Graphene Aerogels Embedded with Boron Nitride Nanoparticles for Solar Energy Storage and Flame-Retardant Materials

Lin, Ke; Cheng, Yulong; Lu, Jiangtao; He, Miao; Zhou, Keqing

doi:10.1021/acsanm.3c04514

Cited by 7 publications

(1 citation statement)

References 74 publications

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“…Weakening surface anchoring of GO using a mild thermal or chemical prereduction method prior to hydrothermal reduction completely suppressed shell formation in the graphene hydrogel . Introducing porous carbon nanotubes, nanoparticles, and polymers into the graphene aerogel can prevent the excessive stacking of graphene nanosheets. For example, rGO/CNT-NH 2 /PDA(GCP) with three-dimensional cross-linked layered pores was prepared under hydrothermal conditions using PDA as a cross-linker and reducing agent …”

Section: Introductionmentioning

confidence: 99%

Polydopamine Enhanced Interactions of Graphene Nanosheets to Fabricate Graphene/Polydopamine Aerogels with Effectively Clear Organic Pollutants

He,

Zhao,

et al. 2024

Langmuir

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Graphene/polydopamine aerogels (GPD X AG, where X represents the weight ratio of DA•HCl to GO) were prepared by the chemical reduction of graphene oxide (GO) using dopamine (DA) and L-ascorbic acid as reducing agents. During the gelation process, DA was polymerized to form polydopamine (PDA). The introduction of PDA in the gelation of aerogels led to a deeper reduction of GO and stronger interactions between graphene nanosheets forced by covalent cross-linking and noncovalent bonding including π−π stacking and hydrogen bonding. The weight ratio of DA•HCl to GO influencing the formation and morphology of GPD X AG was explored. With the increasing content of DA in gelation, the reduction of GO and the cross-linking degree of graphene nanosheets were enhanced, and the resulting GPD X AG had a more regular pore distribution. Additionally, introducing PDA into GPD X AG improved its hydrophobicity because of the adhesion of PDA to a network of aerogels. GPD X AG exhibited a higher removal efficiency for organic pollutants than the controlled graphene aerogels (GAG). Specifically, the adsorption capacity of GPD X AG for organic solvents was superior to that of GAG, and organic solvent was completely separated from the oil/water mixture by GPD X AG. The equilibrium adsorption capacity of GPD X AG for malachite green (MG) was measured to be 768.50 mg/g, which was higher than that for methyl orange (MO). In MG/MO mixed solutions, aerogels had obvious adsorption selectivity for the cationic dye. The adsorption mechanism of aerogels for MG was also discussed by simulating adsorption kinetic models and adsorption isothermal models.

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