Academic literature on the topic 'Cu2+ doped nanoparticles'

In this work, a simple, co-precipitation technique was used to prepare un-doped, pure tin oxide (SnO2). As synthesized SnO2 nanoparticles were doped with Cu2+ ions. Detailed characterization was carried out to observe the crystalline phase, morphological features and chemical constituents with opto-electrical and magnetic properties of the synthesized nanoparticles (NPs). X-ray diffraction analysis showed the existence of crystalline, tetragonal structure of SnO2. Both the sample synthesized here showed different crystalline morphology. The band gap energy (Eg) of the synthesized sample was estimated and it was found to decrease from 3.60 to 3.26 eV. The band gap energy reduced due to increase in Cu2+ dopant amount inside the SnO2 lattice. Optical properties were analyzed using absorption spectra and Photoluminescence (PL) spectra. It was observed that Cu2+ ions incorporated SnO2 NPs exhibited more degradation efficiencies for Rhodamine B (RhB) dye compared to un-doped sample under UV-Visible irradiation. The dielectric characteristics of un-doped, pure and Cu2+ incorporated SnO2 nanoparticles were studied at different frequency region under different temperatures. The ac conductivity and impedance analysis of pure and Cu2+ incorporated SnO2 nanoparticles was also studied. The magnetic properties of the synthesized samples were analysed. Both the sample showed ferromagnetic properties. The research indicated that the Cu2+ ions doping can make the sample a promising candidate for using in the field of optoelectronics, magneto electronics, and microwave devices.

A NIR cyanine@imidazole derivative Cy1 was synthesized and evaluated as a metal ion sensor in solution. Cy1 was shown to be very sensitive to all metal ions tested, presenting a blue shift in the absorption from 668 nm to 633 nm, followed by a change in colour from pale green to blue with Zn2+, Cd2+, Co2+, Ni2+ and Hg2+ ions. Despite the blue shift in the absorption, a decrease at 633 nm (with a colour change from pale green to colourless), as well as a quenching in the emission intensity at 785 nm were observed for Cu2+ ions. The results show the formation of sandwich complexes of two ligands per metal ion with the highest association constant observed for Cu2+ (Log Kass.abs = 14.76 ± 0.09; Log Kass.emis. = 14.79 ± 0.06). The minimal detectable amounts were found to be 31 nM and 37 nM, with a naked eye detection of 2.9 ppm and 2.1 ppm for Hg2+ and Cu2+ ions, respectively. These results prompted us to explore the applicability of Cy1 by its combination with nanomaterials. Thus, Cy1@ doped MNs and Cy1@ doped PMMA nanoparticles were synthesized. Both nanosystems were shown to be very sensitive to Cu2+ ions in water, allowing a naked-eye detection of at least 1 ppm for Cy1@ doped MNs and 7 ppm for Cy1@ doped PMMA. This colourimetric response is an easy and inexpensive way to assess the presence of metals in aqueous media with no need for further instrumentation.

Environmental nanotechnology has received much attention owing to its implications on environmental ecosystem, and thus is promising for the elimination of toxic elements from the aquatic surface. This work focuses on Cu-doped ZnSe nanoparticles using the co-precipitation method. The synthesized Cu-doped ZnSe nanoparticles were examined for structural, optical, and morphological properties with the help of XRD, FTIR, UV/vis diffuse reflection spectroscopy (DRS), FESEM, TEM, and XPS. The synthesized Cu-doped ZnSe nanoparticles revealed the presence of Cu2+ in the ZnSe lattice, which has been shown to take a predominant role for enhanced catalysis in the Cu-doped ZnSe nanoparticles. The synthesized Cu-doped ZnSe nanoparticles were investigated for their catalytic and antibacterial activities. The 0.1 M copper-doped ZnSe nanoparticles exhibited the highest rate of degradation against the methyl orange dye, which was found to be 87%. A pseudo-first-order kinetics was followed by Cu-doped ZnSe nanoparticles with a rate constant of 0.1334 min−1. The gram-positive and gram-negative bacteria were used for investigating the anti-bacterial activity of the Cu-doped ZnSe nanoparticles. The Cu-doped ZnSe nanoparticles exhibited enhanced photocatalytic and antibacterial activity.

This study investigated the production of Cu2+-doped CoFe2O4 nanoparticles (CFO NPs) using a facile sol−gel technique. The impact of Cu2+ doping on the lattice parameters, morphology, optical properties, and electrical properties of CFO NPs was investigated for applications in electrical devices. The XRD analysis revealed the formation of spinel-phased crystalline structures of the specimens with no impurity phases. The average grain size, lattice constant, cell volume, and porosity were measured in the range of 4.55–7.07 nm, 8.1770–8.1097 Å, 546.7414–533.3525 Å3, and 8.77–6.93%, respectively. The SEM analysis revealed a change in morphology of the specimens with a rise in Cu2+ content. The particles started gaining a defined shape and size with a rise in Cu2+ doping. The Cu0.12Co0.88Fe2O4 NPs revealed clear grain boundaries with the least agglomeration. The energy band gap declined from 3.98 eV to 3.21 eV with a shift in Cu2+ concentration from 0.4 to 0.12. The electrical studies showed that doping a trace amount of Cu2+ improved the electrical properties of the CFO NPs without producing any structural distortions. The conductivity of the Cu2+-doped CFO NPs increased from 6.66 × 10−10 to 5.26 × 10−6 ℧ cm−1 with a rise in Cu2+ concentration. The improved structural and electrical characteristics of the prepared Cu2+-doped CFO NPs made them a suitable candidate for electrical devices, diodes, and sensor technology applications.

In search of new approaches to treat bone infection and prevent drug resistance development, a nanosystem based on hollow bioactive glass nanoparticles (HBGN) of composition 79.5SiO2-(18-x)CaO-2.5P2O5-xCuO (x = 0, 2.5 or 5 mol-% CuO) was developed. The objective of the study was to evaluate the capacity of the HBGN to be used as a nanocarrier of the broad-spectrum antibiotic danofloxacin and source of bactericidal Cu2+ ions. Core-shell nanoparticles with specific surface areas close to 800 m2/g and pore volumes around 1 cm3/g were obtained by using hexadecyltrimethylammonium bromide (CTAB) and poly(styrene)-block-poly(acrylic acid) (PS-b-PAA) as structure-directing agents. Flow cytometry studies showed the cytocompatibility of the nanoparticles in MC3T3-E1 pre-osteoblastic cell cultures. Ion release studies confirmed the release of non-cytotoxic concentrations of Cu2+ ions within the therapeutic range. Moreover, it was shown that the inclusion of copper in the system resulted in a more gradual release of danofloxacin that was extended over one week. The bactericidal activity of the nanosystem was evaluated with E. coli and S. aureus strains. Nanoparticles with copper were not able to reduce bacterial viability by themselves and Cu-free HBGN failed to reduce bacterial growth, despite releasing higher antibiotic concentrations. However, HBGN enriched with copper and danofloxacin drastically reduced bacterial growth in sessile, planktonic and biofilm states, which was attributed to a synergistic effect between the action of Cu2+ ions and danofloxacin. Therefore, the nanosystem here investigated is a promising candidate as an alternative for the local treatment of bone infections.

The photocatalytic activity and mechanism of photocatalysts made of ZnO nanoparticles before and after doping with different Cu2+ concentrations were studied by electron paramagnetic resonance and X-ray diffraction. The nanoparticles were prepared using sol–gel method. UV-vis spectrometers characterized the photocatalytic degradation effect of the composite samples on methyl orange solution. The results of X-ray diffraction showed that the hexagonal wurtzite structure of ZnO changed little by Cu2+ doping. With the increase in doping concentration, the CuO and Cu2O diffraction peaks were detected successively in the crystal. The results of the electron paramagnetic resonance test for all samples indicated three kinds of unpaired electrons with g factors of 2.07, 1.997, and 1.954. Further analysis confirmed them to be Cu2+, V+O, and Zn–H complexes. Photocatalytic degradation results of methyl orange showed that proper doping (c(Cu2+) = 2%) could improve the photocatalytic activity of ZnO. The main reason for the increase was that the substitution of Cu2+ for Zn2+ in the crystal lattice produced Zni, and the Zn atom could act as the donor to release electrons, so that the number of electrons in the material increased, which indirectly increased the superoxide radical content in the solution and improves the photocatalytic activity of ZnO.

TiO2 and Cu-doped TiO2 nanoparticles (NPs) with totally extraordinary substance of Cu by exploitation hydrothermal method. The part immaculateness, morphology, molecule estimate, optical properties, and elemental composition of as-incorporated Cu-doped TiO2 NPs were investigated by numerous systematic methods. The XRD designs unveiled Cu-doped TiO2 NPs inside the part unadulterated anatase phase. The plane of (101) XRD and XPS results show the lucky doping of Cu2+ inside the TiO2 lattice. The optical edges of Cu-doped TiO2 demonstrated a transparent light absorption in visible region that assumes an essential part inside the photocatalytic action underneath characteristic daylight. Certain Cu2+ content shows least PL intensity that backings the decrease in recombination rate of charge species. In addition, to get a handle on photocatalytic action, we have tried Cu-doped TiO2 for the degradation of Malachite Green (MG) under visible light. A large portion of 85% degradation was found for Cu-doped TiO2 (1.71 wt.%) underneath daylight minimum of 180 min, severally, that is past that of TiO2 (53%). Also, the degradation of the MG was affirmed by measurement of the chemical oxygen demand of the photodegraded solution. These outcomes demonstrates that the Cu-doped TiO2 NPs are extremely productive for the photodegration of the MG.

2009/2010
Nanosized inorganic particles constitute a field of rapidly growing interest and their tailored synthesis is currently subject of intense study. These particles may show unique properties that are not shared by bulk materials and therefore find a palette of innovative applications, e.g., as diagnostic means, or in drug and even gene delivery, offering the advantage over polymer nanoparticles because they are stable, biologically inert, biocompatible and it is easy to introduce functional groups by modification of the surface hydroxyls. Among various synthetic routes the most explored are the ones carried out in bulk, especially the Stöber synthesis, however the final product are mostly polydisperse particles whose size is difficult to control. On the other hand, w/o microemulsion is providing suitable environment for the control of the particle nucleation and growth kinetics, as the nanodroplets of water are nanoreactors for the synthesis. The main advantage is that the procedure does not require extreme conditions of temperature and pressure and the particle size and shape can be controlled simply by controlling the microemulsion parameters where the most important are the water-to-surfactant molar ratio, R, and water-to-TEOS molar ratio, h. The previous studies focused on the latter synthetic route, in base-catalyzed systems, concerned mainly the evolution of silica nanoparticles and the best results were achieved by SAXS. The volume fraction versus time data gave an insight into nucleation and growth and is in agreement with first order kinetics with respect to TEOS concentration. However, we wanted to understand better the environment in which the synthesis takes place and shed light on the evolution of the soluble species, both of the constituents of the microemulsion and of those taking part to reaction. The soluble species present in the reaction mixture that leads to silica nanoparticle production through the base catalyzed hydrolysis of tetraethyl orthosilicate (TEOS) and the successive condensation were investigated in situ, under the actual synthesis conditions, by means of 1H, 13C, and 29Si NMR spectroscopy. The two former nuclei, owing to higher sensitivity and their presence both in the reacting species and in the constituents of the w/o microemulsion (cyclohexane-Igepal CA520 (5 polyoxyethylene iso-octylphenyl ether)-concentrated ammonia solution) afforded insight into the inverse microemulsion and allowed us to assess the kinetic rate of the hydrolysis step. It was verified that the microemulsion microstructure is maintained during the reaction. Special attention was paid to the reaction medium, and an extended assignment of the 1H and 13C resonances of the surfactant head group was performed. These head group signals undergo some changes due to the environmental modifications induced by transition from cyclohexane solution to w/o microemulsion and further to NH3 containing w/o microemulsion. We followed the quantitative evolution of TEOS and EtOH and assessed their preferential distribution in the various environments provided by this, on the mesoscale heterogeneous, reaction medium. Most authors agree that TEOS is localized mainly in the oil however they argue whether EtOH is preferentially in the water-pools or in oil. The clarification was achieved by means of PGSTE NMR since the diffusion coefficients are commonly exploited to characterize microemulsions, to determine the connectivity of the phase and they can be used to obtain the size of water droplets. It was revealed that NH3 exchanges among the inverse micelles diffusing through cyclohexane and confirmed that the preferred localization for ethanol, a byproduct of the reaction, is the bulk oil. Moreover, it was confirmed that TEOS is localized mainly in the oil. The characterization of the final nanoparticles was carried out by means of transmission electron microscopy (TEM) and it was revealed that the final product were monodispersed particles with radius of 20 nm. The synthesis of SiO2 nanoparticles in an acid-catalyzed system is especially interesting from nanotechnological point of view, owing to the different physical nature of silica synthesized under acidic rather than basic conditions, and from an applicative point of view since intended guest species are not always base resistant. Unfortunately, the application of an acid-catalyzed sol-gel process seems less than straightforward. An inverse microemulsion looks like an optimal reaction medium able to limit the growth of silica particles within the nanometer range. However, relatively few studies have been reported to date, and to the best of our knowledge, only one involves the entire process conducted in an inverse microemulsion with a water core that remains stable throughout the course of the reaction. The cyclohexane-Igepal inverse microemulsion, comprehensively established for the synthesis of silica nanoparticles in NH3-catalyzed sol-gel process, was alternatively studied with an acid-catalyzed sol-gel process. TEOS was used as the silica precursor, while two different aqueous phases containing either HNO3 or HCl at two different concentrations, 0.1 and 0.05 M, were examined in the presence and in the absence of NaF, a catalyst of the condensation step. The evolution of the overall reacting system, specifically hydrolysis and polycondensation of reaction intermediates, was monitored in situ by SAXS. No size variation of the inverse micelles was detected throughout the sol-gel process. Conversely, the density of the micellar core increased after a certain time interval, indicating the presence of the polycondensation product. The IR spectra of the reacting mixture were in agreement with such a hypothesis. 1H and 13C NMR measurements provided information on the soluble species, the surfactant, and TEOS. The TEOS consumption was well fitted by means of an exponential decay, suggesting that a first-order kinetics for TEOS transpires in the various systems examined, with rate constants dependent not only on the acid concentration but also on its nature (anion specific effect), on the presence of NaF, and on the amount of water in the core of the inverse micelle. The self-diffusion coefficients, determined by means of PGSTE NMR, proved that a sizable amount of the byproduct ethanol was partitioned inside the inverse micelles. Moreover, the DOSY spectrum contributed to the assignment of the signals of various oligomeric species present in the commercial mixture of Igepal CA520, since the head group, which is a short polyoxyehtylene chain, is somewhat polydisperse. The embedment of Igepal CA520 in an acid-catalyzed inverse microemulsion led to the separation of 1H signals of the various oligomeric components. This ensued from the differential partitioning between the oil and the surface of the inverse micelles, which depends on the ethyleneoxide number (EON) of the head group and the partition degree, between the two environments, for each individual oligomeric species, and afforded further insight into nonionic inverse microemulsions. It was possible to ascertain that the length distribution of the polyethyleneoxide chains is in good agreement with the Poisson distribution theoretically predicted for the polymerization of ethylene oxide. Characterization of the final product was carried out by means of thermogravimetric analysis (TGA), differential scanning calorimetry (DSC), and TEM, which concurrently confirmed that the silica isolated from the inverse nonionic microemulsion is not significantly different from the product of a bulk acid-catalyzed sol-gel synthesis. TEM micrographs illustrated particles with diameters smaller than the diameter of the inverse micelles as determined by SAXS, due to a shrinkage effect, in addition to nanostructured aggregates in the range 20-100 nm. The metal doped silica systems are important for optical applications and if the metal ions are finely dispersed on silica matrix very efficient catalysators can be obtained. The synthesis of silica nanoparticles in HCl-catalyzed inverse microemulsion was carried out in the presence of both Cu2+ and Co2+ ions with the aim to get correspondingly doped nanoparticles. The systems were characterized by means of 1H and 13C NMR and the quantitative evolution of TEOS and EtOH was followed. The introduction of metals in the glass matrix strongly influences their optical visible absorption spectrum so the UV-Vis spectroscopy was applied in the study. The isolated nanoparticles were characterized by means of IR and Raman spectroscopy and their size was determined by TEM. It was demonstrated that inverse micelles can be used to produce Co2+ and Cu2+ doped SiO2 nanoparticles with diameter of about 3 and 4 nm, respectively. Spherical particles smaller than the micellar size and, in the case of Cu2+ doped system, larger, irregularly shaped aggregates with diameter up to 1 μm were observed. Lots of darker zones were observed in the TEM images of some larger particles and aggregates containing Cu and may be assigned to Cu metal particles encapsulated in silica matrix. Therefore, cobalt was successfully doped in silica nanoparticles while copper doping seemed less satisfactory.
Particelle inorganiche di grandezza nanometrica costituiscono un settore di interesse in rapida crescita e la loro sintesi è attualmente oggetto di intenso studio. Queste particelle possono presentare proprietà uniche non condivise da materiali bulk e quindi trovare una vasta gamma di applicazioni innovative, ad esempio, come mezzo diagnostico, o per drug delivery e anche gene delivery, offrendo il vantaggio rispetto nanoparticelle polimeriche di essere stabili, biologicamente inerti, biocompatibili e facilmente funzionalizzabili con gruppi funzionali modificando dei ossidrili superficiali. Tra le varie vie sintetiche più esplorate sono quelle effettuate in bulk, in particolare la sintesi di Stöber, ma il prodotto finale sono particelle per lo più polidisperse la cui dimensione è difficile da controllare. D'altra parte, la microemulsione a/o sta fornendo l'ambiente adatto per il controllo della cinetica di nucleazione e crescita delle particelle, siccome le nanogoccioline d'acqua sono i nanoreattori per la sintesi. Il vantaggio principale è che la procedura non richiede condizioni estreme di temperatura e pressione e la dimensione delle particelle e la forma possono essere controllati semplicemente attraverso il controllo dei parametri di microemulsione tra cui i più importanti sono il rapporto molare acqua-tensioattivo, R, e acqua-TEOS, h. Gli studi precedenti focalizzati su quest'ultima linea sintetica, nei sistemi base-catalizzati, riguardavano principalmente l'evoluzione delle nanoparticelle di silice ed i migliori risultati sono stati raggiunti con SAXS. I dati di frazione di volume in funzione del tempo hanno fornito informazioni sui processi di nucleazione e di crescita e sono in accordo con una cinetica di primo ordine rispetto alla concentrazione di TEOS. Tuttavia, era importante capire meglio l'ambiente in cui la sintesi accade e mettere in luce l'evoluzione della specie solubile, sia dei componenti della microemulsione che di coloro che prendono parte alla reazione. Le specie solubili presenti nella miscela di reazione che porta alla produzione di nanoparticelle di silice attraverso l’idrolisi base-catalizzata di tetraetile ortosilicato (TEOS) e la successiva condensazione sono state studiate in situ, alle condizioni effettive di sintesi, mediante spettroscopia NMR di 1H, 13C, e 29Si. I primi due nuclei, a causa di una maggiore sensibilità e la loro presenza sia nel reagente che nei componenti della microemulsione a/o (cicloesano-Igepal CA520 (5 poliossietilene iso-octilfenil etere)-soluzione di ammoniaca concentrata) hanno offerto una visione della microemulsione inversa e ci hanno permesso di valutare la velocità di idrolisi. È stato verificato che la microstruttura della microemulsione è mantenuta durante la reazione. L’attenzione è stata rivolta particolarmente verso il mezzo di reazione, ed è stata effettuata un’assegnazione estesa delle 1H e 13C risonanze della testa del tensioattivo. Questi segnali della testa subiscono variazioni a causa delle modificazioni ambientali indotte dal passaggio dalla soluzione di cicloesano a microemulsione a/o e in seguito alla microemulsione a/o contenente NH3. Abbiamo seguito l'evoluzione quantitativa del TEOS e EtOH e valutato la loro distribuzione preferenziale nei vari ambienti forniti da questo mezzo di reazione, eterogeneo sulla mesoscala. Molti autori concordano sul fatto che il TEOS è localizzato principalmente in olio. Tuttavia, si dibatte se EtOH si trova preferenzialmente nelle goccioline d'acqua o nell’olio. Il chiarimento è stato realizzato per mezzo di PGSTE NMR in quanto i coefficienti di diffusione sono comunemente sfruttati per caratterizzare le microemulsioni, per determinare la connettività delle fasi e possono essere utilizzati per ottenere le dimensioni delle goccioline d’acqua. È stato rivelato che NH3 scambia tra le micelle inverse diffondendo attraverso il cicloesano ed è stato confermato che la localizzazione preferita per l'etanolo, il sottoprodotto della reazione, è l'olio. Inoltre, è stato confermato che il TEOS è localizzato principalmente nell’olio. La caratterizzazione delle nanoparticelle finali è stata effettuata per mezzo di microscopia elettronica a trasmissione (TEM) ed è stato rivelato che il prodotto finale sono le particelle monodisperse con raggio di 20 nm. La sintesi di nanoparticelle di SiO2 in un sistema con catalisi acida è particolarmente interessante dal punto di vista nanotecnologico, a causa della diversa natura fisica di silice sintetizzata in condizioni acide, piuttosto che in quelle basiche, e da un punto di vista applicativo in quanto le specie ospite previste non sempre sono resistenti alle basi. Purtroppo, l'applicazione di un processo sol-gel catalizzato da acido è meno chiara. Una microemulsione inversa sembra un mezzo di reazione ottimale in grado di limitare la crescita delle particelle di silice alle grandezze nanometriche. Tuttavia, relativamente pochi studi sono stati riportati fino ad oggi, e al meglio delle nostre conoscenze, solo uno riguarda l'intero processo condotto in una microemulsione inversa con un nucleo d’acqua che rimane stabile durante tutto il corso della reazione. La microemulsione inversa cicloesano-Igepal, stabilita per la sintesi di nanoparticelle di silice in processo sol-gel NH3-catalizzato, in alternativa è stata studiata con il processo sol-gel catalizzato da acido. Il TEOS è stato utilizzato come precursore di silice, mentre diverse fasi acquose contenenti HNO3 o HCl a due differenti concentrazioni, 0.1 o 0.05 M, sono state esaminate in presenza ed in assenza di NaF, un catalizzatore della fase di condensazione. L'evoluzione del sistema reagente complessivo, in particolare l’idrolisi e la policondensazione dei intermedi di reazione, è stata monitorata in situ mediante SAXS. Nessuna variazione delle dimensioni delle micelle inverse è stata rilevata durante tutto il processo sol-gel. Al contrario, è aumentata la densità dell’interno micellare dopo un certo intervallo di tempo, indicando la presenza del prodotto di policondensazione. Gli spettri IR della miscela di reazione erano d'accordo con tale ipotesi. Misure NMR 1H e 13C hanno fornito le informazioni sulle specie solubili.. Il consumo di TEOS era in accordo con un decadimento esponenziale, suggerendo una cinetica di primo ordine in TEOS, con costante di velocità dipendente non solo dalla concentrazione di acido, ma anche dalla natura (effetto anione specifico), dalla presenza di NaF, e dalla quantità di acqua nel nucleo della micella inversa. I coefficienti di auto-diffusione, determinati mediante PGSTE NMR, hanno dimostrato che una quantità considerevole del sottoprodotto etanolo è presente all'interno delle micelle inverse. Inoltre, lo spettro DOSY ha contribuito alla assegnazione dei segnali delle varie specie oligomeriche presenti nella miscela commerciale di Igepal CA520, poiché la testa, che è una breve catena di poliossietilene, è un po’ polidispersa. L’inserimento di Igepal CA520 in una microemulsione inversa contenente acido ha portato alla separazione di segnali 1H dei vari componenti oligomerici. Questo risulterebbe dal partizione differenziale tra l'olio e la superficie delle micelle inverse, che dipende dal numero di ossido di etilene (EON) della testa e il grado di partizione, tra i due ambienti, per ogni singola specie oligomerica, offrendo una visione più completa sulle microemulsioni inverse non ioniche. È stato possibile accertare che la distribuzione della lunghezza delle catene poliossietileniche è in buon accordo con la distribuzione di Poisson teoricamente prevista per la polimerizzazione di ossido di etilene. La caratterizzazione del prodotto finale è stata effettuata mediante analisi termogravimetrica (TGA), calorimetria differenziale a scansione (DSC), e TEM, che contemporaneamente hanno confermato che la silice isolata dalla microemulsione inversa non ionica non è significativamente diversa dal prodotto di sintesi sol-gel da catalisi acida in bulk. Le micrografie TEM hanno illustrato, oltre ad aggregati nanostrutturati nel range 20-100 nm, le particelle con diametro inferiore al diametro delle micelle inverse ,determinato da SAXS, a causa di un effetto di contrazione. I sistemi di silice dopati con metalli sono importanti per le applicazioni ottiche, e se gli ioni metallici sono finemente dispersi in matrice di silice possono essere ottenuti catalizzatori molto efficienti. La sintesi di nanoparticelle di silice in microemulsione inversa catalizzata da HCl è stata effettuata in presenza di entrambi ioni, Cu2+ e Co2+, con l'obiettivo di ottenere le nanoparticelle conseguentemente dopate. I sistemi sono stati caratterizzati mediante 1H e 13C NMR ed è stata seguita l'evoluzione quantitativa di TEOS e EtOH. L'introduzione dei metalli nella matrice vetrosa influenza fortemente il loro spettro di assorbimento ottico visibile per cui nello studio è stata applicata la spettroscopia UV-Vis. Le nanoparticelle isolate sono state caratterizzati mediante spettroscopia IR e Raman e la loro dimensione è stata determinata mediante TEM. È stato dimostrato che le micelle inverse possono essere utilizzate per produrre le nanoparticelle di SiO2 dopate di Co2+ e Cu2+ con diametro di circa 3 e 4 nm, rispettivamente. Sono state osservate le particelle sferiche più piccole rispetto alle dimensioni micellari e, nel caso del sistema dopato di Cu2+, aggregati più grandi di forma irregolare con diametro fino a 1 micron. Nei immagini TEM di alcune particelle più grandi e aggregati contenenti Cu sono state osservate molte zone più scure che possono essere assegnate alle particelle di metallo Cu incapsulato in matrice di silice. Pertanto, il cobalto è stato dopato con successo nelle nanoparticelle di silice, mentre il doping con il rame sembrava meno soddisfacente.
XXIII Ciclo
1983

[ES] Teniendo en cuenta el agotamiento de los combustibles fósiles y la creciente concentración de CO2 en la atmósfera, la hidrogenación de CO2 es una forma prometedora de convertir el CO2 en productos químicos y combustibles de carbono de alto valor añadido. Considerando la gran influencia del tamaño de partícula, la composición química, la naturaleza del soporte y las condiciones de operación sobre el comportamiento catalítico de los catalizadores, se han desarrollado una serie de catalizadores para la hidrogenación de CO2 basados en metales abundantes no nobles y polisacáridos naturales como precursores del grafeno. En la presente tesis doctoral, las especies metálicas soportadas sobre una matriz de carbono grafítico defectuosa, con diferentes tamaños de partículas, muestran diferente actividad catalítica y selectividad para la hidrogenación de CO2. Se prepararon, de forma controlada, nanopartículas de aleaciones de Co y Co-Fe soportadas en grafenos dopados con N defectuosos, con una amplia distribución de tamaño de nanopartículas, para la reacción de Sabatier, presentando una selectividad a metano superior al 90% con valores de conversión de CO2 superiores al 85%. En el caso de un solo metal, Co o Fe, y sus aleaciones en forma de "clusters" y pequeñas nanopartículas soportadas en el mismo material, la selectividad de la hidrogenación de CO2 cambia a CO, en lugar de metano, obteniéndose un valor del 98 % y alcanzando una conversión de CO2 del 56%. Conviene resaltar que, los catalizadores basados en "clusters" de aleaciones de metal con una carga de metal incluso por debajo del 0.2 % en peso, exhiben una mayor selectividad y rendimiento que los que tienen nanopartículas de aleaciones de Co-Fe más grandes que varían de 1 a 4 nm y una carga de metal más alta en una composición similar. Siguiendo la línea de investigación de hidrogenación de CO2, se desarrollaron una serie de nanopartículas de aleaciones de Co-Fe soportadas sobre grafenos dopados con N defectuosos con distribución de tamaño de nanopartículas controlada en el rango de 7-17 nm, obteniendo una selectividad hacia hidrocarburos C2+ alrededor del 45% y una conversión del CO2 cercana al 60%. Además, se realizó un estudio comparativo de la actividad catalítica de catalizadores similares basados en Co-Fe con promotores e inhibidores para la hidrogenación de CO2, observando su influencia en la conversión y selectividad de CO2. Finalmente, además de los catalizadores basados en Co-Fe, también se han preparado catalizadores basados en Cu-ZnO mediante un método de dos pasos. Estas nanopartículas de Cu-ZnO soportadas sobre grafeno defectuoso dopado con N exhiben una alta selectividad hacia la conversión de CO2 a metanol.
[CA] Tenint en compte l'esgotament dels combustibles fòssils i la creixent concentració de CO2 en l'atmosfera, la hidrogenació de CO2 és una forma prometedora de convertir el CO2 en productes químics i combustibles de carboni d'alt valor afegit. Considerant la gran influència de la grandària de partícula, la composició química, la naturalesa del suport i les condicions d'operació sobre el comportament catalític dels catalitzadors, s'han desenvolupat una sèrie de catalitzadors per a la hidrogenació de CO2 basats en metalls abundants no nobles i polisacàrids naturals com a precursors del grafé. En la present tesi doctoral, les espècies metàl·liques suportades sobre una matriu de carboni grafític defectuosa, amb diferents grandàries de partícules, mostren diferent activitat catalítica i selectivitat per a la hidrogenació de CO2. Es van preparar, de manera controlada, nanopartícules d'aliatges de Co i Co-Fe suportades en grafens dopats amb N defectuosos, amb una àmplia distribució de grandària de nanopartícules, per a la reacció de Sabatier, presentant una selectivitat a metà superior al 90% amb valors de conversió de CO2 superiors al 85%. En el cas d'un sol metall, Co o Fe, i els seus aliatges en forma de "clústers" i xicotetes nanopartícules suportades en el mateix material, la selectivitat de la hidrogenació de CO2 canvia a CO, en lloc de metà, obtenint-se un valor del 98% i aconseguint una conversió de CO2 del 56%. Convé ressaltar que, els catalitzadors basats en "clústers" d'aliatges de metall amb una càrrega de metall fins i tot per davall del 0.2% en pes, exhibeixen una major selectivitat i rendiment que els que tenen nanopartícules d'aliatges de Co-Fe més grans que varien d'1 a 4 nm i una càrrega de metall més alta en una composició similar. Seguint la línia d'investigació d'hidrogenació de CO2, es van desenvolupar una sèrie de nanopartícules d'aliatges de Co-Fe suportades sobre grafens dopats amb N defectuosos amb distribució de grandària de nanopartícules controlada en el rang de 7-17 nm, obtenint una selectivitat cap a hidrocarburs C2+ al voltant del 45% i una conversió del CO2 pròxima al 60%. A més, es va realitzar un estudi comparatiu de l'activitat catalítica de catalitzadors similars basats en Co-Fe amb promotors i inhibidors per a la hidrogenació de CO2, observant la seua influència en la conversió i selectivitat de CO2. Finalment, a més dels catalitzadors basats en Co-Fe, també s'han preparat catalitzadors basats en Cu-ZnO mitjançant un mètode de dos passos. Aquestes nanopartícules de Cu-ZnO suportades sobre grafé defectuós dopat amb N exhibeixen una alta selectivitat cap a la conversió de CO2 a metanol.
[EN] Considering the depletion of fossil fuels and the increasing atmospheric CO2 concentration, CO2 hydrogenation is a promising way to convert CO2 into value-added carbon-containing chemicals and fuels. Taking into account the significant influences of the particle size, chemical composition, nature of the support, and operation conditions on the catalytic performance of catalysts, a series of catalysts for CO2 hydrogenation have been developed based on the use of abundant non-noble metals and natural polysaccharides as graphene precursors. In the present PhD Thesis, metal species supported on defective graphitic carbon matrix with different particle sizes show different catalytic activity and selectivity for CO2 hydrogenation. Under effective control, Co and Co-Fe alloy nanoparticles wrapped on defective N-doped graphenes with a broad nanoparticle size distribution were prepared and performed for the Sabatier reaction, exhibiting a selectivity to methane over 90 % at CO2 conversion values over 85 %. In the case of single Co or Fe metal and their alloys in the form of clusters and small nanoparticles wrapped on the same support, the selectivity for CO2 hydrogenation shifts to CO, rather than methane, reaching a conversion of 56 % with 98 % CO selectivity. It is worth noting that the metal alloy clusters-based catalysts with the metal loading even below 0.2 wt.% exhibit a higher selectivity and better performance than the ones with larger Co-Fe alloy nanoparticles ranging from 1-4 nm and higher metal loading in a similar composition. Following the research line for CO2 hydrogenation, a series of Co-Fe alloy nanoparticles supported on defective N-doped graphenes with controlled nanoparticle size distribution in the range of 7-17 nm are developed, obtaining a selectivity towards C2+ hydrocarbons about 45% with a CO2 conversion close to 60%. In addition, a comparative catalytic activity of similar Co-Fe-based catalysts with promoters and poison has been studied for CO2 hydrogenation to observe their influence on CO2 conversion and selectivity. Finally, besides Co-Fe-based catalysts, Cu-ZnO-based catalysts have also been prepared by a two-step method. These Cu-ZnO nanoparticles supported on N-doped defective graphene exhibit a high selectivity for CO2 conversion to methanol.
Peng, L. (2021). Metal Nanoparticles Wrapped on Defective Nitrogen-doped Graphitic Carbons as Highly Selective Catalysts for C02 Hydrogenation [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/172329
TESIS

Engineered nanomaterials with tailored properties are highly required in a wide range of industrial fields. Consequently, the researches dedicated to the identification of new applications for existing materials and to the development of novel promising materials and cost effective, eco-friendly synthesis methods gained considerable attention in the last years. Cobalt ferrite is one of the nanomaterials with a wide application range due to its unique properties such as high electrical resistivity, negligible eddy current loss, moderate saturation magnetization, chemical and thermal stability, high Curie temperature and high mechanical hardness. Moreover, its structural, magnetic and electrical properties can be tailored by the selection of preparation route, chemical composition, dopant ions and thermal treatment. This chapter presents the recent applications of nanosized cobalt ferrites doped or co-doped with divalent transition ions such as Zn2+, Cu2+, Mn2+, Ni2+, Cd2+ obtained by various synthesis methods in ceramics, medicine, catalysis, electronics and communications.

Magnesium Oxide (MgO) nanoparticles have been synthesized by solution combustion technique using stoichiometric composition of magnesium nitrate as oxidizer and urea as fuel. Structure of the MgO was studied with the X-ray diffraction (XRD) using Cu-Kα radiation. MgO/polyvinylpyrrolidone (PVP) nanocomposites have been prepared by blending MgO nanoparticles with the polyvinylpyrrolidone. MgO/PVP nanocomposites were characterized by Fourier transform infrared (FTIR) spectroscopy. Frequency dependence of dielectric constant (ε′), dielectric loss tangent (tanδ) and AC conductivity studies have been undertaken on the MgO/PVP nanocomposites in the frequency range 50Hz-5MHz at room temperature. Dielectric properties such as dielectric constant (ε′) and dielectric loss tangent (tanδ) are found to decrease with the increase in the frequency. Further, AC conductivity of MgO/PVP nanocomposites was found to increase with an increase in the frequency. Observed variation in the a. c. conductivity with the frequency has been understood on the basis of electron hopping model.

In this chapter, results of our recent investigations on the structural, microstructural and magnetic properties of Cu-based Heusler alloys and MFe2O4 (M = Mn, Fe, Co, Ni, Cu, Zn) nanostructures will be discussed. The chapter is divided into two parts, the first part describes growth and different characterizations of Heusler alloys while in the second part magnetic properties of nano-ferrites are discussed. The Cu50Mn25Al25-xGax (x = 0, 2, 4, 8 and 10 at %) alloys have been synthesized in the form of ribbons. The alloys with x ≤ 8 show the formation of Heusler single phase of the Cu2MnAl structure. Further increase of Ga content gives rise to the formation of γ-Cu9Al4 type phase together with Cu2MnAl Heusler phase. The alloys are ferromagnetically ordered and the saturation magnetization (Ms) decreases slightly with increasing Ga concentration. Annealing of the ribbons significantly changes the magnetic properties of Cu50Mn25Al25-xGax alloys. The splitting in the zero field cooled (ZFC) and field cooled (FC) magnetization curves at low temperature has been observed for alloys. Another important class of material is Nanoferrites. The structural and magnetization behaviour of spinel MFe2O4 nanoferrites are quite different from that of bulk ferrites. X-ray diffraction study revealed spinel structure of MFe2O4 nanoparticles. The observed ferromagnetic behaviour of MFe2O4 depends on the nanostructural shape as well as ferrite inversion degree. The magnetic interactions in Ce doped CoFe2O4 are antiferromagnetic that was confirmed by zero field/field cooling measurements at 100 Oe. Log R (Ω) response measurement of MgFe2O4 thin film was taken for 10–90% relative humidity (% RH) change at 300 K.