Modulation of photocatalytic properties through counter-ion substitution: tuning the bandgaps of aromatic sulfonium octamolybdates for efficient photo-degradation of rhodamine B

Non-piezoelectric SiO2 amorphous nanomaterials for highly tribocatalytic water purification

Being widely available in the earth's rock layers, SiO2 is among the earth's most thoroughly distributed natural mineral resources. Here, non-piezoelectric amorphous SiO2 mineral nanoparticles have been experimentally designed for efficient tribocatalytic dye degradation under mechanical friction provided by 400-1200 rpm low-velocity stirring. The friction between the catalyst surface and the stirring rod leads to the generation of positive and negative charges, which react with hydroxide and oxygen, respectively, in the dye solution to produce some active substances, resulting in tribocatalytic organic dye degradation. After being mechanically stirred at 1000 rpm for 6 h using amorphous SiO2 mineral nanoparticle catalysts, ∼95.2% of Rhodamine B dye can be obviously degraded. Radical trapping experiments show that ˙OH and ˙O2- are the main active substances. Furthermore, increasing the contact area or the friction contact interface's roughness is helpful for enhancing the tribocatalytic performance. After 3 recycling cycles, the SiO2 nanoparticles can still degrade ∼89.2% of RhB dye. These low-cost SiO2 mineral nanoparticles, with the advantage of being widely distributed, have the potential to harvest common environmental mechanical friction energy for the purpose of organic pollutant degradation.

Modulating the catalytic properties of decavanadate hybrids using a mixed counterion strategy for selective oxidation of thiophene-based sulfides and detoxification of mustard gas simulant

Selective oxidation of sulfides to sulfoxides, especially thiophene-based sulfides, is a challenging task. Herein, we report a mixed counterion strategy in polyoxometalate (POM) chemistry to tune the selectivity of sulfoxidation reaction catalyzed by decavanadate cluster-based hybrids using H2O2 as the oxidant under ambient conditions. By employing two different aryl sulfonium counterions (ASCIs) bearing different organic functional groups (phenol/aldehyde/salicylaldehyde/2,6-diformyl phenol) in a 1 : 1 synthetic feed ratio, we have generated a series of decavanadate-based hybrids HY1-HY6. Different functional groups on the periphery of hybrids HY1-HY6 helped control the efficiency and selectivity of the sulfoxidation reaction by fine-tuning the electronic and supramolecular effects of these hybrids as catalysts. Further, these hybrids were also applied as catalysts for detoxifying 2-chloroethyl ethyl sulfide (CEES), a mustard gas simulant. The hybrid HY5, with a structural formula (DFHPDS)2(FPDS)2[H2V10O28](H2O)3 (DFHPDS = (3,5-diformyl-4-hydroxyphenyl)dimethylsulfonium, and FPDS = (4-formylphenyl)dimethylsulfonium) showed the best catalytic properties in the series, with up to 99% conversion and 85% and 99% selectivity towards sulfoxide in the case of dibenzothiophene (DBT) and CEES, respectively. This study's findings open new avenues for tuning the catalytic properties of POM-based hybrids toward selective organic transformation reactions by using a mixed counterion strategy.

Aryl selenonium vs. aryl sulfonium counterions in polyoxometalate chemistry: the impact of Se+ cationic centers on the photocatalytic reduction of dichromate

A selenonium organic counter ion has been used in polyoxometalate chemistry to develop a new aryl selenonium polyoxometalate (POM) hybrid, and its photocatalytic properties have been explored in comparison with an aryl sulfonium POM-hybrid counterpart for the first time. The chalcogenonium counterions, namely, methyldiphenylsulfonium trifluoromethane sulfonate (MDPST) and methyldiphenylselenonium trifluoromethane sulfonate (MDPSeT), and their octamolybdate ([Mo8O26]4-) hybrids, 1 and 2, with the general formula (C13H13X)4[Mo8O26] (where X = S for 1 and Se for 2) were synthesized and characterized. Hybrids 1 and 2 vary in their chalcogenonium cationic center (S+vs. Se+), which enabled a direct comparison of their photocatalytic properties as a function of the cationic center. The photocatalytic activities of hybrids 1 and 2 were tested using the reduction of dichromate (Cr2O72-) as a model reaction under UV irradiation. A 99% photocatalytic reduction of Cr2O72- with a rate constant of 0.0305 min-1 was achieved with hybrid 2, while only a 67% reduction with a rate constant of 0.0062 min-1 was observed with hybrid 1 in 180 minutes. The better catalytic performance of hybrid 2 may be correlated to the larger atomic radii of Se than S, which helps in better stabilizing the photogenerated electron-hole (e--h+) pair on the POM cluster by polarizing its lone pair more efficiently compared to S. The catalytic recyclability was tested for up to 4 cycles using hybrid 2, and up to 98% reduction was obtained even after the 4th cycle. Recyclability tests and control experiments also indicated the generation of some elemental Se through possible cleavage of some C-Se bonds of MDPSe under prolonged UV exposure during catalysis, and the Se thus generated was found to contribute to the catalytic reduction of dichromate. This study, therefore, opens new avenues for aryl selenonium moieties and their POM hybrids for potential catalytic applications.

Multifunctional Aryl Sulfonium Decavanadates: Tuning the Photochromic and Heterogeneous Oxidative Desulfurization Catalytic Properties Using Salicylaldehyde-type Functional Moieties on Counterions

Multifunctional materials based on polyoxovanadates (POVs) have rarely been reported. Herein, we used aryl sulfonium counterions (ASCIs) bearing a salicylaldehyde-type functionality to tune the properties of decavanadate ([V10O28]6-)-based hybrids for their application in photochromism and heterogeneous oxidative desulfurization (ODS) catalysis. The counterions FHPDS ((3-formyl-4-hydroxyphenyl)dimethylsulfonium), DFHPDS ((3,5-diformyl-4-hydroxyphenyl)dimethylsulfonium), and EFPDS ((4-ethoxy-3-formylphenyl)dimethylsulfonium) were clubbed with the decavanadate cluster to generate the hybrids (FHPDS)4[H2V10O28](H2O)4 (HY1), (DFHPDS)4[H2V10O28](H2O)3 (HY2), and (EFPDS)4[H2V10O28](H2O)6 (HY3). The photochromic properties of these hybrids were tested under 365 nm irradiation, which showed a color change from yellow to green. Different hybrids exhibited different photocoloration half-life (t1/2) values in the range of 0.77-28.38 min, suggesting the dependence of the photocoloration properties upon functional groups on the counterions. The hybrid HY2, having a 2,6-diformyl phenol moiety on the ASCI, exhibited an impressive t1/2 of 0.77 min. UP to 70% reversibility of photocoloration was achieved for the best photochromic hybrid HY2 in 48 h at 70 °C under an oxygen atmosphere. Theoretical and experimental data suggested that some of these aryl sulfonium POVs follow a different e--h+ stabilization mechanism than traditional sulfonium POM hybrids. Further, the salicylaldehyde-type ASCIs control the solubility of the decavanadate hybrids, which enables their application as heterogeneous catalysts for the selective oxidation of various sulfides. The nature of the substituents on the ASCIs also affected their catalytic activities; the counterion that facilitates the reversible V4+/V5+ switching enhances the catalytic ODS efficiency of the hybrids. Using HY2 as the catalyst, up to 99% conversion and 96% selectivity toward sulfones were achieved in dibenzothiophene (DBT) oxidation. The present study suggests a new promising approach for controlling POVs' photoresponsive and catalytic properties by using ASCIs bearing salicylaldehyde-type functional moieties.

Keggin Cluster Modulated Photocatalytic Activity of Aryl Sulfonium Polyoxometalate Hybrids toward Dichromate Reduction

Dichromate (Cr₂O₇^2-) ion having chromium in its +6 oxidation state is a carcinogen and a potential threat to humans and aquatic life. The photocatalytic reduction of toxic Cr(VI) species into less toxic Cr(III) is an important target in heterogeneous catalysis. In this work, the catalytic activities of a series of Keggin cluster-based aryl sulfonium polyoxometalate hybrids, (FPDS)₃[PMo₁₂O₄₀] (1), (FPDS)₃[PW₁₂O₄₀] (2), (FPDS)₄[SiMo₁₂O₄₀] (3), and (FPDS)₄[SiW₁₂O₄₀] (4), toward the photocatalytic reduction of Cr(VI) have been analyzed and compared. Here, we used the aryl sulfonium counterions to modulate the POM cluster's solubility in water and stabilize the photogenerated e^--h⁺ pair on the cluster. All of the hybrids 1-4 catalyzed the reduction of Cr(VI) to Cr(III) under ultraviolet (UV) irradiation, and their photocatalytic efficiencies followed the order hybrid 1 > hybrid 3 > hybrid 2 > hybrid 4, with the rate-constant values of 0.048, 0.0056, 0.0035, and 0.0028 min^-1, respectively. Hybrid 1 with [PMo₁₂O₄₀]^3- Keggin cluster exhibited the best photocatalytic activity in the series yielding a 99% reduction in 120 min. The reasons behind the best photocatalytic activity of hybrid 1 are identified as its low band gap, less charge recombination, and fast photoresponse. The electron-trapping analyses performed using AgNO₃ revealed electrons as the main reactive species responsible for the photocatalytic reduction of Cr(VI). A plausible photocatalytic mechanism has also been proposed based on electron-trapping experiments. The present study shows that aryl sulfonium Keggin hybrids can function as efficient photocatalysts for Cr(VI) reduction, and their catalytic efficiency varies with the nature of the Keggin cluster.

Applications of Viologens in Organic and Inorganic Discoloration Materials

Viologen derived from 4,4'-bipyridine has attracted much attention because of its color changing properties with electron transfer, unique redox stability and structural diversity. These characteristics have led to its successful use in various applications, in particular in color-changing materials. In the past few years, researchers have been working on the syntheses of viologen-based color-changing functional materials, and such materials have been widely used in many fields. In photochromic materials, it is used as anti-counterfeiting material; in thermochromic, it is used as memory storage material, and in electrochromic, it is used as a battery material. This Review discusses the progress of viologen in organic and inorganic discoloration materials in recent years. The syntheses of viologen and its derivatives are summarized, and its application in the field of discoloration materials is introduced.