF-based solar steam generator
(Mn-CF-SSG) enables to effectively purifying simulated dyeing wastewater
and seawater using natural sunlight. The cost of preparing 1 m2 Mn-CF is about $1.5. This work provides a simple method to
prepare flexible and washable Mn-CF-SSG with low-cost and high efficiency
that has huge potential for practical application of seawater desalination.
To explore the attractive structural and semiconductive properties of two-dimensional bismuthene, exquisite heterojunctions with less interfacial mismatch between bismuthene and SnO 2 nanoparticle are coincidentally architected by a low-temperature procedure, based on a unique self-adaptive attribute of the two-dimensional structure of bismuthene, in combination with the lattice-matching attribute of adjacent lattice-spacing between bismuthene and SnO 2 . When applied in perovskite solar cells as an electron transport layer, the bismuthene−SnO 2 composite layer turns smoother and more transparent and endows higher crystallinity to the upper perovskite layer. Depending on highly conductive bismuthene along with semiconductive bismuthene−SnO 2 heterojunctions, the energy band of the integral composite layer is upshifted and the interfacial resistance between the composite layer and the perovskite layer is reduced, effectively accelerating the electron extraction without declining the hole-blocking, in comparison with the pure SnO 2 layer. A higher statistical average power conversion efficiency of 18.75% is achieved, compared to the counterpart of 17.35%, and it also maintains a high stability of almost 80% of its initial efficiency even in an ∼5% relative humidity environment for more than 800 h, in contrast to its counterpart, which maintains just 50% efficiency retention.
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