Although the metathesis of internal alkynes has been known for more than 40 years, [1] its importance as a synthetic tool has not undergone a growth similar to that of the related metathesis of alkenes. [2] Unquestionably, the success of the latter reaction is largely based on the availability of highly active and well-defined homogeneous catalysts with sufficient air stability and broad functional-group tolerance, [2b, 3] whereas comparatively few systems are known that live up to the expectations for an alkyne metathesis catalyst with regard to its activity, substrate compatibility, and required reaction temperature. [4,5] Among such catalysts, the well-defined, prototypical Schrocktype alkylidyne complex 1 has found the broadest use ( Figure 1), [6] although it usually requires elevated reaction temperatures of about 80 8C and relatively high catalyst loadings (10-20 mol %). [2h, 7] Drawing on the structure of 1, we recently introduced imidazolin-2-iminato alkylidyne complexes of type 2 (Figure 1), which can either be synthesized from WCl 6 (M = W; R = tBu) [8] or, more conveniently, from [M(CO) 6 ] (M= W, Mo; R = Ph). [9] The tungsten systems proved to be particularly efficient in promoting alkyne cross-metathesis (ACM) and ringclosing alkyne metathesis (RCAM) even at room temperature and low catalyst concentrations (1 mol %). [8] Moreover, these catalysts were shown to be compatible with a range of functional groups. [9] Recently, Fürstner and co-workers established a new class of molybdenum nitride and alkylidyne complexes containing triphenylsilanolate (Ph 3 SiO) ligands, [10] with the diethyl ether complex 3 outperforming most of the other Mo-based catalyst systems. [11] Notably, the performance was further improved by the addition of molecular sieve (MS 5 ) to adsorb 2-butyne, which is usually formed during the metathesis reaction. In addition, this catalyst was recently employed for the synthesis of several naturally occurring macrolactides, [12] confirming the great potential of alkyne metathesis as a tool in organic synthetic methodology. However, the corresponding tungsten complexes of the type [PhCW(OSiPh 3 ) 3 L] have not, to date, been synthesized in a similar fashion to that described for 3. [11] Independently of Fürstner's approach and inspired by the work of CopØret, [13] we aimed at the preparation of related tri-(tert-butoxy)silanolate-supported tungsten alkylidyne complexes, since the silanol HOSi(OtBu) 3 can be regarded as a model for Si-OH sites present on silica surfaces. [14] Accordingly, complexes of the type [RCW{OSi(OtBu) 3 } 3 ] could be regarded as homogeneous models for silica-supported alkyne metathesis catalysts, a few examples of which have been reported ( Figure 2). For instance, the well-defined heterogeneous rhenium catalyst 4 promotes both olefin and alkyne metathesis, [15] whereas the groups of Basset and Moore reported grafting reactions on amorphous silica for the alkylidyne complexes [tBuCW(CH 2 tBu)(ODipp) 2 ] (Dipp = 2,6-diisopropylphenyl) and [EtCMo{N(tBu)Ar} 3 ]...
