Fully Oxidized and Mixed-Valent Polyoxomolybdates Structured by Bisphosphonates with Pendant Pyridine Groups: Synthesis, Structure and Photochromic Properties

Abstract

Hybrid organic-inorganic polyoxometalates (POMs) were synthesized in water by the reaction of a Mo^VI precursor with bisphosphonate ligands functionalized by pyridine groups. The fully oxidized POM [(Mo^VI₃O₈)₂(O)(O₃PC(O)(C₃H₆NH₂CH₂C₅H₄NH)PO₃)₂]⁴⁻ has been isolated as water insoluble pure Na salt (NaMo₆(Ale-4Py)₂) or mixed Na/K salt (NaKMo₆(Ale-4Py)₂) and their structure solved using single-crystal X-ray diffraction. The mixed-valent complex [(Mo^V₂O₄)(Mo^VI₂O₆)₂{O₃PC(O)(C₃H₆N(CH₂C₅H₄N)₂(Mo^VIO₃))PO₃}₂]⁸⁻ was obtained as an ammonium salt (NH₄Mo₆(AlePy₂Mo)₂), in the presence of a reducing agent (hydrazine). ³¹P NMR spectroscopic studies in aqueous media have allowed determining the pH stability domain of NH₄Mo₆(AlePy₂Mo)₂. NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ exhibit remarkable solid-state photochromic properties in ambient conditions. Under UV excitation, they develop a very fast color-change from white to deep purple and proved to be the fastest photochromic organoammonium/POM systems. The coloration kinetics has been fully quantified for both salts and is discussed in light of the hydrogen-bonding networks.

1. Introduction

Polyoxometalates (POMs) are discrete soluble metal oxide fragments of d-block transition metals in high oxidation states (W^V,VI, Mo^V,VI, V^IV,V) with a wide range of properties going from magnetism [1] to biology [2] and catalysis [3]. Among these properties, photochromism attracts increasing interest due to the potential applications of POM-based photoresponsive molecular materials as reversible memory photodevices [4]. Reversible color-change effects under UV irradiation have been first evidenced on alkylammonium polyoxomolybdates [5,6]. The mechanism has been rationalized considering the transfer of an electron from an O atom of the POM unit to a Mo^VI center, coupled with the transfer of a hydrogen atom (see below). These materials are ionic crystals combining anionic POMs and cationic alkylammonium counter-ions. However, an alternative and attractive approach to get functionalized POM-based materials consists in the covalent attachment of organic ligands directly onto the POM core [7]. It has indeed been demonstrated that the presence of covalently bonded organic ligands can bring new functionalities and allow the elaboration of unique materials and devices [8], as demonstrated by the characterization of surfaces patterned with POMs [9,10], the synthesis of fluorescent [11] and catalytic [12] POMs, or the elaboration of extended frameworks based on POM building units [13]. We have developed for several years the functionalization of POMs by bisphosphonates (BPs) with the general formula H₂O₃PC(R₁)(R₂)PO₃H₂ (R₁ = H, OH) [14]. Once deprotonated, BPs act as multidentate ligands and can form stable POM complexes [15]. We initiated a few years ago a study on the synthesis of polyoxomolybdates with grafted BPs, starting with Mo^V/BP complexes. Alendronic acid (Ale, Scheme 1) and its aminophenol derivative were reacted with Mo^V ions, leading to low nuclearity complexes [16]. The reaction of Mo^VI ions with Ale was then investigated and we showed that the synthetic pH governs the formation of one complex over the other. The mononuclear POM [(MoO₂)(Ale)₂]⁶⁻ (Mo(Ale)₂) [17] was isolated at pH 7.5, the hexanuclear complex [(Mo₃O₈)₂O(Ale)₂]⁶⁻ (Mo₆(Ale)₂) [18] at pH = 4.5 and the dodecanuclear complex [(Mo₃O₈)₄(Ale)₄]⁸⁻ (Mo₁₂(Ale)₄) at pH = 3.0 [16]. The hexa and dodecanuclear hybrid POMs possess highly efficient solid-state photochromic properties which are brought by the grafting of the organic ligand [18]. We then decided to post-functionalize the Ale ligand with pyridine groups with the aim to explore its chelating properties towards additional metal ions and study their influence on the structure and properties of the molybdobisphosphonate complexes. We thus report here our results with two BP ligands bearing one or two pyridine groups, abbreviated Ale-4Py and AlePy₂, respectively (Scheme 1). The photochromic properties of the Mo^VI derivatives with Ale-4Py have been studied and are compared with those of related complexes.

Scheme 1. Structure and abbreviations of the ligands used in this work.

Scheme 1. Structure and abbreviations of the ligands used in this work.

2. Results and Discussion

2.1. Synthesis and Characterization

The new BP Ale-4Py ligand has been obtained by coupling Ale and 4-pyridinecarboxaldehyde, followed by the reduction of the resulting imine derivative. We explored the synthesis of hybrid polyoxomolybdates functionalized by BP ligands, namely Ale-4Py and AlePy₂, using two different synthetic protocols (Scheme 2). The first one consists in reacting an aqueous solution of Mo^VI oxoanions with Ale-4Py. The pH is set at 3.1 by addition of 2 M HCl and the solution is heated to 80 °C for 30 min. White crystals of the pure Na (NaMo₆(Ale-4Py)₂) and of the mixed Na/K salt (NaKMo₆(Ale-4Py)₂) of the hybrid POMs were isolated after slow evaporation and characterized by single crystal X-ray diffraction and elemental analysis (see below). Surprisingly, the X-ray study revealed the presence of the hexanuclear anion [(Mo^VI₃O₈)₂(O)(O₃PC(O)(C₃H₆NH₂CH₂C₅H₄NH)PO₃)₂]⁴⁻ (Mo₆(Ale-4Py)₂). Indeed, the crystallization of a dodecanuclear POM of general formula Mo₁₂(BP)₄ was expected as these species were shown to be stable at pH 3 while the formation of the hexanuclear POMs Mo₆(BP)₂ (BP = Ale, O₃PC(C₃H₆NRR’R”)(O)PO₃ with R, R’, R” = H or CH₃) occurs at pH ~ 6 [18].

Scheme 2. Synthetic pathways.

Scheme 2. Synthetic pathways.

The second synthetic pathway consists in using a solution of [Mo^V₂O₄(H₂O)₆]²⁺ ions prepared by reduction of MoO₃ by hydrazine in 4 M HCl. AlePy₂ is added in the solution and the pH is adjusted to 7.5 by addition of aqueous ammonium hydroxide. An abundant precipitate forms and progressively redissolves while stirring for two days at room temperature. Red crystals (Figure 1) are isolated after slow evaporation of the resulting solution. The formula of the hybrid POM, [(Mo^V₂O₄)(Mo^VI₂O₆)₂{O₃PC(O)(C₃H₆N(CH₂C₅H₄N)₂(Mo^VIO₃))PO₃}₂]⁸⁻ (Mo₆(AlePy₂Mo)₂) has been deduced from single crystal X-ray analysis (see below) and confirmed by elemental analysis. The mixed-valent anion contains two Mo^V and six Mo^VI ions, which are formed by slow reoxidation in air of the Mo^V ions of the reacting solution. Such reoxidation has been previously observed [16,19,20]. The red color of the complex is correlated to the presence of the dimeric unit {Mo^V₂O₄}, which can be found in oxomolybdenum(V) clusters isolated in organic solvents [21] as well as in cyclic POMs and ε-Keggin type species synthesized in aqueous solutions [14], and is the indication of electron localization while the blue color of mixed-valent Mo species is the sign of electron delocalization [22].

Figure 1. Picture of the crystals of NH₄Mo₆(AlePy₂Mo)₂ in the synthetic medium.

Figure 1. Picture of the crystals of NH₄Mo₆(AlePy₂Mo)₂ in the synthetic medium.

NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ are insoluble in all common solvents. Therefore, it was not possible to investigate their stability in solution by ³¹P NMR spectroscopy. Nevertheless, it has been possible to record the ³¹P NMR spectra of the synthetic solutions (Figure 2a). Three peaks around 22 ppm are observed which can be tentatively attributed to the presence of conformers in equilibrium in solution [18].

Figure 2. ³¹P NMR spectra of a) the synthetic medium of NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ and b) an aqueous solution of NH₄Mo₆(AlePy₂Mo)₂ at various pH.

Figure 2. ³¹P NMR spectra of a) the synthetic medium of NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ and b) an aqueous solution of NH₄Mo₆(AlePy₂Mo)₂ at various pH.

Crystals of NH₄Mo₆(AlePy₂Mo)₂ have been dissolved in D₂O and the pH adjusted to 7. A single peak at 25.6 ppm is observed by ³¹P{¹H} NMR (Figure 2b). This indicates that the two P atoms in each BP ligand are magnetically equivalent although they appear inequivalent in the crystal structure (Figure S1). This is in contrast also with the observation of doublets at 30.1 and 26.2 ppm on the ³¹P{¹H} NMR spectrum of a POM possessing the {(Mo^V₂O₄)(Mo^VI₂O₆)₂(BP)₂} (BP = O₃PC(O)(CH₂-3-C₅NH₄)PO₃ = Ris) core [20]. The ³¹P NMR spectrum of NH₄Mo₆(AlePy₂Mo)₂ at pH 4.5 is identical, showing the stability of the POM at this pH. In contrast, when the pH decreases to 3, the evolution of the ³¹P NMR spectrum together with the appearance of a blue color clearly indicate the decomposition of the POM.

2.2. Structures

The hexanuclear anion [(Mo^VI₃O₈)₂(O)(O₃PC(O)(C₃H₆NH₂CH₂C₅H₄NH)PO₃)₂]⁴⁻ (Mo₆(Ale-4Py)₂), common in the structures of NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂, contains two trinuclear {Mo₃O₈} fragments connected by a central oxo bridge (Figure 3), encountered also in structures reported with etidronate [23], alendronate [17,24] and its methyl derivatives [18]. Each trinuclear unit is built of two face-sharing octahedra which share also a corner with a third Mo^VI octahedron. The three octahedra are linked to one bisphosphonate ligand via four Mo-O-P bonds with the phosphonate groups and one Mo-O-C bond with the deprotonated hydroxo group. Two conformations have been previously observed for the hexanuclear complexes of general formula [(Mo^VI₃O₈)₂(O)(BP)₂]ⁿ⁻ [14]. In the A conformer (Figure 3a), the six Mo^VI ions are approximately coplanar. This conformer is the most frequently encountered, and is found in particular in Rb_0.25(NH₄)_5.75[(Mo^VI₃O₈)₂(O)(Ale)₂] [18]. The B conformer (Figure 3b), observed for example in Na₆[(Mo^VI₃O₈)₂(O)(Ale)₂] [24], results from a rotation around the central oxygen atom of a trimeric unit, so that the three Mo^VI ions of a trimeric unit are located in a plane perpendicular to the three Mo^VI ions of the other trimeric unit. The conformers are very close in energy, and the stabilization of one conformer or another depends on the inter- and intra-molecular interactions governed by the crystal packing. A comparison of the structures of the anions in NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ with those of the alendronate derivatives shows that the Mo₆(Ale-4Py)₂ entities in NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ adopt the B conformation. The orientation of the organic ligand is slightly different from one compound to the other.

In the unit cell, the anions alternate with alkali counter-ions (4 Na⁺ ion in NaMo₆(Ale-4Py)₂ and 3.5 K⁺ and 0.5 Na⁺ in NaKMo₆(Ale-4Py)₂) and the crystal packing thus appear quite different in the two structures (Figure S2). Despite this, the hydrogen bond networks involving the POM units appear remarkably similar. Both intra and intermolecular hydrogen bonds are observed between the protonated amino and pyridine groups of the Ale-4Py ligands and bridging oxygen atoms of the POM cores or crystallized water molecules (Figure 4 and Table S1). The structure of NaMo₆(Ale-4Py)₂ contains one crystallographically independent Mo₆(Ale-4Py)₂ anion. As shown in Figure 4a, two of them are connected together into a supramolecular dimer {Mo₆(Ale-4Py)₂}₂ via two H-bonds involving two of the four pyridinium groups (the other two being connected to water molecules). Each dimer also develops eight additional N-H∙∙∙O interactions: four of them involve the protonated amino groups of the four Ale-4Py ligands and the oxygen atoms of the two Mo₆(Ale-4Py)₂ units, while the other four connect the protonated amino groups with water molecules.

Figure 3. Mixed polyhedral/ball-and-stick representation of the hexanuclear POM of general formula [(Mo^VI₃O₈)₂(O)(BP)₂]ⁿ⁻ in (a) Rb_0.25(NH₄)_5.75[(Mo^VI₃O₈)₂(O)(Ale)₂]¹⁸ (A conformation), (b) Na₆[(Mo^VI₃O₈)₂(O)(Ale)₂]²⁴ (B conformation), (c) NaMo₆(Ale-4Py)₂ and (d) NaKMo₆(Ale-4Py)₂; blue octahedra: Mo^VIO₆, pink tetrahedra: PO₄, orange spheres: O, black spheres: C, green spheres: N.

Figure 3. Mixed polyhedral/ball-and-stick representation of the hexanuclear POM of general formula [(Mo^VI₃O₈)₂(O)(BP)₂]ⁿ⁻ in (a) Rb_0.25(NH₄)_5.75[(Mo^VI₃O₈)₂(O)(Ale)₂]¹⁸ (A conformation), (b) Na₆[(Mo^VI₃O₈)₂(O)(Ale)₂]²⁴ (B conformation), (c) NaMo₆(Ale-4Py)₂ and (d) NaKMo₆(Ale-4Py)₂; blue octahedra: Mo^VIO₆, pink tetrahedra: PO₄, orange spheres: O, black spheres: C, green spheres: N.

The structure of NaKMo₆(Ale-4Py)₂ is built upon two crystallographically independent Mo₆(Ale-4Py)₂ units which are assembled into two supramolecular dimers (Figure 4b). The relative arrangement of anions within the dimers is as in NaMo₆(Ale-4Py)₂, and therefore, very similar N-H∙∙∙O contacts are developed.

The Mo₆(AlePy₂Mo)₂ POM contains a mixed-valent {(Mo^V₂O₄)(Mo^VI₂O₆)₂(BP)₂} core (Figure 5). Two face-sharing Mo^VI octahedra are connected symmetrically to a {Mo^V₂O₄} dimeric unit via a common oxygen atom and two pentadentate AlePy₂ ligands. We can note that AlePy₂ and Ale-4Py behave very differently. Indeed, while in Ale-4Py the aminopyridine fragments cannot act as chelating groups, the two pyridine and the alkylammino groups of AlePy₂ can strongly bind to an additional metal ion. This is highlighted by the fact that in NaKMo₆(Ale-4Py)₂ and NaMo₆(Ale-4Py)₂ the pyridine and alkylammonium groups do not act as a ligand. In contrast in Mo₆(AlePy₂Mo)_2, the nitrogen atoms of the two pyridine and of the amino groups of the AlePy₂ ligand are bound to an isolated Mo^VI ion in octahedral coordination. The coordination sphere of this ion is completed by three terminal oxo groups. Valence bond calculations confirm the oxidation states of the Mo ions in this octanuclear complex (Figure S1). It can be noticed that the oxygen atoms of the POM develop hydrogen bonding interactions exclusively with water molecules (Figure S3a). In the solid, there is a segregation of the organic and inorganic parts with the formation of double layers of Mo₆ clusters at z = ½ and Mo-organic regions at z = 0 (Figure S3b).

Figure 4. Hydrogen bonding schemes involving the supramolecular dimers {Mo₆(Ale-4Py)₂}₂ in (a) NaMo₆(Ale-4Py)₂ and (b) NaKMo₆(Ale-4Py)₂.

Figure 4. Hydrogen bonding schemes involving the supramolecular dimers {Mo₆(Ale-4Py)₂}₂ in (a) NaMo₆(Ale-4Py)₂ and (b) NaKMo₆(Ale-4Py)₂.

Figure 5. Mixed polyhedral/ball-and-stick representation of the mixed-valent POM [(Mo^V₂O₄)(Mo^VI₂O₆)₂{O₃PC(O)(C₃H₆N(CH₂C₅H₄N)₂(Mo^VIO₃))PO₃}₂]⁸⁻ in NH₄Mo₆(AlePy₂Mo)₂; blue octahedra: Mo^VIO₆, grey octahedra: Mo^VO₆, blue spheres: Mo^VI, pink tetrahedra: P, orange spheres: O, black spheres: C, green spheres: N; hydrogen atoms have been omitted for clarity.

Figure 5. Mixed polyhedral/ball-and-stick representation of the mixed-valent POM [(Mo^V₂O₄)(Mo^VI₂O₆)₂{O₃PC(O)(C₃H₆N(CH₂C₅H₄N)₂(Mo^VIO₃))PO₃}₂]⁸⁻ in NH₄Mo₆(AlePy₂Mo)₂; blue octahedra: Mo^VIO₆, grey octahedra: Mo^VO₆, blue spheres: Mo^VI, pink tetrahedra: P, orange spheres: O, black spheres: C, green spheres: N; hydrogen atoms have been omitted for clarity.

2.3. Solid-State Photochromic Properties

The solid-state photochromic properties of NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ have been thoroughly investigated in ambient conditions by diffuse reflectance spectroscopy. Under low-power UV excitation at λ_ex = 365 nm (3.34 eV), the two compounds exhibit strong photochromic responses. The color of the white microcrystalline powders gradually shifts to deep purple with a remarkable coloration contrast, and finally reaches an eye-detected saturation level after only 20 min (Figure 6a and Figure S4a for NaKMo₆(Ale-4Py)₂ and NaMo₆(Ale-4Py)₂, respectively). As displayed in Figure 6b, the color change of NaKMo₆(Ale-4Py)₂ deals with the growth of a broad absorption band in the visible range at λ_max = 508 nm (2.44 eV) that mainly dictates the photogenerated hue, and a second very less-intense absorption band rising up at ~750 nm (1.65 eV). Similar absorption bands are also observed for NaMo₆(Ale-4Py)₂ (Figure S4b). It is worth noting that these bands are quite comparable with those of other photochromic Mo₆(BP)₂ compounds [18], and then, they well characterize the photoreduced Mo₆ core. In such photochromic organoammonium/POM systems, the UV excitation transfers an electron from an O atom of the POM unit to the adjacent Mo⁶⁺ site [5,25]. This electron/hole pair segregation is coupled with the transfer of a hydrogen atom from the ammonium group to an adjacent {MoO₆} octahedron. The H atom moves along the hydrogen bond creating a {Mo⁵⁺(OH)O₅} site. The coloration is then due to the photoreduction of Mo⁶⁺ (4d⁰) to Mo⁵⁺ (4d¹) cations and occurs via d−d transitions and/or Mo⁶⁺/Mo⁵⁺ intervalence transfers. The photocoloration rate is strongly correlated to the strength of the N⁺-H bonds considering that, the lower the dissociation energy of the N⁺-H bond, the faster the coloration speed [6].

The coloration kinetics of NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ has been quantified by monitoring the evolution of their reflectivity values versus the UV irradiation time (R(t)). According to the photocoloration kinetics model of organoammonium/POM systems, the decrease of R^λmax(t) (i.e., the reflectivity at the wavelength of the maximum photogenerated absorption in the visible) with the UV irradiation time is correlated to the decrease of the concentration of reducible Mo⁶⁺ cations, according to a pseudo second-order kinetic law [6]. Herein, the R⁵⁰⁸(t) vs. t curves for NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ are perfectly fitted as R⁵⁰⁸(t) = a/(bt+1) + R⁵⁰⁸(∞) (Figure 6c). R⁵⁰⁸(∞) is the reflectivity value at the end of the photochromic process, that is at t = ∞. The a parameter is defined as a = R⁵⁰⁸(0)-R⁵⁰⁸(∞), i.e. the difference between the reflectivity values just before UV illumination (t = 0) and at t = ∞. The b parameter is defined as b = k^c × C_6+,r(0), where k^c is the coloration rate constant, and C_6+,r(0) is the initial concentration of photoreducible Mo⁶⁺ centers per unit volume. The details of the coloration kinetic parameters are given in Table S2. NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ exhibit a remarkably fast photocoloration rates well characterized by a very short coloration half-time (t_1/2 = 0.37 min for both compounds). The very fast photoreduction rate of the Mo⁶⁺ ions is also well assessed by monitoring the evolution of the photoreduction degree Y(t) which reaches 98% for NaMo₆(Ale-4Py)₂ and 97% for NaKMo₆(Ale-4Py)₂ after only 20 min of UV irradiation (Figure S5).

In addition, for two hybrid materials, i and j built upon the same POM unit (then which develop the same photogenerated absorption bands), the relative coloration rate constants k^c_i/k^c_j can be extracted from the ratio b_ia_j/b_ja_i, to compare their coloration rates [6]. Here, k^c_{NaMo6(Ale-4Py)2}/ k^c_{NaKMo6(Ale-4Py)2} = 1.1, and both compounds exhibit the same photocoloration rates. This quite evidences that in these two hybrid systems that contain the same Mo₆(Ale-4Py)₂ anion and very similar H-bonding networks, the intrinsic photochromic process is not influenced by the packing with the other alkali countercations. Noticeably, NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ exhibit remarkably improved solid-state photochromic performances compared to those of Mo₆-Ale that was, to date, the fastest photochromic members of the Mo₆(BP)₂ series [18,26] (Table S2) (for example, the coloration rate constant ratio k^c_{NaKMo6(Ale-4Py)4}/k^c_Mo6-Ale reaches 10.6). Consequently, these two new compounds are the most efficient known photochromic organoammonium/POM systems (Table 1). It should be reasonably assumed that the very high photochromic performances of NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ should originate from a beneficial combination of three main factors that are: (i) the presence of the easily photoreducible Mo₆ core [18], (ii) a great number of N-H∙∙∙O contacts between the Mo₆(Ale-4Py)₂ units and the organoammonium groups of the Ale-4Py ligands, and (iii) the implication in the H-bonding interactions of the diprotonated amino group which possesses a low dissociation energy of the N⁺-H bond [6].

Table 1. Comparison of the t_1/2 values for various photochromic organoammonium/POM systems.

Compound	λmax (nm) a	t1/2 (min) b	Ref.
NaMo6(Ale-4Py)2	508	0.37	this work
NaKMo6(Ale-4Py)2	508	0.37	this work
Mo6(Ale)2	508	2.87	[18]
Mo6(Ale-1Ca)2	508	31.25	[18]
Mo6(Ale-1Cb)2	508	4.78	[18]
Mo6(Ale-2C)2	508	12.82	[18]
Mo6(1C-Ale)2 Mo6(Ris)2	508	5.71	[18]
Mo6(Ris)2	508	14.89	[26]
Mo12(Ale)4	464	8.20	[18]
Mo12(Ale-1Ca)4	464	5.44	[18]
Mo12(Ale-2C)4	464	51.81	[18]
(H2DABCO)2(NH4)2[Mo8O27]	525	37.0	[6]
(H2DABCO)2(H2pipz)[Mo8O27]	525	5.6	[6]
(H2pipz)3[Mo8O27]	525	7.8	[6]
(H2DABCO)2(HDMA)0.5Na0.75[Mo8O27]	525	0.8	[6]

^a Photoinduced absorption band wavelength. ^b Coloration kinetic half-life time (min).

Table 1. Comparison of the t_1/2 values for various photochromic organoammonium/POM systems.

Compound	λmax (nm) a	t1/2 (min) b	Ref.
NaMo6(Ale-4Py)2	508	0.37	this work
NaKMo6(Ale-4Py)2	508	0.37	this work
Mo6(Ale)2	508	2.87	[18]
Mo6(Ale-1Ca)2	508	31.25	[18]
Mo6(Ale-1Cb)2	508	4.78	[18]
Mo6(Ale-2C)2	508	12.82	[18]
Mo6(1C-Ale)2 Mo6(Ris)2	508	5.71	[18]
Mo6(Ris)2	508	14.89	[26]
Mo12(Ale)4	464	8.20	[18]
Mo12(Ale-1Ca)4	464	5.44	[18]
Mo12(Ale-2C)4	464	51.81	[18]
(H2DABCO)2(NH4)2[Mo8O27]	525	37.0	[6]
(H2DABCO)2(H2pipz)[Mo8O27]	525	5.6	[6]
(H2pipz)3[Mo8O27]	525	7.8	[6]
(H2DABCO)2(HDMA)0.5Na0.75[Mo8O27]	525	0.8	[6]

^a Photoinduced absorption band wavelength. ^b Coloration kinetic half-life time (min).

NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ show reversible color-change effects. The bleaching is correlated to the back oxidation of the Mo⁵⁺ cations by O₂ in ambient conditions [27]. After switching off the UV irradiation, the bleaching occurs slowly in air and at room temperature. No color change occurs when the colored samples are kept in O₂ free atmosphere, and at the opposite the bleaching is much faster when samples are exposed to O₂ flux. The fading process is also strongly accelerated by keeping the samples in air under moderate heating at 40 °C (the deep purple color disappears after a few minutes). To date, about 15 coloration/fading cycles at room temperature as well as at 40 °C can be performed without detecting any fatigue resistance with naked eyes.

Figure 6. (a) Photographs of the powder of NaKMo₆(Ale-4Py)₂ at different UV irradiation time (in min). (b) Evolution of the photo-generated absorption in NaKMo₆(Ale-4Py)₂ after 0, 0.5, 1, 2, 3, 4, 5, 7, 10, 15, 20, 30, 40, 60, 80, 100 and 130 min of UV irradiation (λ_ex = 365 nm). (c) Comparison of the R⁵⁰⁸(t) vs. t plots for NaMo₆(Ale-4Py)₂ (■), and NaKMo₆(Ale-4Py)₂ (○). The lines show the fits of the plots according to rate law R⁵⁰⁸(t) = a/(bt + 1) + (R⁵⁰⁸(0) − a).

Figure 6. (a) Photographs of the powder of NaKMo₆(Ale-4Py)₂ at different UV irradiation time (in min). (b) Evolution of the photo-generated absorption in NaKMo₆(Ale-4Py)₂ after 0, 0.5, 1, 2, 3, 4, 5, 7, 10, 15, 20, 30, 40, 60, 80, 100 and 130 min of UV irradiation (λ_ex = 365 nm). (c) Comparison of the R⁵⁰⁸(t) vs. t plots for NaMo₆(Ale-4Py)₂ (■), and NaKMo₆(Ale-4Py)₂ (○). The lines show the fits of the plots according to rate law R⁵⁰⁸(t) = a/(bt + 1) + (R⁵⁰⁸(0) − a).

3. Experimental Section

3.1. General

The alendronic acid H₂O₃PC(OH)(C₃H₆NH₂)PO₃H₂ (Ale) [27] and its derivative Na₄[O₃PC(OH)(C₃H₆N(CH₂C₅H₄N)₂)PO₃] (Na₄HAlePy₂) [28] were synthesized according to reported procedures. All other chemicals were used as purchased without purification. Ale-4Py and AlePy₂ were reacted with Mo^VI and Mo^V precursors. However, only the reactions of Ale-4Py with Mo^VI and AlePy₂ with Mo^V led to crystalline compounds which could be characterized by single-crystal X-ray diffraction analysis.

3.2. Synthesis of Na₂[(HO₃P)₂(OH)C(C₃H₆NHCH₂(C₅H₄N)] (Na₂H₃Ale-4Py)

Alendronic acid (1.5 g, 6 mmol) and triethylamine (1.6 mL, 12 mmol) were stirred at room temperature in 36 mL of MeOH until complete dissolution. Then, 4-pyridinecarboxaldehyde (0.62 mL, 6.6 mmol) was added to the mixture. The solution was stirred at reflux for 2 h. and then allowed to cool down to room temperature. After slow addition of (TBA)BH₄ (1.549 g, 6 mmol), the resulting mixture was refluxed overnight. The solution was then concentrated to about 10 mL and NaPF₆ (2.022 g, 12 mmol) was added. A white precipitate appeared instantly. The solid was filtered under vacuum and washed with MeOH and Et₂O. The ligand (1.612 g, yield 70%) was used without further purification. ³¹P NMR (200 MHz, D₂O): δ 17.7. ¹H NMR (200 MHz, D₂O): δ 8.47 (d, 2H, ³J = 5.41 Hz), 7.40 (d, 2H, ³J = 5.41 Hz), 4.18 (s, 2H), 3.05 (m, 2H, N-CH₂-CH₂), 1.91 (m, 4H, N-CH₂-CH₂-CH₂). IR (KBr pellets): ν(cm⁻¹) = 3192 (w), 2968 (w), 2950 (w), 1610 (m), 1501 (m), 1424 (m), 1381 (w), 1224 (m), 1191 (m), 1141 (s), 1122 (s), 1071 (vs), 1036 (vs), 959 (s), 930 (s), 882 (s), 844 (s), 810 (m), 787 (m), 673 (s), 605 (m), 589 (m), 556 (m), 541 (m).

3.3. Synthesis of Na₄[(Mo^VI₃O₈)₂(O)(O₃PC(O)(C₃H₆NH₂CH₂C₅H₄NH)PO₃)₂].14H₂O (NaMo₆(Ale-4Py))

To a solution of Na₂MoO₄ (0.291 g, 1.2 mmol) in 10 mL of water was added Na₂H₃(Ale-4Py) (0.154 g, 0.4 mmol). The pH was adjusted to 3.1 with 2 M HCl and the mixture was stirred at 80 °C for 30 min. A fine powder was then eliminated by centrifugation (0.134 g) and the filtrate was left to evaporate at room temperature. The IR spectrum of the powder shows the presence of Mo-O and P-O vibrations close to the vibrations found in Mo₁₂(BP)₄ species. After one month, white crystals (yield 0.037 g; 10% based on Mo) suitable for X-ray diffraction studies were collected by filtration. The formation of the white insoluble powder explains the low yield of the synthesis.

IR (KBr pellets): ν(cm⁻¹) = 3361 (br), 3082 (s), 2832 (m), 2788 (m), 1644 (s), 1624 (s), 1508 (m), 1467 (m), 1252 (w), 1137 (s), 1067 (s), 1015 (s), 907 (vs), 872 (vs), 815 (s), 675 (s), 548 (s). Anal. calcd. for C₂₀H₅₈N₄Mo₆Na₄O₄₅P₄ (1866.16 g.mol⁻¹) (found): C 12.87 (12.60), H 3.13 (2.95), N 3.00 (2.94). EDX analyses confirm the values of the Mo/P and Mo/Na ratios.

3.4. Synthesis of Na_0.5K_3.5[(Mo^VI₃O₈)₂(O)(O₃PC(O)(C₃H₆NH₂CH₂C₅H₄NH)PO₃)₂].13H₂O (NaKMo₆(Ale-4Py)₂)

To a solution of Na₂MoO₄ (0.291 g, 1.2 mmol) in 10 mL of water was added Na₂H₃(Ale-4Py) (0.154 g, 0.4 mmol). The pH was adjusted to 3.1 with 2 M HCl and the mixture was stirred at 80 °C for 30 minutes. A fine powder was then eliminated by centrifugation. KCl (0.100 g) was added to the filtrate and the solution was left to evaporate at room temperature. After one month, white crystals (yield 0.056 g; 15% based on Mo) suitable for X-ray diffraction studies were collected by filtration.

IR (KBr pellets): ν(cm⁻¹) = 3365 (br), 3082 (s), 2832 (m), 2789 (m), 1644 (s), 1626 (s), 1509 (m), 1468 (m), 1256 (w), 1137 (s), 1065 (s), 1016 (s), 907 (vs), 871 (vs), 811 (s), 678 (s), 551 (s). Anal. calcd. for C₂₀H₅₆N₄K_3.5Mo₆Na_0.5O₄₄P₄ (1904.53 g.mol⁻¹) (found): C 12.61 (12.50), H 2.96 (2.82), N 2.94 (2.85). EDX analyses confirm the values of the Mo/P, Mo/K and Mo/Na ratios.

3.5. Synthesis of (NH₄)₈[(Mo^V₂O₄)(Mo^VI₂O₆)₂{O₃PC(O)(C₃H₆N(CH₂C₅H₄N)₂(Mo^VIO₃))PO₃}₂]·20H₂O (NH₄Mo₆(AlePy₂Mo)₂)

A 0.1 M solution of [Mo^V₂O₄(H₂O)₆]²⁺ was prepared as previously reported [19] by reduction of MoO₃ by N₂H₄ in 4M HCl. Na₄HAlePy₂ (0.325 g, 0.21 mmol) was added in aqueous [Mo^V₂O₄(H₂O)₆]²⁺ (0.1 M, 6.25 mL, 0.625 mmol). A green precipitate appeared. Aqueous ammonium hydroxide (33%) was added dropwise to pH 7.5. An orange precipitate was formed. The beaker was covered with a watch glass and the mixture was stirred for 2 days until the solution progressively turned limpid. The deep red solution was filtered, and left to evaporate at room temperature after addition of NH₄Br (1.2 g, 12.24 mmol). Red crystals were collected by filtration two days later (0.095 g, yield 24% based on Mo). Elemental analysis calcd. (found) for C₃₂H₁₀₈N₁₄Mo₈O₅₆P₄ (2477 g mol⁻¹): C 15.52 (15.20), H 4.39 (4.04), N 7.92 (8.42), Mo 30.98 (30.01), P 5.00 (4.91). IR (ν/cm⁻¹): 1638 (m), 1606 (m), 1419 (s), 1314 (w), 1283 (w), 1142 (sh), 1123 (s), 1075 (sh), 1052 (s), 1013 (s), 913 (m), 896 (sh), 856 (s), 760 (w), 702 (m), 682 (w), 645 (m), 479 (m).

3.6. X-ray Crystallography

Data collection was carried out by using a Bruker Nonius X8 APEX 2 diffractometer equipped with a CCD bi-dimensional detector using the monochromatized wavelength λ(Mo Kα) = 0.71073 Å. Absorption correction was based on multiple and symmetry-equivalent reflections in the data set using the SADABS program [29] based on the method of Blessing [30].The structures were solved by direct methods and refined by full-matrix least-squares using the SHELX-TL package [31]. In all structures, there are small discrepancies between the formulae determined by elemental analysis and those deduced from the crystallographic atom list because of the difficulty in locating all disordered water molecules (and also the counter-cations in some cases). In the structures of NH₄Mo₆(AlePy₂Mo)₂, NH₄⁺ and H₂O could not be distinguished based on the observed electron densities; therefore, all the positions were labeled O and assigned the oxygen atomic scattering factor. Crystallographic data are given in Table 2. Partial atomic labeling schemes, selected bond distances and bond valence sum calculations [32] are reported in Figure S1.

Table 2. Crystallographic data.

Parameters	NaMo6(Ale-4Py)2	NaKMo6(Ale-4Py)2	NH4Mo6(AlePy2Mo)2
Formula	C20H58N4Mo6Na4O45P4	C20H56N4K3.5Mo6Na0.5O44P4	C32H108N14Mo8O56P4
Formula weight/g mol−1	1866.16	1904.53	2476.67
Crystal system	triclinic	triclinic	triclinic
Space group	P-1	P-1	P-1
a/Å	9.0240(3)	17.9501(5)	17.602(2)
b/Å	19.4282(6)	19.4745(4)	22.134(2)
c/Å	21.1568(7)	19.8487(5)	28.323(3)
α/°	103.992(2)	76.188(1)	97.443(5)
β/°	95.5612(2)	69.590(1)	95.464(5)
γ/°	103.407(1)	76.669(1)	107.430(5)
V/Å3	3454.8(2)	6231.6(3)	10334(2)
Z	2	4	4
Dcalc/g cm−3	1.813	2.028	1.560
μ/mm−1	1.273	1.616	1.087
Data/parameters	12208/865	36431/1558	36283 / 2119
Rint	0.0301	0.0429	0.0467
GOF	1.023	1.070	1.035
R1 (I > 2σ (I))	0.0710	0.0568	0.1051
wR2	0.1960	0.1649	0.2719

Table 2. Crystallographic data.

Parameters	NaMo6(Ale-4Py)2	NaKMo6(Ale-4Py)2	NH4Mo6(AlePy2Mo)2
Formula	C20H58N4Mo6Na4O45P4	C20H56N4K3.5Mo6Na0.5O44P4	C32H108N14Mo8O56P4
Formula weight/g mol−1	1866.16	1904.53	2476.67
Crystal system	triclinic	triclinic	triclinic
Space group	P-1	P-1	P-1
a/Å	9.0240(3)	17.9501(5)	17.602(2)
b/Å	19.4282(6)	19.4745(4)	22.134(2)
c/Å	21.1568(7)	19.8487(5)	28.323(3)
α/°	103.992(2)	76.188(1)	97.443(5)
β/°	95.5612(2)	69.590(1)	95.464(5)
γ/°	103.407(1)	76.669(1)	107.430(5)
V/Å3	3454.8(2)	6231.6(3)	10334(2)
Z	2	4	4
Dcalc/g cm−3	1.813	2.028	1.560
μ/mm−1	1.273	1.616	1.087
Data/parameters	12208/865	36431/1558	36283 / 2119
Rint	0.0301	0.0429	0.0467
GOF	1.023	1.070	1.035
R1 (I > 2σ (I))	0.0710	0.0568	0.1051
wR2	0.1960	0.1649	0.2719

3.7. Physical Methods

Infrared (IR) spectra were recorded on a Nicolet 30 ATR 6700 FT spectrometer. EDX measurements were performed on a JEOL JSM 5800LV apparatus. The ³¹P NMR spectra were recorded on a Brüker AC-300 spectrometer operating at 121.5 MHz in 5-mm tubes with ¹H decoupling. ³¹P NMR chemical shifts were referenced to the external usual standard 85% H₃PO₄. Diffuse reflectance spectra were collected at room temperature on a finely ground sample with a Cary 5G spectrometer (Varian) equipped with a 60 mm diameter integrating sphere and computer control using the “Scan” software. Diffuse reflectance was measured from 250–1000 nm with a 2 nm step using Halon powder (from Varian) as reference (100% reflectance). The reflectance data were treated by a Kubelka-Munk transformation [33] to better locate the absorption thresholds. The samples were irradiated with a Fisher Bioblock labosi UV lamp (λ_exc = 365 nm, 6W) at a distance of 50 mm.

4. Conclusions

In summary, the synthesis of two novel molybdobisphosphonate complexes with BPs functionalized by pyridine groups has been performed by a one step or two step procedure in water. These POMs have been characterized in the solid state by single crystal X-ray diffraction and in solution by ³¹P NMR spectroscopy. NH₄Mo₆(AlePy₂Mo)₂ is the ammonium salt of the mixed-valent anion [(Mo^V₂O₄)(Mo^VI₂O₆)₂(AlePy₂)₂(Mo^VIO₃)₂]⁸⁻ in which the two pyridine arms of each BP ligand chelate an additional Mo^VI ion. [(Mo^VI₃O₈)₂(O)(Ale-4Py)₂]⁴⁻ (Mo₆(Ale-4Py)₂) crystallizes as a pure Na salt and as a mixed Na/K salt. Although the nature of the alkali counter-ions is different in the two salts and thus the 3D structure, the hydrogen bonding networks involving the Mo₆(Ale-4Py)₂ units are quite similar. This strongly impacts the photochromic properties of both compounds. Noticeably, NaMo₆(Ale-4Py)₂ and NaKMo₆(Ale-4Py)₂ exhibit remarkably fast and quite comparable color-change effects from white to deep purple under UV excitation, and to date they are the most efficient known photochromic organoammonium/POM systems. Their highly solid-state photochromic performances in ambient conditions can be correlated to a great number of N-H∙∙∙O contacts between the oxygen atoms of the hexanuclear units and the organoammonium groups of the Ale-4Py ligands as well as the presence of the diprotonated amino groups.