PVP-capped nickel nanoparticles: Synthesis, characterization and utilization as a glycerol electrosensor

“…Other metallic nanoparticles coated with PVP used in conducting inks for printed electronics, multilayer ceramic capacitors (MLCC) and magnetic devices were recently reported [124,136,[140][141][142] . Kubota et al used PVP as a surface modifier for synthesizing zero-valent Cu NPs, which are of interest as conductive inks for applications in printed electronics.…”

“…Nickel NPs were sintered using PVP as a binder for nanoinks, which can be applied in MLCC electrodes and printed electronics [141] . A group conducted by Neiva prepared electrochemical sensors for glycerol for applications in clinical diagnosis, pharmaceutical, food industries, and biofuels, by synthesizing Ni NPs and using PVP as a stabilization agent [142] . The electrochemical sensors proved a low detection limit, easiness of preparation and manipulation [142] .…”

“…A group conducted by Neiva prepared electrochemical sensors for glycerol for applications in clinical diagnosis, pharmaceutical, food industries, and biofuels, by synthesizing Ni NPs and using PVP as a stabilization agent [142] . The electrochemical sensors proved a low detection limit, easiness of preparation and manipulation [142] . Another study describing a synthesis method to obtain Ni NPs containing PVP as protective agent against nanoparticle aggregation is given by Couto et al [113] .…”

Poly(vinylpyrrolidone) – A Versatile Polymer for Biomedical and Beyond Medical Applications

“…Other metallic nanoparticles coated with PVP used in conducting inks for printed electronics, multilayer ceramic capacitors (MLCC) and magnetic devices were recently reported [124,136,[140][141][142] . Kubota et al used PVP as a surface modifier for synthesizing zero-valent Cu NPs, which are of interest as conductive inks for applications in printed electronics.…”

“…Nickel NPs were sintered using PVP as a binder for nanoinks, which can be applied in MLCC electrodes and printed electronics [141] . A group conducted by Neiva prepared electrochemical sensors for glycerol for applications in clinical diagnosis, pharmaceutical, food industries, and biofuels, by synthesizing Ni NPs and using PVP as a stabilization agent [142] . The electrochemical sensors proved a low detection limit, easiness of preparation and manipulation [142] .…”

“…A group conducted by Neiva prepared electrochemical sensors for glycerol for applications in clinical diagnosis, pharmaceutical, food industries, and biofuels, by synthesizing Ni NPs and using PVP as a stabilization agent [142] . The electrochemical sensors proved a low detection limit, easiness of preparation and manipulation [142] . Another study describing a synthesis method to obtain Ni NPs containing PVP as protective agent against nanoparticle aggregation is given by Couto et al [113] .…”

Poly(vinylpyrrolidone) – A Versatile Polymer for Biomedical and Beyond Medical Applications

“…The electrocatalytic activity of our Ni−NGr/GCE catalyst is significantly higher for glucose oxidation compared to nickel nanoparticles on porous silicon (PS) flower (Ni@PS‐CPE) using carbon paste electrode (CPE), nickel nanoparticles (NiNPs) on polyvinylpyrrolidone (PVP) stabilized graphene nanosheets (GNs) with chitosan (CS) (PVP‐GNs‐NiNPs‐CS), a glassy carbon disc electrode modified with multi‐walled carbon nanotubes and nickel (II) oxide (GC/MWCNT/NiO), chitosan‐reduced graphene oxide‐nickel nanoparticles (CS‐RGO‐NiNPs) on a screen‐printed electrode (SPE) and nano NiO modified carbon paste electrodes . However, the Ni−Co bi‐metal nanowire filled multiwall carbon nanotubes (MWCNT/Ni−Co) catalyst showed comparatively better electrocatalytic activity than our synthesized electrocatalyst, indicating the synergistic effect of nickel and cobalt on MWCNT/Ni−Co nanocomposite.…”

Nickel‐Nanoparticles on Doped Graphene: A Highly Active Electrocatalyst for Alcohol and Carbohydrate Electrooxidation for Energy Production

“…As nanopartículas apresentam propriedades diferentes daquelas exibidas pelo mesmo material quando estes se encontram em partículas de maior tamanho como bulks, e dentre suas principais características, o aumento da área superficial provocado pela modificação do eletrodo mostrou resultados promissores na detecção e quantificação do analito. 12,13 , platina 14,15 , ouro 16,17 , carbono vítreo [18][19][20][21][22] , entre outros; e materiais utilizados na modificação superficial, como óxidos metálicos 23,24 , polímeros condutores 25,26 e nanopartículas metálicas [27][28][29][30] .…”

Liberação controlada em ureia revestida empregando um sistema polimérico acrilato com foco no íon amônio