ABSTRACT
The catalytic oxidation of phenethoxybenzene as a lignin model compound with a ß-O-4 bond was conducted using the Keggin-type polyoxometalate nanocatalyst (TBA)5[PMo10V2O40]. The optimization of the process's operational conditions was carried out using response surface methodology. The statistically significant variables in the process were determined using a fractional factorial design. Based on this selection, a central circumscribed composite experimental design was used to maximize the phenethoxybenzene conversion, varying temperature, reaction time, and catalyst load. The optimal conditions that maximized the phenethoxybenzene conversion were 137 °C, 3.5 h, and 200 mg of catalyst. In addition, under the optimized conditions, the Kraft lignin catalytic depolymerization was carried out to validate the effectiveness of the process. The depolymerization degree was assessed by gel permeation chromatography from which a significant decrease in the molar mass distribution Mw from 7.34 kDa to 1.97 kDa and a reduction in the polydispersity index PDI from 6 to 3 were observed. Furthermore, the successful cleavage of the ß-O-4 bond in the Kraft lignin was verified by gas chromatography-mass spectrometry analysis of the reaction products. These results offer a sustainable alternative to efficiently converting lignin into valuable products.
ABSTRACT
Resumen Se sintetizaron catalizadores (SNX#WPA) basados en ácido tungstofosfórico, en soportes de nanoestructuras de sílice (SNX), con distribución de diámetros y tamaños de mesoporos variables. Las SNX se prepararon en medio de octano/agua, usando poliestireno y bromuro de cetiltrimetilamonio como plantillas. Los materiales se caracterizaron por DRX, TEM y adsorción/desorción de nitrógeno. La relación octano/agua influyó tanto en la morfología y el tamaño de las SNX como en la distribución del tamaño de poro. Las SNX obtenidas utilizando relaciones OCT/H2O en el rango de 0,07-0,35, presentan mesoporos pequeños (5-6 nm) y grandes (28-34 nm), generados principalmente por poliestireno. Los mesoporos grandes y su contribución de volumen fueron claramente más altos que en las muestras SN1, SN2 y SN3. La estructura y la morfología de SNX#WPA fueron similares a las de las SNX usadas como soporte. Además, la caracterización de todos los materiales SNX#WPA por FT-IR y 31P NMR indicó la presencia de especies [PW12O40]3- y [H3-XPW12O40](3-X)- sin degradar. Según los resultados de la valoración potenciométrica, los sólidos presentaron sitios ácidos muy fuertes. Se evaluó la actividad de SNX#WPA como catalizadores en la síntesis de quinoxalinas, a partir de lo cual se obtuvieron altos rendimientos, sin formación de subproductos. De ello resultó que los materiales preparados son catalizadores altamente selectivos y reutilizables.
Abstract Tungstophosphoric acid supported on silica nanostructures (SNX#WPA) with variable diameter and mesopore size distribution were synthetized. Silica nanostructures (SNX) were prepared in octane/aqueous media using polystyrene and CTAB as organic templates. The materials were characterized by XRD, SEM, TEM and dinitrogen adsorption/ desorption isotherm analysis. The octane/ water ratio influenced the morphology and size of SNX prepared, as well as its pore size distribution. The SNX samples obtained using OCT/H2O ratios in the range 0.07-0.35 (SN4, SN5, and SN6 samples). present small (5-6 nm) and large (28-34 nm) mesopores (mainly generated by polystyrene). Large mesopores and their volume contribution were clearly higher than in the SN1, SN2, and SN3 samples. The structure and morphology of SNX#WPA samples were similar to those of the SNX. Furthermore, the characterization of all the SNX#WPA materials by FT-IR and 31P NMR indicated the presence of undegraded [PW12O40]3- and [H3-XPW12O40](3-X)-species. According to the potentiometric titration results, the solids presented very strong acid sites. The performance of SNX#WPA materials as catalysts in the synthesis of quinoxalines was evaluated. The yields achieved were high, without formation of by-products resulting from competitive reactions or decomposition products, so the prepared materials are highly selective and reusable catalysts.
Resumo Catalisadores (SNX#WPA) baseados em ácido tungsofosfórico suportado em nanoestruturas de sílica (SNX) foram sintetizados com distribuição de tamanhos e diâmetros variados de mesoporos. Os SNX foram preparados em meio octano/aquoso usando poliestireno e brometo de cetiltrimetilamônio como modelos orgânicos. Os materiais foram caracterizados por DRX, TEM e adsorção/ dessorção de nitrogénio. A razão octano/ agua influenciou a morfologia e o tamanho do SNX, bem como a distribuição do tamanho dos poros. O SNX obtido usando razões OCT/ H2O na faixa de 0,07-0,35, possui mesoporos pequenos (5-6 nm) e grandes (28-34 nm) (gerados principalmente por poliestireno). Mesoporos grandes e sua contribuição em volume foram claramente maiores do que nas amostras SN1, SN2 e SN3. A estrutura e a morfologia do SNX#WPA foram semelhantes às do SNX usado como suporte. Além disso, a caracterização de todos os materiais SNX#WPA por FT-IR e 31P NMR indicou a presença das espécies [PW12O40]3- e [H3-XPW12O40](3-X)- sem degradar. De acordo com os resultados da titulação potenciométrica, os sólidos apresentaram locais ácidos muito fortes. A atividade do SNX#WPA como catalisadores na síntese de quinoxalinas foi avaliada, produzindo altos rendimentos, sem formação de subprodutos, resultando em materiais catalisadores altamente seletivos e reutilizáveis.
ABSTRACT
The Photo-Fenton-like (PF-like) process with minute Fe(III) concentrations and the Hydrogen Peroxide Photolysis (HPP), using Xe-lamp or solar light as sources of irradiation, were efficiently applied to eliminate the herbicide 2,4-D from water. PF-like experiments concerning ferric and H2O2 concentrations of 0.6â¯mgâ¯L-1 and 20â¯mgâ¯L-1 respectively, using Xenon lamps (Xe-lamps) as a source of irradiation and 2,4-D concentrations of 10â¯mgâ¯L-1 at pH 3.6, exhibited complete 2,4-D degradation and 77% dissolved organic carbon (DOC) removal after 30â¯min and 6â¯h of irradiation respectively whereas HPP (in absence of ferric ions) experiments showed a 2,4-D reduction and DOC removal of 90% and 7% respectively after 6â¯h of irradiation. At pH 7.0, HPP process achieved a 2,4-D abatement of approximately 75% and a DOC removal of 4% after 6â¯h. PF-like exhibited slightly improved 2,4-D and DOC removals (80% and 12% respectively) after the same irradiation time probably due to the low pH reduction (from 7.0 to 5.6). Several chlorinated-aromatic intermediates were identified by HPLC-MS. These by-products were efficiently removed by PF at pH 3.6, whereas at neutral PF-like and acid or neutral HPP, they were not efficiently degraded. With natural solar light irradiation, 10 and 1â¯mgâ¯L-1 of 2,4-D were abated using minor H2O2 concentrations (3, 6, 10 and 20â¯mgâ¯L-1) and iron at 0.6â¯mgâ¯L-1 in Milli-Q water. Similar results to Xe-lamp experiments were obtained, where solar UV-B + A light H2O2 photolysis (HPSP) and solar photo-Fenton-like (SPF-like) played an important role and even at low H2O2 and ferric concentrations of 3 and 0.6â¯mgâ¯L-1 respectively, 2,4-D was efficiently removed at pH 3.6. Simulated surface water at pH 3.6 containing 1â¯mgâ¯L-1 2,4-D, 20â¯mgâ¯L-1 H2O2 and 0.6â¯mgâ¯L-1 Fe(III) under natural sunlight irradiation efficiently removed the herbicide and its main metabolite 2,4-DCP after 30â¯min of treatment while at neutral pH, 40% of herbicide degradation was achieved. In the case of very low iron concentrations (0.05â¯mgâ¯L-1) at acid pH, 150â¯min of solar treatment was required to remove 2,4-D.
Subject(s)
2,4-Dichlorophenoxyacetic Acid/chemistry , Water Pollutants, Chemical/chemistry , Water Purification/methods , Hydrogen Peroxide/chemistry , Hydrogen-Ion Concentration , Iron/chemistry , Photolysis , Ultraviolet Rays , Water Purification/instrumentationABSTRACT
The TiO2/HZSM-11 materials were synthesized using titanium isopropoxide as a TiO2 precursor and HZSM-11 a medium pore size zeolite with high thermal and chemical resistance as support. The amount of titanium isopropoxide was varied in order to obtain TiO2 concentrations of 3, 10, 20, 30 and 50 wt% in the final material. They were characterized by a series of complementary techniques: X-ray diffraction (XRD), ultraviolet-visible diffuse reflectance spectroscopy (DRS), transmittance Fourier transform infrared spectroscopy (FTIR) and scanning electron microscopy (SEM). The surface area of the TiO2/HZSM-11 samples decreased with the increment of TiO2 loading. As result of the increment of the calcination temperature from 450 to 800°C an increase in the size of the anatase crystals was observed. However, the X-ray diffraction patterns of the solids only presented the characteristic peaks of the anatase phase. The catalytic activity of the materials in the photodegradation of Dichlorvos (DDVP) depended on the TiO2 amount the thermal treatment temperature. The sample containing 30% TiO2 calcined at 450°C showed the best catalytic performance and it can be reused without noticeable activity loss during at least four cycles. The catalytic performance was similar to that of the P25 Degussa used as a reference but its separation, recovery and reuse was easier.
Subject(s)
Dichlorvos/chemistry , Pesticides/chemistry , Photolysis , Titanium/chemistry , Zeolites/chemistry , Catalysis , Solutions , Surface Properties , TemperatureABSTRACT
Low-frequency ultrasound (LFUS) irradiation induces morphological, optical and surface changes in the commercial nano-TiO(2)-based photocatalyst, Evonik-Degussa P-25. Low-temperature electron spin resonance (ESR) measurements performed on this material provided the first experimental evidence for the formation of oxygen vacancies (V(o)), which were also found responsible for the visible-light absorption. The V(o) surface defects might result from high-speed inter-particle collisions and shock waves generated by LFUS sonication impacting the TiO(2) particles. This is in contrast to a number of well-established technologies, where the formation of oxygen vacancies on the TiO(2) surface often requires harsh technological conditions and complicated procedures, such as annealing at high temperatures, radio-frequency-induced plasma or ion sputtering. Thus, this study reports for the first time the preparation of visible-light responsive TiO(2)-based photocatalysts by using a simple LFUS-based approach to induce oxygen vacancies at the nano-TiO(2) surface. These findings might open new avenues for synthesis of novel nano-TiO(2)-based photocatalysts capable of destroying water or airborne pollutants and microorganisms under visible light illumination.
Subject(s)
Nanostructures/chemistry , Nanostructures/radiation effects , Oxygen/chemistry , Sonication/methods , Titanium/chemistry , Titanium/radiation effects , Absorption , High-Energy Shock Waves , Light , Materials Testing , Oxygen/radiation effects , Particle Size , Particulate Matter/chemistry , Particulate Matter/radiation effectsABSTRACT
Under air atmosphere, the photocatalytic discoloration of malachite green (MG) aqueous solutions (a triphenylmethane dye) in the presence of TiO(2) and UV light followed an oxidative pathway, involving an N-demethylation process evidenced by a blue shifting of the main absorption band with a maximum at 618 nm. This oxidative process was affected by the nature of the dye counter-ion and the pH of the solution. At pH 6.0, the oxidation was found to be faster than at pH 3.0, perhaps due to the poor interactions between MG and the semiconductor surface. Furthermore, with the presence of oxalate as counter-ion, the oxidative photocatalytic discoloration was negatively affected mainly at acidic pH. Under nitrogen atmosphere, some evidence was found about the double behaviour of MG when involved in the photocatalytic discoloration reactions pertaining to TiO(2) under these conditions. MG could be simultaneously oxidized, forming N-demethylated by-products, or reduced, thus leading to leuco-malachite green (LMG) (a colorless and toxic substance) as the main product. The LMG formation is favoured at low pH in the presence of oxalate as counter-ion.
Subject(s)
Coloring Agents/chemistry , Metal Nanoparticles/chemistry , Nitrogen/chemistry , Rosaniline Dyes/chemistry , Titanium/chemistry , Ultraviolet Rays , Air , Catalysis , Color , Coloring Agents/radiation effects , Hydrogen-Ion Concentration , Ions/chemistry , Metal Nanoparticles/radiation effects , Oxidation-Reduction , Rosaniline Dyes/radiation effects , Spectrophotometry, UltravioletABSTRACT
A series of mesoporous titania materials modified with tungstophosphoric acid (TPA) were successfully synthesized by using urea as low-cost template via sol-gel reactions, followed by removing the urea by extraction with water. They were characterized by FT-IR, 31P MAS-NMR, XRD, DTA-TGA, DRS, TEM and BET. The samples presented mesopores with a diameter higher than 3.0 nm. The S(BET) of the solids decreases with the increase of the TPA content and with the increase of the calcination temperature. According to FT-IR and 31P MAS-NMR studies the main species present in the samples is [PW12O40]3- anions, which was partially transformed into [P2W21O71]6- and [PW11O39]7- anion during the synthesis and drying step. The XRD patterns of the modified samples only exhibited the characteristic peaks of anatase phase. The presence of TPA retarded the crystallization of the anatase phase and its transformation into rutile phase. The point of zero charge decreased in parallel with the increment of tungstophosphoric acid in the samples and with the increase of the calcination temperature. The band gap energy decreased as a result of the introduction of TPA into the TiO2 matrix, but remained practically constant with the increase of the calcination temperature.
