Chemical Kinetic Method for Active-Site Quantification in Fe-N-C Catalysts and Correlation with Molecular Probe and Spectroscopic Site-Counting Methods.
Jason S BatesJesse J MartinezMelissa N HallAbdulhadi A Al-OmariEamonn MurphyYachao ZengFang LuoMathias PrimbsDavide MengaNicolas BibentMoulay Tahar SougratiFriedrich E WagnerPlamen AtanassovGang WuPeter StrasserTim-Patrick FellingerFrédéric JaouenThatcher W RootShannon S StahlPublished in: Journal of the American Chemical Society (2023)
Mononuclear Fe ions ligated by nitrogen (FeN x ) dispersed on nitrogen-doped carbon (Fe-N-C) serve as active centers for electrocatalytic O 2 reduction and thermocatalytic aerobic oxidations. Despite their promise as replacements for precious metals in a variety of practical applications, such as fuel cells, the discovery of new Fe-N-C catalysts has relied primarily on empirical approaches. In this context, the development of quantitative structure-reactivity relationships and benchmarking of catalysts prepared by different synthetic routes and by different laboratories would be facilitated by the broader adoption of methods to quantify atomically dispersed FeN x active centers. In this study, we develop a kinetic probe reaction method that uses the aerobic oxidation of a model hydroquinone substrate to quantify the density of FeN x centers in Fe-N-C catalysts. The kinetic method is compared with low-temperature Mössbauer spectroscopy, CO pulse chemisorption, and electrochemical reductive stripping of NO derived from NO 2 - on a suite of Fe-N-C catalysts prepared by diverse routes and featuring either the exclusive presence of Fe as FeN x sites or the coexistence of aggregated Fe species in addition to FeN x . The FeN x site densities derived from the kinetic method correlate well with those obtained from CO pulse chemisorption and Mössbauer spectroscopy. The broad survey of Fe-N-C materials also reveals the presence of outliers and challenges associated with each site quantification approach. The kinetic method developed here does not require pretreatments that may alter active-site distributions or specialized equipment beyond reaction vessels and standard analytical instrumentation.
Keyphrases
- metal organic framework
- aqueous solution
- highly efficient
- blood pressure
- high resolution
- quantum dots
- visible light
- transition metal
- single molecule
- small molecule
- cell proliferation
- molecular docking
- signaling pathway
- risk assessment
- hydrogen peroxide
- peripheral blood
- electronic health record
- heavy metals
- molecularly imprinted
- ionic liquid
- human health
- electron transfer