Nordin, N.
, Tan, K.
, Wen, H.
, Ju, X.
, Zhou, W.
, Wu, H.
, He, T.
, Chen, P.
and Chua, Y.
(2025),
Delicate Tuning of Reaction Thermodynamics via Formation of Bimetal Phenoxide: Synthesis, Structure, and Hydrogen Storage Performance, ACS Applied Energy Materials, [online], https://doi.org/10.1021/acsaem.4c02824, https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=959156
(Accessed July 8, 2025)
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Delicate Tuning of Reaction Thermodynamics via Formation of Bimetal Phenoxide: Synthesis, Structure, and Hydrogen Storage Performance
Published
Author(s)
Nor I. Nordin, Khai C. Tan, Hong Wen, Xiaohua Ju, , , Teng He, Ping Chen, Yong Chua
Abstract
Arene-cycloalkane pairs are promising for hydrogen storage but often encounter unfavorable thermodynamic and kinetic issues in hydrogenation and dehydrogenation. A recent strategy to circumvent thermodynamic constraints involves introducing electron-donating alkali and alkaline earth metals into arene-cycloalkane pairs. However, excessive aromatic stabilization during the metalation of single-ring arene-cycloalkane leads to immoderate thermodynamic tuning in monometal organic compounds. To address this issue, we attempted to manipulate the metalation effect by introducing two metals with different electron-donating abilities to form a bimetal organic compound. Herein, the fabrication of the first bimetal organic compound with bimetal replacement of H in the −OH group of arene-cycloalkane pairs, i.e., phenol-cyclohexanol, was reported. The observed amount of H2 released from the reaction between the phenol and the metal hydride as well as the combined characterizations using X-ray diffraction and various spectroscopic techniques confirm the formation of lithium aluminum phenoxide, (LiAl)(C6H5O)4, and its phenolic complex (LiAl)(C6H5O)4·4(C6H5OH). Both compounds crystallize into tetrahedral structures but with different cation-ligand geometrical arrangements due to the presence of different ligands, i.e., C6H5O− and C6H5OH, in each structure. These bimetal organic compounds show potential for vehicular hydrogen storage, demonstrating efficient hydrogen uptake at 90 °C and partial reversibility at 140 °C.Citation
ACS Applied Energy Materials
Volume
8
Issue
10
Pub Type
Journals
Download Paper
Keywords
phenoxide, hydrogen storage, X-ray crystallography
Citation
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Created May 2, 2025, Updated July 7, 2025