O2 activation by nonheme iron complexes: A monomeric Fe(III)-Oxo complex derived from O2

C. E. MacBeth; A. P. Golombek; Jr Young; C. Yang; K. Kuczera; M. P. Hendrich; A. S. Borovik

doi:10.1126/science.289.5481.938

O₂ activation by nonheme iron complexes: A monomeric Fe(III)-Oxo complex derived from O₂

C. E. MacBeth, A. P. Golombek, Jr Young, C. Yang, K. Kuczera, M. P. Hendrich, A. S. Borovik

Chemistry (Twin Cities)

Research output: Contribution to journal › Article › peer-review

374 Scopus citations

Abstract

Iron species with terminal oxo ligands are implicated as key intermediates in several synthetic and biochemical catalytic cycles. However, there is a dearth of structural information regarding these types of complexes because their instability has precluded isolation under ambient conditions. The isolation and structural characterization of an iron(III) complex with a terminal oxo ligand, derived directly from dioxygen (O₂), is reported. A stable structure resulted from placing the oxoiron unit within a synthetic cavity lined with hydrogen-bonding groups. The cavity creates a microenvironment around the iron center that aids in regulating O₂ activation and stabilizing the oxoiron unit. These cavities share properties with the active sites of metalloproteins, where function is correlated strongly with site structure.

Original language	English (US)
Pages (from-to)	938-941
Number of pages	4
Journal	Science
Volume	289
Issue number	5481
DOIs	https://doi.org/10.1126/science.289.5481.938
State	Published - Aug 11 2000

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abstract = "Iron species with terminal oxo ligands are implicated as key intermediates in several synthetic and biochemical catalytic cycles. However, there is a dearth of structural information regarding these types of complexes because their instability has precluded isolation under ambient conditions. The isolation and structural characterization of an iron(III) complex with a terminal oxo ligand, derived directly from dioxygen (O2), is reported. A stable structure resulted from placing the oxoiron unit within a synthetic cavity lined with hydrogen-bonding groups. The cavity creates a microenvironment around the iron center that aids in regulating O2 activation and stabilizing the oxoiron unit. These cavities share properties with the active sites of metalloproteins, where function is correlated strongly with site structure.",

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T1 - O2 activation by nonheme iron complexes

T2 - A monomeric Fe(III)-Oxo complex derived from O2

AU - MacBeth, C. E.

AU - Golombek, A. P.

AU - Young, Jr

AU - Yang, C.

AU - Kuczera, K.

AU - Hendrich, M. P.

AU - Borovik, A. S.

PY - 2000/8/11

Y1 - 2000/8/11

N2 - Iron species with terminal oxo ligands are implicated as key intermediates in several synthetic and biochemical catalytic cycles. However, there is a dearth of structural information regarding these types of complexes because their instability has precluded isolation under ambient conditions. The isolation and structural characterization of an iron(III) complex with a terminal oxo ligand, derived directly from dioxygen (O2), is reported. A stable structure resulted from placing the oxoiron unit within a synthetic cavity lined with hydrogen-bonding groups. The cavity creates a microenvironment around the iron center that aids in regulating O2 activation and stabilizing the oxoiron unit. These cavities share properties with the active sites of metalloproteins, where function is correlated strongly with site structure.

AB - Iron species with terminal oxo ligands are implicated as key intermediates in several synthetic and biochemical catalytic cycles. However, there is a dearth of structural information regarding these types of complexes because their instability has precluded isolation under ambient conditions. The isolation and structural characterization of an iron(III) complex with a terminal oxo ligand, derived directly from dioxygen (O2), is reported. A stable structure resulted from placing the oxoiron unit within a synthetic cavity lined with hydrogen-bonding groups. The cavity creates a microenvironment around the iron center that aids in regulating O2 activation and stabilizing the oxoiron unit. These cavities share properties with the active sites of metalloproteins, where function is correlated strongly with site structure.

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O₂ activation by nonheme iron complexes: A monomeric Fe(III)-Oxo complex derived from O₂

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