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Unleashing Superior Hydrogen Storage of Magnesium Hydride via Vanadium-Doped Bimetallic MXene

Yitian Wu, Zhenluo Yuan, Yaojie Zhang, Qiuming Peng, Shumin Han, Yanping Fan, Baozhong Liu

2025Inorganic Chemistry12 citationsDOI

Abstract

Magnesium hydride (MgH 2 ) has been recognized as a promising hydrogen storage material because of its low cost and high hydrogen capacity. However, the sluggish kinetics and high operating temperature hindered its utilization. Herein, vanadium-substituted titanium-based bimetallic MXene (Ti 3– n V n C 2 ) was prepared to boost the hydrogen storage efficiency of MgH 2 . The incorporation of 5 wt % Ti 2.2 V 0.8 C 2 dramatically decreased the dehydrogenation temperature of MgH 2 and improved its kinetics and cyclic stability. The MgH 2 -5 wt % Ti 2.2 V 0.8 C 2 started to release hydrogen at 165 °C, and it released 7.0 wt % H 2 in 30 min at 220 °C and took in 5.3 wt % H 2 in 2 h at 75 °C, showing excellent kinetics. In addition, the activation energy of MgH 2 -added Ti 2.2 V 0.8 C 2 was 80.81 ± 3.29 kJ mol –1, which is lower than that of the most Ti-/or V-based catalyst-doped MgH 2 systems. Mechanism analysis reveals that the remarkably enhanced hydrogen storage performance is ascribed to the stable existence and uniform distribution of Ti-species (Ti 0 and Titanium hydride) and V-species (V 0 and V 5+ ), which facilitated the rapid hydrogen absorption/desorption of MgH 2 and ensured its stable hydrogen storage capacity. This study offers valuable perspectives for the assembly and design of bimetallic catalysts within the realm of solid-state hydrogen storage materials.

Topics & Concepts

ChemistryBimetallic stripHydrogen storageVanadiumHydrideDopingMagnesium hydrideMagnesiumInorganic chemistryHydrogenCatalysisOrganic chemistryOptoelectronicsPhysicsHydrogen Storage and MaterialsMXene and MAX Phase MaterialsAmmonia Synthesis and Nitrogen Reduction
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