Silver Nanoparticles Embedded in Gelatin Biopolymer Hydrogel as Catalyst for Reductive Degradation of Pollutants

“…However, post exfoliation, variation in interplanar spacing was found and the GNP peak at 2 θ = 26.3° and the dominant peak of MoS 2 at 2 θ = 14.2° along with the generation of a hump around 2 θ = 20° arising from gelatin were observed. 56 The presence of a signature diffraction pattern of both graphite and MoS 2 in the exfoliated sheets confirms the crystalline nature which usually was not found with the oxidation-based method. 57…”

Gelatin-assisted co-exfoliation of graphene nanoplatelets/MoS₂for high-performance supercapacitors

“…However, post exfoliation, variation in interplanar spacing was found and the GNP peak at 2 θ = 26.3° and the dominant peak of MoS 2 at 2 θ = 14.2° along with the generation of a hump around 2 θ = 20° arising from gelatin were observed. 56 The presence of a signature diffraction pattern of both graphite and MoS 2 in the exfoliated sheets confirms the crystalline nature which usually was not found with the oxidation-based method. 57…”

Gelatin-assisted co-exfoliation of graphene nanoplatelets/MoS₂for high-performance supercapacitors

“…AgNPs shows more advantages such as sharp extinction bands, high extinction coefficients and field enhancements for probes [13,14]. AgNPs have been successfully employed for the catalytic degradation of dyes and pollutants [15,16]. AgNPs successfully employed as green and robust catalysts in different chemical reactions involving catalysis and organic transformations [17,18].…”

Eco-friendly synthesis of silver nanoparticles using leaf extract of Flemingia wightiana: spectral characterization, antioxidant and anticancer activity studies

“…Carbon-based materials, due to their unique properties such as light weight, many varieties of forms, doping capability with hetero atoms, low-cost and ease of processability, are suitable supports for heterogeneous catalysts. 22–24 Hydrocarbons such as chitosan, 25,26 starch, 27–29 gelatin, 30–32 alginate 33,34 and cellulose 35,36 can be used as low-cost supports for the synthesis of heterogeneous catalysts. Among them, cellulose has received a lot of consideration due to its large surface area, good mechanical properties and almost inexhaustible, biodegradable, and renewable properties.…”

Novel cellulose supported 1,2-bis(4-aminophenylthio)ethane Ni(ii) complex (Ni^II(BAPTE)(NO₃)₂-Cell) as an efficient nanocatalyst for the synthesis of spirooxindole derivatives