scientific commentaries\(\def\hfill{\hskip 5em}\def\hfil{\hskip 3em}\def\eqno#1{\hfil {#1}}\)

STRUCTURAL CHEMISTRY

ISSN: 2053-2296

Volume 78| Part 6| June 2022| Pages 322-323

https://doi.org/10.1107/S2053229622004491

Open  access

Comment on molybdenum polyoxo clusters: from the `Blues' to the `Reds'

Bernt Krebs^a*

^aWestfälische Wilhelms-Universität Münster, Institut für Anorganische und Analytische Chemie, Corrensstrasse 28/30, D-48149 Münster, Germany
^*Correspondence e-mail: krebs@uni-muenster.de

Edited by P. Raithby, University of Bath, United Kingdom

Keywords: giant assemblies; building blocks; lanthanides; molecular wheels; molecular cages; molecular hybrids; polyoxomolybdate.

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Molybdenum `Blues', `Browns' and the recently discovered `Reds' are unquestionably some of the most impressive nanoscale architectures in polyoxometalate (POM) chemistry (Müller & Gouzerh, 2012; Lin et al., 2020). These three polyoxomolybdate classes, with the general formula [X<sub>a</sub>Y<sub>b</sub>H<sub>c</sub>Mo<sup>VI</sup><sub>x</sub>Mo<sup>V</sup><sub>y</sub>O<sub>z</sub>(H<sub>2</sub>O)<sub>v</sub>]<sup>n−</sup> (a and b = number of organic ligands and heteroelements, respectively; c = degree of protonation; x and y = number of Mo<sup>VI</sup> and reduced Mo<sup>V</sup> centres, respectively) are classified as gigantic mixed-valence (Mo<sup>V/VI</sup>) polyoxomolybdate clusters with various topologies ranging from `wheels' to `balls', `cages' and the `blue lemon', known to be the largest inorganic mol­ecule to date (Lin et al., 2020; Müller & Gouzerh, 2012). While the subclasses of molybdenum `Blues', `Browns' and `Reds' have the reduction of an acidified solution containing orthomolybdate ([MoO₄]²⁻) or hepta­molybdate (H_x[Mo₇O₂₄]^(6–x)–) in common, they can be distinguished by three characteristic features. Firstly, `Blues', `Browns' and `Reds' exhibit distinct degrees of reduction, with the `Blues' being the least (∼18%) and the `Reds' the most (up to ∼81%) reduced representatives (Ribó et al., 2022).

Secondly, in terms of molybdenum building blocks, wheel-shaped molybdenum `Blues' are composed of {MoO<sub>6</sub>} ({Mo<sub>1</sub>}), corner-sharing {Mo<sub>2</sub>O<sub>11</sub>} ({Mo<sub>2</sub>}) and the essential building block {Mo<sub>8</sub>O<sub>35</sub>} ({Mo<sub>8</sub>}), while the ball-shaped `Browns' consist of {Mo₁}, edge-sharing {Mo₂O₁₀} ({Mo₂′}) and {Mo₆O₂₇} ({Mo₆}) units (Fig. 1) (Müller & Gouzerh, 2012).

Figure 1 Polyhedral representation of the building blocks in mixed-valence polyoxomolybdates. Colour code: {MoO6} ({Mo1}), yellow; corner-sharing {Mo2O11} ({Mo2}), red; edge-sharing {Mo2O10} ({Mo2′}, ochre; {Mo6O27} ({Mo6}) and {Mo8O35} ({Mo8}), blue, with the central {MoO7} unit in cyan.

Remarkably, molybdenum `Reds' exclusively comprise {Mo₁} and {Mo₂′} units (Fig. 1) (Lin et al., 2020), hence requiring a comparably trickier synthetic approach than their blue counterparts, which necessitates the use of additional cluster-stabilizing coordinated ions (e.g. SO₃²⁻, 3d- and 4f-metal ions) (Lin et al., 2020; Ribó et al., 2022) to aggregate the {Mo₁} and dumbbell-shaped {Mo₂′} into larger clusters, consequently promoting mol­ecular growth (Ribó et al., 2022).

Contrary to molybdenum `Reds', additional ions (e.g. 3d- and 4f-metal ions) react differently in `Blue' systems as they are utilized here for fine-tuning the mol­ecular shape (Garrido Ribó et al., 2020) and alternating the mol­ecule's physical characteristics rather than spanning the cluster framework.

For instance, large electrophilic `open-shell' metal centres, such as 4f-metal ions, alter the overall charge, mol­ecular shape and size, and always cause a symmetry reduction of molybdenum `Blues' when introduced into their frameworks (Al-Sayed & Rompel, 2022). In `Blue' systems, however, 3d-metal ions seem to behave in a significantly opposite manner from their 4f counterparts considering their relatively small size which leaves them without any impact on the assembly of the {Mo₁}, {Mo₂} and {Mo₈} building blocks (Fig. 1).

Thirdly, in terms of functionalizability, the `Blues' and `Browns' can be organically functionalized, resulting in reaction vessels for studying confined mol­ecules. Organic hybridization is typically accomplished by attaching carboxyl groups to the cluster and nitro­gen-containing pendant groups in carb­oxy­lic acids. Such constructs are capable of promoting mol­ecular growth and triggering the formation of various guest@host architectures (Xuan et al., 2017, 2019; Imai et al., 2009). In stark contrast to their `Blue' counterparts, nothing is yet known about the organic hybridizability of molybdenum `Reds'. In the event of a molybdenum `Red' hybridization, the dumbbell-shaped and edge-sharing {Mo₂′} (Fig. 1) building blocks would have to be functionalized organically.

In this context, Al-Sayed et al. (2022) recently made a significant contribution, reporting a new binding mode of an organic hybridization reagent in mixed valence polyoxomolybdates (Al-Sayed et al., 2022). The organic functionalization of a dumb­bell-shaped and edge-sharing {Mo₂′} building block occurred through chelation of a pyridine derivative, as shown by the isolation of the [Mo₂O₂(OH)₄(C₆H₄NO₂)₂]²⁺ unit (Fig. 2) acting as a charge-balancing dication for the molybdenum `Blue' cluster Na<sub>4</sub>[Mo<sub>2</sub>O<sub>2</sub>(OH)<sub>4</sub>(C<sub>6</sub>H<sub>4</sub>NO<sub>2</sub>)<sub>2</sub>]<sub>2</sub>[Mo<sub>120</sub>Ce<sub>6</sub>O<sub>366</sub>H<sub>12</sub>(OH)<sub>2</sub>(H<sub>2</sub>O)<sub>76</sub>]∼200H<sub>2</sub>O. As `Reds' comprise a multitude of {Mo₂′} units, the outstanding work of Al-Sayed et al. (2022) represents a major synthetic step forward, since it showcases the first example of the N,O-chelation of {Mo₂′} units (Fig. 2).

Figure 2 Ball-and-stick representation of the organofunctionalized [Mo2O2-(OH)4(C6H4NO2)2]2+ unit acting as a charge-balancing dication for the Japanese rice-ball-shaped Molybdenum Blue Na4[Mo2O2(OH)4(C6H4NO2)2]2[Mo120Ce6O366H12(OH)2(H2O)76]∼200H2O. Colour code: Mo black, O red, C grey, N blue and H white.

To understand the fundamental principles of a multicomponent system driving the assembly of these aesthetically pleasing constructions, as well as the prospects for forming novel ones, is a major undertaking. Identifying novel steps in the formation process of mixed-valence polyoxomolybdates, such as an effect of a structure-directing ligand or implementing a unique functionalization of building blocks, will enable the construction of POM clusters with unprecedented sizes and topologies, thereby shedding light upon the mostly elusive self-assembly mechanisms, ultimately perhaps paving the way towards novel POM architectures with nuclearities surpassing the famous Na₄₈[H_xMo₃₆₈O₁₀₃₂(H₂O)₂₄₀(SO₄)₄₈]∼1000H₂O (Mo₃₆₈) `blue lemon' (Müller et al., 2002).

More than two decades separate the discovery of the `Blues' and the `Reds'. Is that the end of the molybdenum classes, or will the synthetic chemists have yet another new colour to enjoy?