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1. Kinetics Experiment on the Reaction of Coumarin-102 with NaOH Using Smartphone Fluorescence Imaging

   https://doi.org/10.1021/acs.jchemed.4c01052  

   Wink, Donald J; Huma, Loredana C; Demirbuga, Mustafa; Zhang, Hongyang; Jursich, Gregory; Stec, Ewa (March 2025, Journal of Chemical Education)

   Holme, Thomas A (Ed.)

   This paper reports a laboratory experiment that determines the kinetics of the reaction of coumarin-102, a fluorescent dye, with sodium hydroxide. The reaction is studied by monitoring the loss of coumarin-102 fluorescence during ring-opening saponification by hydroxide using smartphone cameras and near-UV (“blacklight”) illumination. The order of the reaction in coumarin-102 is determined by examining the time course of fluorescence decay over time and fitting the data to integrated rate law models. The order of the reaction in sodium hydroxide is determined by varying the concentration of NaOH and comparing the impact on the rate of the reaction. This represents an easy-to-implement kinetics experiment that uses an engaging phenomenon (fluorescence), a convenient data-acquisition technology (smartphone cameras) and an important image-processing software program (ImageJ). This gives students the ability to work with the determination of the rate law for both coumarin-102 and for sodium hydroxide, using complementary methods. This experiment is both informative and enjoyable for students, enabling them to directly observe kinetics—quite literally with open eyes—making scientific concepts more tangible and engaging. The experiment has also been adapted in a manner consistent with the principles of evidence-centered design using content of kinetics and the scientific practice of mathematical reasoning. 

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2. In situ quasi-elastic neutron scattering study on the water dynamics and reaction mechanisms in alkali-activated slags

   https://doi.org/10.1039/c9cp00889f  

   Gong, Kai; Cheng, Yongqiang; Daemen, Luke L.; White, Claire E. (May 2019, Physical Chemistry Chemical Physics)

   null (Ed.)

   In this study, in situ quasi-elastic neutron scattering (QENS) has been employed to probe the water dynamics and reaction mechanisms occurring during the formation of NaOH- and Na 2 SiO 3 -activated slags, an important class of low-CO 2 cements, in conjunction with isothermal conduction calorimetry (ICC), Fourier transform infrared spectroscopy (FTIR) analysis and N 2 sorption measurements. We show that the single ICC reaction peak in the NaOH-activated slag is accompanied with a transformation of free water to bound water (from QENS analysis), which directly signals formation of a sodium-containing aluminum-substituted calcium–silicate–hydrate (C–(N)–A–S–H) gel, as confirmed by FTIR. In contrast, the Na 2 SiO 3 -activated slag sample exhibits two distinct reaction peaks in the ICC data, where the first reaction peak is associated with conversion of constrained water to bound and free water, and the second peak is accompanied by conversion of free water to bound and constrained water (from QENS analysis). The second conversion is attributed to formation of the main reaction product ( i.e. , C–(N)–A–S–H gel) as confirmed by FTIR and N 2 sorption data. Analysis of the QENS, FTIR and N 2 sorption data together with thermodynamic information from the literature explicitly shows that the first reaction peak is associated with the formation of an initial gel (similar to C–(N)–A–S–H gel) that is governed by the Na + ions and silicate species in Na 2 SiO 3 solution and the dissolved Ca/Al species from slag. Hence, this study exemplifies the power of in situ QENS, when combined with laboratory-based characterization techniques, in elucidating the water dynamics and associated chemical mechanisms occurring in complex materials, and has provided important mechanistic insight on the early-age reactions occurring during formation of two alkali-activated slags. 

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3. Programmable C−N Bond Formation through Radical‐Mediated Chemistry in Plasma‐Microdroplet Fusion

   https://doi.org/10.1002/anie.202413122  

   Grooms, Alexander J; Huttner, Robert T; Stockwell, Mackenzie; Tadese, Leah; Marcelo, Isabella M; Kass, Anthony; Badu‐Tawiah, Abraham K (November 2024, Angewandte Chemie International Edition)

   Non‐thermal plasma discharge produced in the wake of charged microdroplets is found to facilitate catalyst‐free radical mediated hydrazine cross‐coupling reactions without the use of external light source, heat, precious metal complex, or trapping agents. A plasma‐microdroplet fusion platform is utilized for introduction of hydrazine reagent that undergoes homolytic cleavage forming radical intermediate species. The non‐thermal plasma discharge that causes the cleavage originates from a chemically etched silica capillary. The coupling of the radical intermediates gives various products. Plasma‐microdroplet fusion occurs online in a programmable reaction platform allowing direct process optimization and product validation via mass spectrometry. The platform is applied herein with a variety of hydrazine substrates, enabling i) self‐coupling to form secondary amines with identical N‐substitutions, ii) cross‐coupling to afford secondary amine with different N‐substituents, iii) cross‐coupling followed by in situ dehydrogenation to give the corresponding aryl‐aldimines with two unique N‐substitutions, and iv) cascade heterocyclic carbazole derivatives formation. These unique reactions were made possible in the charged microdroplet environment through our ability to program conditions such as reagent concentration (i. e., flow rate), microdroplet reactivity (i. e., presence or absence of plasma), and reaction timescale (i. e., operational mode of the source). The selected program is implemented in a co‐axial spray format, which is found to be advantageous over the conventional one‐pot single emitter electrospray‐based microdroplet reactions. 

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4. Relating the early‐age reaction kinetics and material property development in a model metakaolin geopolymer

   https://doi.org/10.1111/jace.20531  

   Egnaczyk, Thaddeus M; Quinn, Caitlin M; Wagner, Norman J (April 2025, Journal of the American Ceramic Society)

   Abstract Geopolymers, a class of alkali‐activated binders, are studied as sustainable alternatives to Ordinary Portland Cement due to their potential for CO₂emission reduction. However, the critical relationship between early‐age reaction kinetics, the development of material properties, and evolving chemical structure remains insufficiently explored, primarily because of the complexity of the underlying chemical reactions and the wide variety of geopolymer chemistries. To address this, we investigate the mechanism of early‐age (<72 h) strength development of a model metakaolin geopolymer by measuring curing kinetics using isothermal calorimetry, material property development via rheology, and chemical coordination at distinct extents of reaction via²⁹Si and²⁷Al NMR. A novel approach of collecting solid‐state²⁹Si and²⁷Al NMR spectra at low temperature (−17°C) successfully quenches the geopolymer reaction, allowing for spectrum collection at a desired extent of reaction despite long²⁹Si NMR spectrum collection times. Applying the Avrami kinetic model to deconvoluted calorimetry data enables independent analysis of dissolution and polycondensation/crosslinking reactions. From these data, the gel reaction product mass fraction is estimated, revealing an exponential relationship with the storage modulus in the activated metakaolin slurry. This study provides new insights into the interconnected dynamics of molecular chemistry, reaction kinetics, rheology, and strength development, offering a semi‐empirical framework for understanding property evolution in geopolymers more broadly. 

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5. Kinetics and Mass Yields of Aqueous Secondary Organic Aerosol from Highly Substituted Phenols Reacting with a Triplet Excited State

   https://doi.org/10.1021/acs.est.1c00575  

   Ma, Lan; Guzman, Chrystal; Niedek, Christopher; Tran, Theodore; Zhang, Qi; Anastasio, Cort. (January 2021, Environmental science technology)

   null (Ed.)

   Biomass burning emits large amounts of phenols, which can partition into cloud/fog drops and aerosol liquid water (ALW) and react to form aqueous secondary organic aerosol (aqSOA). Triplet excited states of organic compounds (3C*) are a likely oxidant, but there are no rate constants with highly substituted phenols that have high Henry’s law constants (KH) and are likely important in ALW. To address this gap, we investigated the kinetics of six highly substituted phenols with the triplet excited state of 3,4-dimethoxybenzaldehyde. Second-order rate constants at pH 2 are all fast, (2.6 - 4.6)E9 M-1 s-1, while values at pH 5 are 2 to 5 times smaller. Rate constants are reasonably described by a quantitative structure-activity relationship with phenol oxidation potentials, allowing rate constants of other phenols to be predicted. Triplet-phenol kinetics are unaffected by ammonium sulfate, sodium chloride, galactose (a biomass-burning sugar), or Fe(III). In contrast, ammonium nitrate increases the rate of phenol loss by making hydroxyl radical, while Cu(II) inhibits phenol decay. Mass yields of aqueous SOA from triplet reactions are large and range from 59 to 99%. Calculations using our data along with previous oxidant measurements indicate that phenols with high KH can be an important source of aqSOA in ALW, with 3C* typically the dominant oxidant. 

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