2.1. General

All solvents and reagents including meso-tetra­phenyl­porphine-4,4′,4′′,4′′′-tetra­sulfonic acid tetrasodium salt (TPPS), 4,4′-bi­pyridine (bipy) and Mn(NO₃)₂·xH₂O were purchased from Sigma–Aldrich.

2.2. Synthesis of [H(bipy)]₂[(MnTPPS)(H₂O)₂]·2bipy·14H₂O

TPPS (10.2 mg, 0.01 mmol) and Mn(NO₃)₂·xH₂O (1.0 mg, 0.006 mmol) were dissolved in distilled water (10 ml) and the solution was stirred for 30 min. Then, 4,4′-bi­pyridine (9.4 mg, 0.06 mmol) was dissolved in hot (343 K) distilled water (5 ml) and added to the mixture in a 100 ml CEM EasyPrep microwave vessel. The mixture was heated by microwaves under autogenous pressure at 433 K for 2 h, and then cooled naturally to room temperature, yielding diffraction-quality prismatic dark-red crystals. [For C₄₂H₄₆Mn_0.5N₆O₁₄S₂. Found: C, 53.55 (4); H, 4.85 (2); N, 8.84 (6); O, 22.95 (6); S, 6.89 (4). Calculated: C, 53.08; H, 4.88; N, 8.84; O, 23.57; S, 6.75]. ν_max/cm⁻¹ 3397 (OH), 1636–1413 (CC), 1393 and 1180 (SO), 1340 (CN), 1204 and 1070 (bipy), 1003 (MnTPPS) and 857–634 (CH) (see Fig. S1 in the supporting information).

2.3. Single-crystal X-ray diffraction

Prismatic dark-red single-crystals of compound 1 (dimensions given in Table 4) were selected under a polarizing microscope and mounted on MicroMounts. Single-crystal X-ray diffraction data were collected at 100 K on a SuperNova single source diffractometer with Cu Kα radiation (λ = 1.54184 Å). Data frames were processed [unit-cell determination, intensity-data integration, correction for Lorentz and polarization effects (Yinghua, 1987) and analytical absorption correction] using the CrysAlisPro software package (Agilent Technologies UK Ltd, 2012).

The structure of 1 was solved in the triclinic space group using the SIR92 program (Altomare et al., 1993) which allowed us to determine the position of the Mn atom, as well as some of the O, N, S and C atoms of the porphyrin and bi­pyridine molecules. The refinement of the crystal structure was performed by full matrix least-squares based on F², using the SHELXL97 program (Sheldrick, 2008), obtaining the remaining C, N, O and S atoms of the porphyrin and O atoms of water molecules. Anisotropic displacement parameters (Farrugia, 1997) were used for all non-hydrogen atoms, except for the disordered crystallized water molecules (Fig. S2). All H atoms connected to aromatic rings (C—H = 0.95 Å) were fixed geometrically and refined using a riding model with common isotropic displacements. Four of the crystallized water mol­ecules of compound 1 were disordered over two groups, with half occupancy each, as well as for one of the porphyrin sulfite groups. Crystal data for compound 1 are listed in Table 1. Geometric parameters, atomic coordinates and anisotropic displacement parameters are given in the supporting information, Tables S1, S2 and S3.

Table 1 Crystallographic data for 1 Compound [H(bipy)]2[(MnTPPS)(H2O)2]·2bipy·14H2O   Formula C42H46Mn0.5N6O14S2   FW (g mol−1) 950.44   Crystal system Triclinic   Space group (No. 2)   a (Å) 9.7187 (4)   b (Å) 11.2496 (5)   c (Å) 21.8708 (7)   α (°) 88.401 (3)   β (°) 83.848 (3)   γ (°) 64.446 (4)   V (Å3) 2144.4 (2)   Z 2   ρobs, ρcal (g cm−3) 1.44 (5), 1.472   F(000) 993   μ (mm−1) 2.923   Crystal size (mm) 0.14 × 0.05 × 0.01   Absorption correction Analytical   Radiation, λ (Å) 1.54184   Temperature (K) 100.0 (2)   Reflections collected, unique 17468, 8113 (Rint = 0.051)   Limiting indices −9 ≤h ≤ 11, −13 ≤ k ≤ 13, −26 ≤ l ≤ 26   Refinement method Full-matrix least-squares on F2   Final R indices [I > 2σ(I)]† R1 = 0.0609, wR2 = 0.1516   R indices (all data)† R1 = 0.0984, wR2 = 0.1742   Goodness of fit on F2 1.012   Parameters, restraints 599, 4   †R1 = [(|Fo|−|Fc|)]/|Fo|. wR2 = [[w|Fo|2−|Fc|2)2]/[w(|Fo|2)2]1/2.

Diameter values of the channels for compounds 1, 2 and 3 were calculated using the program TOPOS (available at https://www.topos.ssu.samara.ru).

2.4. Physicochemical characterization techniques

The IR spectra were collected on a JASCO FT/IR-6100 spectrometer at room temperature in the range 4000–400 cm⁻¹, in KBr pellets (1% sample). C, H, N, S and O elemental analyses were measured using a Euro EA 3000 elemental analyser. Thermogravimetric analyses were carried out using a NETZSCH STA 449 F3 thermobalance. A crucible containing approximately 10 mg of sample was heated at 5 K min⁻¹ in the temperature range 303–873 K.

TEM work was done on a Philips SuperTwin CM200 operated at 200 kV and equipped with an LaB₆ filament and EDAX EDS microanalysis system. The samples for TEM analysis were prepared by dispersion into ethanol and keeping the suspension in an ultrasonic bath for 15 min. After that, a drop of the suspension was spread onto a TEM copper grid (300 mesh) covered by a holey carbon film, followed by drying under vacuum.

2.5. Catalytic activity

The oxidation reactions of benzyl alcohol, 1-phenyl­ethanol, 1-hexanol and 1-octanol were carried out at 343 K using aceto­nitrile as the solvent. The catalyst/substrate molar ratio (based on the metal) used for all the reactions was 5:100. Powdered crystals of the catalysts were initially dried at 373 K under vacuum to remove solvent and water adsorbed on the surface.

Before the reactions, approximately 5 mg of dried catalyst was activated by stirring with the oxidizing agent tert-butyl hydro­peroxide (TBHP) in 2 ml of aceto­nitrile for 30 min at 343 K. After this activation stage, the catalyst was separated from the liquid medium by centrifugation. The reactor was then charged with the activated catalyst and the corresponding alcohol in 2 ml of solvent. The mixture was heated to 343 K and then the oxidizing agent was added dropwise (1.5 equivalents of TBHP).

Aldol condensation reactions of benzaldehyde, p-tolu­aldehyde, p-methoxybenzaldehyde and heptanal were carried out at 373 K without solvent. The catalyst/substrate molar ratio (based on the metal) used for all the reactions was 10:100. Powdered crystals of the catalysts were first dried at 373 K under vacuum to remove solvent and water adsorbed on the surface. The reactor was charged with the catalyst (10 mg), acetone (1 ml) and the corresponding substrate, and the mixture was then heated to 373 K.

Knoevenagel condensation reactions of benzaldehyde, p-tolu­aldehyde, p-fluoro­benzaldehyde, 4-chloro­benzaldehyde and 3-nitro­benzaldehyde were carried out at 343 K using toluene as the solvent. The catalyst/substrate molar ratio (based on the metal) used for all the reactions was 5:100. Powdered crystals of the catalysts were first dried at 373 K under vacuum to remove solvent and water adsorbed on the surface. The reactor was charged with the catalyst (5 mg), malono­nitrile (4.6 mg), do­decane as internal standard (2.0 µl) and the corresponding substrate in 2 ml of solvent, and then the mixture was heated to 343 K.

The one-pot cascade reaction was tested for acetal hydrolysis followed by Knoevenagel condensation at 343 K in toluene. The catalyst/substrate molar ratio (based on the metal) used for the reaction was 10:100. Powdered crystals of the catalysts were first dried at 373 K under vacuum to remove solvent and water adsorbed on the surface. The reactor was charged with the catalyst (5.2 mg), toluene (2 ml), benz­aldehyde di­methyl acetal (5.3 µl), malono­nitrile (2.3 mg) and do­decane (2 µl) as internal standard, and then the mixture was heated to 343 K.

Detailed results for the catalytic activity exhibited by compounds 1, 2 and 3 will be described in Sections 3.3 and 3.4.

Reaction samples were taken at regular times and analysed on a Hewlett–Packard 5890 II GC–MS or on a Konik HCGC 5000B gas chromatograph–mass spectrometer. Blank experiments were carried out under the reaction conditions in order to determine the extent of the uncatalysed reaction; for all the blank reactions only traces of the product were found. After the reaction, the catalysts were filtered, dried and characterized by IR spectroscopy, and by TEM microscopy in some cases. The calculations of turnover frequencies (TOF; turnover frequency is mol substrate converted/mol catalyst per hour) were performed in the initial stages of the reaction, when the reaction rates are higher, as usual.

3.1. Crystal structures

The structural features of these materials are of great importance in order to achieve satisfactory conversion rates for catalytic reactions. In this sense, the metalloporphyrinic synthons are intended to act as heterogeneous catalysts and structural building units at the same time. In relation to the latter, accessibility of the guest molecules to catalytic metal centres on the surface of the crystal-network cavities is one of the most important features necessary to consider the compounds as potential catalysts, and was taken into account for compounds 1, 2 and 3.

Compound 1 with the formula [H(bipy)]₂[(MnTPPS)(H₂O)₂]·2bipy·14H₂O is a coordination compound consisting of complex ions. The crystal structure, determined by single-crystal X-ray diffraction, shows [(MnTPPS)(H₂O)₂]²⁻ anionic monomers where TPPS⁴⁻ ligands are present. The Mn^II ion is in an octahedral coordination environment, bonded to the four porphyrin N atoms and with two water molecules in the axial positions.

The [(MnTPPS)(H₂O)₂]²⁻ anions crystallize as shown in Fig. 1. The voids generated between metalloporphyrinic monomers are occupied by [H(bipy)]⁺ cations and crystallized bi­pyridine molecules and, as shown in Fig. S3, those bi­pyridine molecules were pairwise hydrogen-bonded [N5—H1N⋯N4; 2.741 7 Å and 171 9°] and parallel-stacked, giving rise to robust π–π interactions (centroid-to-centroid distances are 3.468 and 3.746 Å) (Soltanzadeh & Morsali, 2009). Additionally, the interstitial voids are occupied by 14 crystallized water molecules per monomer.

Figure 1 Crystal-structure packing for compound 1. Colour code: Mn pink, C grey, N blue, O red and S yellow. H atoms have been omitted for clarity.

The crystal structure is stabilized by an intricate hydrogen-bonded system (Table S4), connecting the [(MnTPPS)(H₂O)₂]²⁻ units along the direction between the axial water molecule (O7) and the sulfonate groups (O3) (Fig. S4). Additionally, the metalloporphyrinic monomers are linked by a hydrogen-bonded chain along the [100] direction. This connection involves the coordinated water molecules (O7) and two crystallized water molecules (O8 and O11). It is worth noting that there is a zigzag chain of water molecules along the [100] direction which stabilizes the structure. This chain is located between the sulfonate groups involving the O12 to O16 crystallized water molecules (Fig. 2).

Figure 2 Representation of the accessibility of guest molecules to the active metal centres for compound 1. Colour code: Mn pink, C grey, N blue, O red and S yellow. The accessible pathway is represented by the green cylinder.

As shown in Fig. 1 and Fig. S5, the [H(bipy)₂]⁺ cations are located on the interporphyrinic voids and linked through O9, O10 and O12 water molecules to the sulfonate groups (O2) and through O8 to the axial water molecules (O7).

Fig. 2 shows the accessibility of the crystal structure to external guest molecules in order to access channels along the x axis. The calculated value of the diameter, obtained using TOPOS (Section 2.3), is 4.3 Å. As shown, the porphyrin units are separated by 9.7187 (4) Å (the a cell parameter), allowing the interaction of potential guest molecules with the active metal centres.

The crystal structure and thermal analysis of compound 2 (μ-O-[FeTCPP]₂·16DMF) have been reported previously by us (Fidalgo-Marijuan et al., 2015). This compound consists of FeTCPP dimers, where monomers are connected by an O-bridge. In this way, the active catalytic centres are exposed to the channels of the framework. The calculated value of the diameter, obtained using TOPOS, is 5.2 Å. As shown in Fig. S6, the dimers are packed forming hydrogen-bonded layers in the xy plane, generating the aforementioned channels along the [001] direction, where potential guest molecules are then distributed to the active centres (Fig. 3).

Figure 3 Representation of the accessibility of guest molecules to the active metal centres for compound 2. Colour code: Fe purple, C grey, N blue and O red. Accessible pathways are represented by the green cylinders.

The crystal structure and thermal analysis for compound 3, with the formula [CoTPPS_0.5(bipy)(H₂O)₂]·6H₂O, have also been reported by us in previous work (Fidalgo-Marijuan et al., 2013). The crystal structure is formed by one-dimensional polymers, where octahedral Co^II ions of CoTPPS units are axially bonded to bipy ligands (Fig. S7). The extension of the one-dimensional polymers consists of a link between alternating Co^II centres along the [001] direction through the bipy ligands in a bipy–CoTPPS–bipy–Co(H₂O)₄ fashion. In this case, the accessibility to active metal centres takes place along the direction where the active metal centres are exposed to the channels of the framework (Fig. 4). The calculated value for the diameter obtained using TOPOS is 6.1 Å.

Figure 4 Representation of the accessibility of guest molecules to the active metal centres for compound 3. Colour code: Co orange, C grey, N blue, O red and S yellow. Accessible pathways are represented by the green cylinders.

3.2. Thermal analysis

Thermal behaviour is crucial in determining the stability and correct catalytic activation of these materials. As observed in Fig. 5, the thermogravimetric decomposition curve of compound 1 shows a continuous mass loss from room temperature to 813 K, where three steps can be distinguished. The first is assigned to an overlapped two-stage step between room temperature and 673 K. The first stage occurs up to 468 K, with a 12.1% weight loss attributed to the coordinated and crystallized water molecules. The second stage, up to 673 K (19.7% weight loss), corresponds to the crystallized bi­pyridine molecules. The second step, occurring between 673 K and 723 K, with a 14.3% weight loss, is attributed to the bi­pyridine molecules formerly present as [H(bipy)]⁺ cations. The latter assignment is based on the fact that these cationic entities are more robustly linked than their crystallized analogues. The last step, between 723 K and 813 K (42.7% weight loss), is the final degradation of the TPPS units. The calcination product was identified by X-ray powder diffraction analysis and it consists of Mn₂O₃ (space group Rc, a = 5.04, c = 14.12 Å, γ = 120°; Lee et al., 1980).

Figure 5 Thermal analysis for compound 1.

Compounds 2 and 3 have been thermally characterized in our previous work (Fidalgo-Marijuan et al., 2015, 2013), showing high thermal stability (compound 2 up to 593 K and 3 up to 633 K). The thermogravimetry/differential scanning calorimetry (TG/DSC) curve for activated compound 2 is shown in Fig. S8.

Additionally, Fig. S9 shows the X-ray thermo-diffraction measurements (XRTD) of powdered single crystals for compounds 1 and 2. The results indicate that both compounds were thermally stable after activation for catalytic purposes.

3.3. Catalytic properties

Synthetic metalloporphyrin complexes have been largely used for a wide variety of catalytic transformations (Chatterjee et al., 2016; Rayati et al., 2016; Sengupta et al., 2016; Zhou et al., 2016), and in this work we have explored the catalytic activity of the monomeric framework [H(bipy)]₂[(MnTPPS)(H₂O)₂]·2bipy·14H₂O, 1, the dimeric framework μ-O-[FeTCPP]₂·16DMF, 2 (Fidalgo-Marijuan et al., 2015), and the one-dimensional framework [CoTPPS_0.5(bipy)(H₂O)₂]·6H₂O, 3 (Fidalgo-Marijuan et al., 2013). As previously shown, these three compounds exhibit features that make them suitable candidates for catalysis of different reactions. Firstly, the metal coordination spheres are either unsaturated or there are water molecules that are easy to remove during the activation stage, as shown by the thermogravimetric analysis. Fig. S10 shows a simplified scheme for 1, 2 and 3, highlighting the catalytic active centres. In addition, the networks are significantly accessible, with mobile DMF or water solvent molecules located in the cavities.

Thus, the catalytic performance was studied for the oxidation of alcohols, aldol and Knoevenagel condensations, and a one-pot cascade reaction for an acetal hydrolysis followed by a C—C Knoevenagel condensation (Scheme 1). The studied substrates for all the reactions are summarized in Table S5.

3.3.1. Oxidation of alcohols

The selective oxidation of alcohols to aldehydes is a relevant transformation in waste recovery and in organic synthesis because of the properties and chemical reactivity of carbonylic compounds that make aldehydes the preferred starting materials in many syntheses (Davis et al., 2013). Although considerable progress has been made using noble-metal nanoparticles such as Au (Corma & Garcia, 2008), it would still be desirable to develop catalysts based on less expensive metals and processes. In this sense, some porphyrinic compounds have been tested (Zou et al., 2013; Machado et al., 2013; Chen & Ma, 2016) in an effort to minimize costs and waste generation.

The reaction conditions were initially set using benzyl alcohol as a model substrate. Based on our previous experience (Fidalgo-Marijuan et al., 2015; Larrea et al., 2011), the reactions were carried out using tert-butyl hydro­peroxide (TBHP) as the oxidizing agent in aceto­nitrile. Using 5% catalyst and 1.5 equivalents of TBHP in 2 ml of solvent at 343 K, total conversions of 50% for 1, 73% for 2 and 71% for 3 were achieved after 7 h of reaction. The scope of the reaction was studied with various alcohols: 1-phenyl­ethanol, 1-hexanol and 1-octanol (Table 2). Figs. S11, S12 and S13 show the kinetic profiles of these oxidation reactions for 1, 2 and 3.

Table 2 Selective oxidation of several alcohols over catalysts 1, 2 and 3 CT is the total conversion.     Compound 1 Compound 2 Compound 3 Substrate Oxidant TOF (h−1) CT (%) t (h) TOF (h−1) CT (%) t (h) TOF (h−1) CT (%) t (h) Benzyl-alcohol TBHP 72 70 20 72 73 7 143 77 20 1-Phenyl­ethanol TBHP 46 44 24 91 73 5 8 44 21 1-Hexanol TBHP 66 92 24 3 15 6 22 71 24 1-Octanol TBHP 2 12 24 6 9 18 2 25 24

The best result for 1 is achieved towards the oxidation of 1-hexanol, since 2 is better for 1-phenyl­ethanol. For benzyl alcohol oxidation, the conversion values are quite similar for the three catalysts, though compound 3 clearly shows a higher TOF. The poor conversion values achieved for 1-octanol in all cases could be explained by the fact that this substrate presents more steric hindrance. A comparison of these results with similar porphyrinic catalysts found in the literature indicates a significant reduction in the reaction time (half time) for catalyst 2 (Modak et al., 2013). Moreover, comparing the benzyl alcohol results with classic Rh-, Ru- and Ce-based catalysts showed the conversion rates are slightly higher and have much shorter reaction times (Wusiman & Lu, 2015; Burange et al., 2013; Sarkar et al., 2014).

One of the disadvantages of heterogeneous catalysis is the difficulty of studying the reaction mechanisms; often the involved intermediates are unknown. Even so, in the proposed mechanism for alcohol oxidation the initial stage consists of activation of TBHP by coordination to the unsaturated metal centre in order to obtain the corresponding peroxo species. After coordination, tert-butoxyl radicals are generated, abstracting an H atom from the substrate and leading to the corresponding aldehyde or ketone (Fig. 6) (Orive et al., 2013).

Figure 6 Proposed mechanism for the alcohol oxidations with TBHP over catalyst 2. Colour code: Fe purple, C grey, N blue and O red. Bonds to be removed and created are marked in red and blue, respectively.

3.3.3. Knoevenagel condensation

Taking into account the previous results, compound 2 was also tested as a catalyst for the Knoevenagel condensation reaction (Scheme 1c) between various substrates and derivatives (Table 4) and malono­nitrile (pK_a = 11.1). As above, the reaction conditions were set using benzaldehyde as the substrate, 5% catalyst, 1.0 equivalent of malono­nitrile in 2 ml of toluene and 2 µl of do­decane as internal standard at 343 K, reaching a total conversion of 79% after 22 h of reaction (Table 4). The scope of the reaction was then studied with p-tolu­aldehyde, p-fluoro­benzaldehyde, 4-chloro­benzaldehyde and 3-nitro­benzaldehyde. Fig. S16 shows the kinetic profiles of the Knoevenagel condensation reactions.

Table 4 Knoevenagel condensation over catalyst 2 Substrate TOF (h−1) CT (%) t (h) Benzaldehyde 49 79 22 p-Tolu­aldehyde 53 81 24 p-Fluoro­benzaldehyde 32 69 24 p-Chloro­benzaldehyde 137 100 24 m-Nitro­benzaldehyde 129 100 18

As observed, when introducing substituents into the meta- or para-positions of the benzaldehyde ring, the conversion rates differ as a result of electronic effects, following the order of reactivity: m-nitro­benzaldehyde ≃ p-chloro­benz­aldehyde > p-tolu­aldehyde ≃ benzaldehyde > p-fluoro­benz­aldehyde.

For both aldol and Knoevenagel condensations, the activation of the carbonyl groups is prompted by a Lewis acid (the metal ion). The proximity of the active centres (Fe ions) meant that a mechanism involving two-site adsorption of the donor molecule could be proposed (Fig. 7) (Larrea et al., 2015; Položij et al., 2014). In fact, the distance of 5.656 (1) Å between Fe^III ions allowed the cyanide groups of malono­nitrile [N⋯N distance 4.319 (3) Å] to interact with the Fe active centres. Comparing these results with other MOFs (Larrea et al., 2015), the obtained conversion rates and TOF are among the best using only 5% catalyst under similar reaction conditions.

Figure 7 Proposed mechanism for the benzyl alcohol Knoevenagel condensation over catalyst 2. Colour code: Fe purple, C grey, N blue and O red. Bonds to be removed (red dashed lines) and created (turquoise dashed lines) are shown.

3.4. Heterogeneity and recyclability tests

The heterogeneous nature of catalysts 1 and 3 towards the oxidation of alcohols were tested using benzyl alcohol (2 has been tested previously; Fidalgo-Marijuan et al., 2015). For rigorous proof of heterogeneity, a test (Sheldon et al., 1998) was carried out by filtering the catalyst from the reaction mixture at 343 K after 20 min, when conversions of 24% and 47% had been reached for 1 and 3, respectively. The filtrate was allowed to react for up to 7 h. The reaction mixture and the filtrate were analysed afterwards by GC–MS. No significant change in the conversion rate was found for the filtrate (Fig. 8), meaning that the active species does not leach and the observed catalysis is truly heterogeneous in nature.

Figure 8 Kinetic profiles of the oxidation of benzyl alcohol (a) over compound 1 and (b) over compound 3 after hot filtering with TBHP.

The recyclability of catalysts 1 and 3 was also tested for the benzyl alcohol oxidation. The catalyst was recovered after the reaction by centrifugation and washed several times with aceto­nitrile, then dried at 373 K and reused. As shown in Table S6, catalyst 3 maintains activity after five cycles, whereas 1 shows a small decrease.

As was previously done for the oxidation reactions, the heterogeneous nature of the catalyst and recyclability were tested or the aldol and Knoevenagel condensations by hot filtration. As shown in Fig. 9, the experiments reveal that 2 is a truly heterogeneous catalyst for this reaction. Additionally, the catalyst was reused over five cycles and shows a progressive decrease in catalytic activity after the third cycle (Table S7).

Figure 9 Kinetic profile of the condensation of benzaldehyde with malono­nitrile over compound 2 after hot filtering.

After the catalytic reactions, the catalysts were recovered by centrifugation, washed with aceto­nitrile, ethanol or toluene and then characterized by IR spectroscopy. The IR spectra of the recovered catalyst for all reactions showed that the chemical-bond systems remained unchanged (Fig. S18). In fact, the solid shows the same characteristic vibration modes as the original compound. As shown in Fig. S18, the characteristic vibrations of the porphyrin macrocycle are present. Additionally, both the fresh catalyst and the recovered solid after the reaction were studied by TEM, as discussed below.

3.5. Transmision electron microscopy

In order to carry out a deeper characterization of the recovered catalyst, compounds 2 and 3 were analysed by TEM before and after the catalytic reactions. Compound 1 is unstable under an electron beam, so it was not analysed by TEM. TEM analysis shows that compounds 2 and 3 maintain a certain grade of crystallinity following the catalytic reactions. Moreover, the pre- and post-catalysis particles of 2 and 3 keep their morphology: elongated prisms for 2 and curved-edge particles for 3 (Fig. S19).

The crystalline nature and moderate stability of samples 2 and 3 under an electron beam allowed us to measure the lattice spacing for both compounds. The HRTEM images (Fig. 10) of the pristine sample (a) and the recovered residue after the catalytic reaction (b) of compound 2 reveal a lattice spacing of 13.45 Å along the width of the crystal. This observed lattice spacing corresponds to the (101), and (210) set of crystallographic planes. For compound 3, the pristine sample (c) and the recovered residue (d) present a spacing near to 14.02 Å, which corresponds to the (011) set of crystallographic planes. Therefore, both compounds maintain the same lattice spacing before and after the catalytic reactions so, as previously observed by IR spectroscopy, compounds 2 and 3 keep their structural integrity.

Figure 10 HRTEM images for pristine compounds (a) 2 and (c) 3 and the recovered residues after the catalytic reactions for (b) 2 and (d) 3. Lattice spacing is marked by yellow lines and the upper right image corresponds to the Fourier transform of the area inside the blue square.