Your search keyword '"Suggs K"' showing total 2 results

1. Doubly-Charged Negative Ions as Novel Tunable Catalysts: Graphene and Fullerene Molecules Versus Atomic Metals.

Author

Suggs K and Msezane AZ

Subjects

Anti-Bacterial Agents chemistry, Antiviral Agents chemistry, Biocompatible Materials chemistry, Catalysis, Oxidation-Reduction, Peroxides chemistry, Water chemistry, Anions chemistry, Cations chemistry, Fullerenes chemistry, Graphite chemistry, Metals chemistry

Abstract

The fundamental mechanism underlying negative-ion catalysis involves bond-strength breaking in the transition state (TS). Doubly-charged atomic/molecular anions are proposed as novel dynamic tunable catalysts, as demonstrated in water oxidation into peroxide. Density Functional Theory TS calculations have found a tunable energy activation barrier reduction ranging from 0.030 eV to 2.070 eV, with Si 2- , Pu 2- , Pa 2- and Sn 2- being the best catalysts; the radioactive elements usher in new application opportunities. C 60 2- significantly reduces the standard C 60 - TS energy barrier, while graphene increases it, behaving like cationic systems. According to their reaction barrier reduction efficiency, variation across charge states and systems, rank-ordered catalysts reveal their tunable and wide applications, ranging from water purification to biocompatible antiviral and antibacterial sanitation systems.

Published

2020

2. Fullerene Negative Ions: Formation and Catalysis.

Author

Felfli Z, Suggs K, Nicholas N, and Msezane AZ

Subjects

Algorithms, Catalysis, Electrons, Models, Chemical, Oxidation-Reduction, Water chemistry, Anions chemistry, Fullerenes chemistry

Abstract

We first explore negative-ion formation in fullerenes C 44 to C 136 through low-energy electron elastic scattering total cross sections calculations using our Regge-pole methodology. Then, the formed negative ions C 44 - to C 136 - are used to investigate the catalysis of water oxidation to peroxide and water synthesis from H 2 and O 2 . The exploited fundamental mechanism underlying negative-ion catalysis involves hydrogen bond strength-weakening/breaking in the transition state. Density Functional Theory transition state calculations found C 60 - optimal for both water and peroxide synthesis, C 100 - increases the energy barrier the most, and C 136 - the most effective catalyst in both water synthesis and oxidation to H 2 O 2 .

Published

2020