Aqueous Chemistry of the Metallocene [Cp2MoCl2]BF4: Evidence of Autocatalytic Molybdenum(V) Reduction in Water

The aqueous chemistry of the air-stable Mo(V) metallocene [Cp2MoCl2]BF4 (1) yields an unexpected autocatalytic reduction when water is added to an acetonitrile solution of 1. While 1 yields the expected stable Cp–Mo ligation and rapid chloride hydrolysis in water, a Mo(V) → Mo(IV) reduction to the m...

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Veröffentlicht in:	Organometallics 2013-05, Vol.32 (10), p.2902-2907
Hauptverfasser:	Kuo, Louis Y, Shari’ati, Yusef A, Valente, Edward J
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Sprache:	eng
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creator	Kuo, Louis Y Shari’ati, Yusef A Valente, Edward J
description	The aqueous chemistry of the air-stable Mo(V) metallocene [Cp2MoCl2]BF4 (1) yields an unexpected autocatalytic reduction when water is added to an acetonitrile solution of 1. While 1 yields the expected stable Cp–Mo ligation and rapid chloride hydrolysis in water, a Mo(V) → Mo(IV) reduction to the metallocene Cp2MoCl2 (2) was evident. Under acidic conditions (pH ∼2) or trace amounts of water this reduction was slow enough to be monitored spectroscopically, and it is shown to be autocatalytic in aqueous 2. No reaction occurs when 1 and 2 are in the dichloride form in acetonitrile (i.e., no water). It is hypothesized that the added water serves two roles. First it initially reduces a small population of 1 to 2, and then as the aquated Mo(IV) metallocene, it catalyzes the reduction of the remaining Mo(V) in water. This is the first aqueous investigation of the Mo(V) metallocene, and it shows a novel and unprecedented autocatalytic reduction that is mediated by water.
doi_str_mv	10.1021/om301262u
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While 1 yields the expected stable Cp–Mo ligation and rapid chloride hydrolysis in water, a Mo(V) → Mo(IV) reduction to the metallocene Cp2MoCl2 (2) was evident. Under acidic conditions (pH ∼2) or trace amounts of water this reduction was slow enough to be monitored spectroscopically, and it is shown to be autocatalytic in aqueous 2. No reaction occurs when 1 and 2 are in the dichloride form in acetonitrile (i.e., no water). It is hypothesized that the added water serves two roles. First it initially reduces a small population of 1 to 2, and then as the aquated Mo(IV) metallocene, it catalyzes the reduction of the remaining Mo(V) in water. 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title	Aqueous Chemistry of the Metallocene [Cp2MoCl2]BF4: Evidence of Autocatalytic Molybdenum(V) Reduction in Water
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