SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2912241061> ?p ?o ?g. }

Showing items 1 to 100 of ±163 with 100 items per page.

W2912241061 endingPage "221" @default.
W2912241061 startingPage "221" @default.
W2912241061 abstract "We report for the first time a procedure in which Nafion/Graphite nanoplatelets (GNPs) thin films are fabricated using a modified layer-by-layer (LbL) method. The method consists of dipping a substrate (quartz and/or glassy carbon electrodes) into a composite solution made of Nafion and GNPs dissolved together in ethanol, followed by washing steps in water. This procedure allowed the fabrication of multilayer films of (Nafion/GNPs)n by means of hydrogen bonding and hydrophobic‒hydrophobic interactions between Nafion, GNPs, and the corresponding solid substrate. The average thickness of each layer evaluated using profilometer corresponds to ca. 50 nm. The as-prepared Nafion/GNPs LbL films were characterized using various spectroscopic techniques such as X-ray photoelectron spectroscopy (XPS), energy-dispersive X-ray spectroscopy (EDS), FTIR, and optical microscopy. This characterization highlights the presence of oxygen functionalities that support a mechanism of self-assembly via hydrogen bonding interactions, along with hydrophobic interactions between the carbon groups of GNPs and the Teflon-like (carbon‒fluorine backbone) of Nafion. We showed that Nafion/GNPs LbL films can be deposited onto glassy carbon electrodes and utilized for the voltammetric detection of caffeine in beverages. The results showed that Nafion/GNPs LbL films can achieve a limit of detection for caffeine (LoD) of 0.032 μM and linear range between 20‒250 μM using differential pulse voltammetry, whereas, using cyclic voltammetry LoD and linear range were found to be 24 μM and 50‒5000 μM, respectively. Voltammetric detection of caffeine in beverages showed good agreement between the values found experimentally and those reported by the beverage producers. The values found are also in agreement with those obtained using a standard spectrophotometric method. The proposed method is appealing because it allows the fabrication of Nafion/GNPs thin films in a simple fashion using a single-step procedure, rather than using composite solutions with opposite electrostatic charge, and also allows the detection of caffeine in beverages without any pre-treatment or dilution of the real samples. The proposed method is characterized by a fast response time without apparent interference, and the results were competitive with those obtained with other materials reported in the literature." @default.
W2912241061 created "2019-02-21" @default.
W2912241061 creator A5019718006 @default.
W2912241061 creator A5035692672 @default.
W2912241061 creator A5081261261 @default.
W2912241061 creator A5087836142 @default.
W2912241061 date "2019-02-07" @default.
W2912241061 modified "2023-10-16" @default.
W2912241061 title "Voltammetric Detection of Caffeine in Beverages at Nafion/Graphite Nanoplatelets Layer-by-Layer Films" @default.
W2912241061 cites W1878474542 @default.
W2912241061 cites W1966062300 @default.
W2912241061 cites W1967935495 @default.
W2912241061 cites W1972184709 @default.
W2912241061 cites W1979475806 @default.
W2912241061 cites W1988310931 @default.
W2912241061 cites W1996521710 @default.
W2912241061 cites W2005062196 @default.
W2912241061 cites W2008303532 @default.
W2912241061 cites W2010798322 @default.
W2912241061 cites W2011575459 @default.
W2912241061 cites W2011600639 @default.
W2912241061 cites W2012553932 @default.
W2912241061 cites W2013436076 @default.
W2912241061 cites W2014935324 @default.
W2912241061 cites W2018928748 @default.
W2912241061 cites W2019441196 @default.
W2912241061 cites W2022181343 @default.
W2912241061 cites W2026854602 @default.
W2912241061 cites W2033504587 @default.
W2912241061 cites W2035404321 @default.
W2912241061 cites W2041531691 @default.
W2912241061 cites W2042885362 @default.
W2912241061 cites W2052299213 @default.
W2912241061 cites W2052628187 @default.
W2912241061 cites W2057104805 @default.
W2912241061 cites W2058122340 @default.
W2912241061 cites W2059543311 @default.
W2912241061 cites W2059628030 @default.
W2912241061 cites W2061429990 @default.
W2912241061 cites W2067177732 @default.
W2912241061 cites W2077820374 @default.
W2912241061 cites W2079438373 @default.
W2912241061 cites W2081200721 @default.
W2912241061 cites W2084119931 @default.
W2912241061 cites W2086057406 @default.
W2912241061 cites W2094255943 @default.
W2912241061 cites W2105685140 @default.
W2912241061 cites W2107157585 @default.
W2912241061 cites W2119806837 @default.
W2912241061 cites W2128654538 @default.
W2912241061 cites W2212430710 @default.
W2912241061 cites W2225020320 @default.
W2912241061 cites W2233797376 @default.
W2912241061 cites W2291688091 @default.
W2912241061 cites W2292055628 @default.
W2912241061 cites W2312850474 @default.
W2912241061 cites W2321368018 @default.
W2912241061 cites W2324366651 @default.
W2912241061 cites W2338545648 @default.
W2912241061 cites W2588626582 @default.
W2912241061 cites W2599526570 @default.
W2912241061 cites W2606594247 @default.
W2912241061 cites W2607235648 @default.
W2912241061 cites W2611762087 @default.
W2912241061 cites W2754364436 @default.
W2912241061 cites W2756256477 @default.
W2912241061 cites W2766889474 @default.
W2912241061 cites W2773596706 @default.
W2912241061 cites W2790844502 @default.
W2912241061 cites W2804614807 @default.
W2912241061 cites W2805988393 @default.
W2912241061 cites W2895233122 @default.
W2912241061 cites W2896832441 @default.
W2912241061 cites W2902518347 @default.
W2912241061 cites W4382023229 @default.
W2912241061 cites W768012932 @default.
W2912241061 doi "https://doi.org/10.3390/nano9020221" @default.
W2912241061 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/6410159" @default.
W2912241061 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/30736450" @default.
W2912241061 hasPublicationYear "2019" @default.
W2912241061 type Work @default.
W2912241061 sameAs 2912241061 @default.
W2912241061 citedByCount "14" @default.
W2912241061 countsByYear W29122410612019 @default.
W2912241061 countsByYear W29122410612020 @default.
W2912241061 countsByYear W29122410612021 @default.
W2912241061 countsByYear W29122410612022 @default.
W2912241061 countsByYear W29122410612023 @default.
W2912241061 crossrefType "journal-article" @default.
W2912241061 hasAuthorship W2912241061A5019718006 @default.
W2912241061 hasAuthorship W2912241061A5035692672 @default.
W2912241061 hasAuthorship W2912241061A5081261261 @default.
W2912241061 hasAuthorship W2912241061A5087836142 @default.
W2912241061 hasBestOaLocation W29122410611 @default.
W2912241061 hasConcept C104779481 @default.
W2912241061 hasConcept C113196181 @default.
W2912241061 hasConcept C127413603 @default.
W2912241061 hasConcept C140205800 @default.