Room-Temperature H2 Splitting and N2-Hydrogenation Induced by a Neutral LuII Complex

Evangelos Papangelis; Luca Demonti; Iker del Rosal; Angus Shephard; Laurent Maron; Grégory Nocton; Thomas Simler

doi:10.1021/jacs.4c18416

Room-Temperature H₂ Splitting and N₂-Hydrogenation Induced by a Neutral Lu^II Complex

Evangelos Papangelis
, Luca Demonti
, Iker del Rosal
, Angus Shephard
, Laurent Maron
, Grégory Nocton
, Thomas Simler

CNRS
University of Athens
Université Paul Sabatier

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

The direct splitting of H₂ and N₂ molecules is a challenging reaction that is closely related to the Haber-Bosch ammonia synthesis process. Until now, such reactivity has never been observed in the case of molecular lanthanide species. Here, we show that careful selection of the ligand scaffold allows the isolation and characterization of a kinetically stable but highly reactive Lu^II complex. This divalent lanthanide species enables direct H₂ splitting at room temperature, an unknown reactivity in lanthanide chemistry, which has been fully corroborated by DFT calculations. In addition, the Lu^II complex readily binds N₂, leading to an end-on coordinated diazenido (N₂)^2- lanthanide complex. The latter can be hydrogenated under very smooth conditions (ca. 1.2 bar H₂, ambient temperature) to form a unique Lu^III-NH₂ complex. Direct N₂ hydrogenation and cleavage are thus accessible using low-valent molecular rare-earth metal complexes.

langue originale	Anglais
Pages (de - à)	9752-9763
Nombre de pages	12
journal	Journal of the American Chemical Society
Volume	147
Numéro de publication	11
Les DOIs	https://doi.org/10.1021/jacs.4c18416
état	Publié - 19 mars 2025
Modification externe	Oui

Accès au document

10.1021/jacs.4c18416

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title = "Room-Temperature H2 Splitting and N2-Hydrogenation Induced by a Neutral LuII Complex",

abstract = "The direct splitting of H2 and N2 molecules is a challenging reaction that is closely related to the Haber-Bosch ammonia synthesis process. Until now, such reactivity has never been observed in the case of molecular lanthanide species. Here, we show that careful selection of the ligand scaffold allows the isolation and characterization of a kinetically stable but highly reactive LuII complex. This divalent lanthanide species enables direct H2 splitting at room temperature, an unknown reactivity in lanthanide chemistry, which has been fully corroborated by DFT calculations. In addition, the LuII complex readily binds N2, leading to an end-on coordinated diazenido (N2)2- lanthanide complex. The latter can be hydrogenated under very smooth conditions (ca. 1.2 bar H2, ambient temperature) to form a unique LuIII-NH2 complex. Direct N2 hydrogenation and cleavage are thus accessible using low-valent molecular rare-earth metal complexes.",

author = "Evangelos Papangelis and Luca Demonti and \{del Rosal\}, Iker and Angus Shephard and Laurent Maron and Gr{\'e}gory Nocton and Thomas Simler",

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T1 - Room-Temperature H2 Splitting and N2-Hydrogenation Induced by a Neutral LuII Complex

AU - Papangelis, Evangelos

AU - Demonti, Luca

AU - del Rosal, Iker

AU - Shephard, Angus

AU - Maron, Laurent

AU - Nocton, Grégory

AU - Simler, Thomas

PY - 2025/3/19

Y1 - 2025/3/19

N2 - The direct splitting of H2 and N2 molecules is a challenging reaction that is closely related to the Haber-Bosch ammonia synthesis process. Until now, such reactivity has never been observed in the case of molecular lanthanide species. Here, we show that careful selection of the ligand scaffold allows the isolation and characterization of a kinetically stable but highly reactive LuII complex. This divalent lanthanide species enables direct H2 splitting at room temperature, an unknown reactivity in lanthanide chemistry, which has been fully corroborated by DFT calculations. In addition, the LuII complex readily binds N2, leading to an end-on coordinated diazenido (N2)2- lanthanide complex. The latter can be hydrogenated under very smooth conditions (ca. 1.2 bar H2, ambient temperature) to form a unique LuIII-NH2 complex. Direct N2 hydrogenation and cleavage are thus accessible using low-valent molecular rare-earth metal complexes.

AB - The direct splitting of H2 and N2 molecules is a challenging reaction that is closely related to the Haber-Bosch ammonia synthesis process. Until now, such reactivity has never been observed in the case of molecular lanthanide species. Here, we show that careful selection of the ligand scaffold allows the isolation and characterization of a kinetically stable but highly reactive LuII complex. This divalent lanthanide species enables direct H2 splitting at room temperature, an unknown reactivity in lanthanide chemistry, which has been fully corroborated by DFT calculations. In addition, the LuII complex readily binds N2, leading to an end-on coordinated diazenido (N2)2- lanthanide complex. The latter can be hydrogenated under very smooth conditions (ca. 1.2 bar H2, ambient temperature) to form a unique LuIII-NH2 complex. Direct N2 hydrogenation and cleavage are thus accessible using low-valent molecular rare-earth metal complexes.

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