Litcius/Paper detail

Room Temperature Hydrogen Absorption of Mg/MgH<sub>2</sub> Catalyzed by BaTiO<sub>3</sub>

Joshua Adedeji Bolarin, Zhao Zhang, Hujun Cao, Zhi Li, Teng He, Ping Chen

2021The Journal of Physical Chemistry C25 citationsDOI

Abstract

This paper seeks to present notable insights into the catalytic behavior of a ferroelectric BaTiO3 nanomaterial at the boundary plane in the separation of MgH2 starting from 185 °C. The synergy between mechanical milling and enhanced electronic distribution at the surface of BaTiO3 aided magnesium to a remarkable absorption of 4.5 wt % H2 at room temperature under 30 bar within 20 h. The composite released H2 ∼ 5.7 wt % in 15 min at 310 °C and ∼5.1 wt % in 90 min at 250 °C. The lowered activation energy of decomposition was calculated to be ∼60 kJ/mol with a decomposition enthalpy of 72.3 kJ/mol-H2. The composite reversibly produced ∼5.7 wt % H2 across 20 cycles in less than 120 h at 300 °C. As revealed by detailed experimental results, the interplay between +4 and +3 states of titanium at “111” twin boundaries of BaTiO3, and the formation of oxygen vacancies, play an important role in improving the sorption kinetics and the reversibility of Mg/MgH2. Meanwhile, the anomalous ferroelectric character of the +2 state of barium around Ti–O and Mg after milling of BaTiO3 is also believed to slightly enhance MgH2 desorption enthalpy via a chemisorption process. Our findings have brought MgH2 a few steps closer to practical applications.

Topics & Concepts

Materials scienceChemisorptionEnthalpyBarium titanateCatalysisDesorptionHydrogenDecompositionActivation energyAbsorption (acoustics)MagnesiumFerroelectricityChemical engineeringPhysical chemistryInorganic chemistryChemistryThermodynamicsComposite materialMetallurgyAdsorptionCeramicOrganic chemistryDielectricEngineeringPhysicsOptoelectronicsHydrogen Storage and MaterialsSpacecraft and Cryogenic TechnologiesAmmonia Synthesis and Nitrogen Reduction