Ultrasonic Irradiation Process Research Articles

Influence of micron-sized air bubbles on sonochemical reactions in aqueous solutions exposed to combined ultrasonic irradiation and aeration processes

Sonochemical reactors are promising for wastewater treatment applications. However, the combination of ultrasonic irradiation and aeration processes raises questions regarding the extent to which entrained air bubbles influence sonochemistry. In this study, the effect of micron-sized air bubbles (20 and 70 µm, 0.1–5.0 vol%) on sonochemical activity, based on KI dosimetry, was tested in a horn-type reactor (20 kHz). Bubbles were generated using the pressurization–depressurization method. The results showed that low bubble concentrations increased sonochemical yields but higher concentrations tended to decrease the yields. Compared with the bubble-free case, 20-μm bubbles enhanced sonochemistry at all concentrations, while 70-μm bubbles inhibited sonochemistry at the highest concentration (5.0 vol%). Two regimes, acoustic attenuation and nucleus introduction, were identified as inhibiting and enhancing sonochemical effects, respectively, and their dependence on bubble characteristics was examined. These results are significant as investigation into these regimes will allow a deeper understanding of the key factors controlling sonochemistry in the presence of micron-sized air bubbles and could be used to design sonoreactors equipped with aerators.

Emerging Solvent Regeneration Technologies for CO2 Capture through Offshore Natural Gas Purification Processes

It is estimated that 40% of natural gas reservoirs in the world are contaminated with acid gases (such as hydrogen sulfide and carbon dioxide), which hinder exploitation activities. The demand for natural gas will increase by 30% from 2020 to 2050, with the rise of industrial activities and the lifting of travel restrictions. The long-term production of these high acid-gas fields requires mitigation plans, which include carbon capture, utilization, and a storage process to reduce carbon emissions. Absorption is one the most established technologies for CO2 capture, yet it suffers from extensive energy regeneration and footprint requirements in offshore operations. Therefore, the aims of this paper are to review and analyze the recent developments in conventional and emerging solvent regeneration technologies, which include a conventional packed-bed column, membrane contactor, microwave heating, flash drum, rotating packed bed, and ultrasonic irradiation process. The conventional packed column and flash drum are less complex, with minimum maintenance requirements, but suffer from a large footprint. Even though the rotating packed-bed column and microwave heating demonstrate a higher solvent flexibility and process stability, both technologies require regular maintenance and high regeneration energy. Membrane contactor and ultrasonic irradiation absorption systems are compact, but restricted by various operational issues.

New sonochemical magnetite nanoparticles functionalization approach of dithiooxamide–formaldehyde developed cellulose: From easy synthesis to recyclable 4‐nitrophenol reduction

Magnetic [FA‐c‐(C‐DTX)@Fe3O4] nanocomposites have been prepared with a four‐step technique involving three mechanical stirring conventional steps to obtain [(FA‐c‐(DTX‐g‐DAC)] and an ultrasound‐assisted Fe3O4 coating approach to fabricate [FA‐c‐(C‐DTX)@Fe3O4]. Magnetic nanoparticles (NPs) (Fe3O4 NPs) synthesis and integration has been easily and rapidly approached under novel environmentally friendly optimized reaction conditions: an ethanol–water solution, one iron precursor use, short reaction time, low temperature, and an ultrasonic irradiation process. This new condition's unique combination is attributed to our new synthesis procedure. Sonochemically synthetisized [FA‐c‐(C‐DTX)@Fe3O4] were easily separated from the reaction mixture simply via external magnetic field application, and therefore, neither filtration nor centrifigation was required. The synthetisized samples have been investigated by Fourier transform infrared (FTIR) spectroscopy, nuclear magnetic resonance (NMR) spectroscopy, X‐ray photoelectron spectroscopy (XPS), X‐ray diffraction (XRD), thermogravimetry analysis (TGA), scanning electron microscopy (SEM), and vibrating‐sample magnetometry (VSM). Obtained outcomes including successful magnetite coating process, good crystallinity, homogenous morphology, enhanced thermal stability, and obvious magnetic properties suggested the potential of sonochemical procedure to fabricate and integrate magnetic NPs. This sonochemically synthesized catalyst was evaluated toward the reduction of the organic pollutant 4‐nitrophenol and showed excellent catalytic activity. This ultrasound‐assisted nanocomposites preparation is simply scalable to meet industrial application.

A comparative Study for Grey Water Using Ozonation and Ultrasonic Irradiation Processes.

Grey water is considered a type of wastewater which bring damage to human health and environmental if disposed improperly. This lead to research an efficient treatment method to reduce the damage. The methodology used for grey water treatment was ozonation and ultra sonication. PH, ozone dose, temperature and time were the factors effecting the overall performance of the treatment process for the two forms of grey water(car wash water and Domestic water). both the COD & oil content were measured to determine the effectiveness of the process. for carwash sample, the COD and oil content were 95%,96.5% at 0.52 mg/l ozone dose, at 55 min duration time and ph=9. As for the domestic water, the COD and oil content were 96.5%,96% at 0.52 mg/l ozone dose, at 55 min duration time and ph=9. The removal was lower for ultrasoniation.for carwash sample, the COD and oil content were 94% and 74% at 45Co, at 55 min duration time and ph=9. As for the domestic water, the COD and oil content were 97% and 96 % at 55 min duration time and ph=9.Finally, treatment of greywater with ozone has proven to be more efficient than ultrasound

Kinetic of the degradation of sulfanilic acid azochromotrop (SPADNS) by Fenton process coupled with ultrasonic irradiation or L-cysteine acceleration

Abstract The degradation kinetics of sulfanilic acid azochromotrop (SPADNS) in aqueous phase by Fenton process has been examined. The effect of pH, hydrogen peroxide [H2O2], ferrous ion [Fe2＋], molar ratio of [H2O2]/[Fe2＋] and SPADNS concentration [SPADNS] have been estimated systematically. The optimum reaction conditions were found to be pH = 3.5, [H2O2] = 1.7 × 10−3 M, [Fe2＋] =1.0 × 10−4 M for [SPADNS] = 1.0 × 10−4 M. Under these situations, 100% decolorization efficiency of aqueous SPAND solution was accomplished after 60 min of reaction. Also, the influence diverse inorganic anions (such as Cl − , NO 3 − , HCO 3 − , etc. present in contaminated water) on the degradation efficiency of Fenton oxidation were investigated. A combination of ultrasonic irradiation and Fenton process (US/Fenton) has been used to evaluate the effect of azo bond loading factor ( L azo bond ; 0.25 to 1) on SPANDS degradation kinetic rates. The results show that the oxidation of Fenton could be enhanced by ultrasonic irradiation. For example, the color removal for L azo bond 0.25, using Fenton and US-Fenton processes were 84.6% and 92.7% after an hour of oxidation reaction, respectively. While in the same period of time, there was no significant increment for TOC removal of chemical oxygen demand (COD) loading factor L COD 0.25, using Fenton and US-Fenton processes, which were 44.3% and 46.0%, respectively. This may be attributed to the formation of molecules with high stability against hydroxyl free radical. Also, this study found there was no significant effect on SPANDS degradation with the introduction of L-cysteine (Cys) to Fenton system. Three kinetic models (first-order, the second-order, and Behnajady–Modirshahla–Ghanbary) were evaluated and the Behnajady–Modirshahla–Ghanbary kinetic model was found to be the best model representing the experimental kinetic data of SPADNS.

Fabrication and characterization of novel polyester thin‐film nanocomposite membranes achieved by functionalized SiO2 nanoparticles for gas separation

In this article, a new type of soluble polyester/silica (PE/SiO2) hybrid was prepared by the ultrasonic irradiation process. Surface modification of SiO2 was conducted using coupling agent γ‐glycidyloxypropyltrimethoxysilane (GOTMS) under ultrasonic irradiation. The structures of the modified hybrid nanocomposites were identified with a Fourier‐transform infrared spectroscopy (FT‐IR), whereas the size of the SiO2 in PE was characterized with a scanning electron microscope (SEM). SEM results indicated the formation and dispersion of nanometer scale size of inorganic domains inside the PE matrix due to the introduction of modified SiO2 and the interactions between organic and inorganic phases. The size of SiO2 particles in the modified system was about 25 nm. The transmission electron microscope (TEM) analysis showing the well‐dispersed nanosized titania nanoparticles (NPs). The densities and solubilities of the PE/SiO2 hybrids were also measured. Furthermore, thermal stability, residual solvent in the membrane film, and structural ruination of membranes were analyzed by thermal gravimetric analysis (TGA). Moreover, their mechanical properties were also characterized. It can be observed that the Young's moduli (E) of the hybrid films increase linearly with the silica content. The results obtained from gas permeation experiments showed that adding SiO2 to the PE membrane structure increased the permeability of the membranes. POLYM. ENG. SCI., 59:E237–E247, 2019. © 2018 Society of Plastics Engineers

Efficient Synthesis of Five Types of Heterocyclic Compounds via Intramolecular Elimination Using Ultrasound-Static Heating Technique.

An experimental technique, ultrasound-static heating, has been developed for the efficient synthesis of heterocyclic compounds. The technique involves ultrasonic irradiation and static heating processes. First, the ultrasonic irradiation process is performed to form an intermediate of the heterocyclic compound under mild conditions and the subsequent static heating process (heating the intermediate under solvent-free conditions without stirring) produces the target heterocyclic compounds via intramolecular elimination.

Novel polyester/SiO2 nanocomposite membranes: Synthesis, properties and morphological studies

In this paper, a new type of soluble polyester/silica (PE/SiO2) hybrid was prepared by the ultrasonic irradiation process. The coupling agent γ-glycidyloxypropyltrimethoxysilane (GOTMS) was chosen to enhance the compatibility between the polyester (PE) and silica (SiO2). Furthermore, the effects of the coupling agent on the morphologies and properties of the PE/SiO2 hybrids were investigated using UV-vis and FT-IR spectroscopies and FE-SEM. The densities and solubilities of the PE/SiO2 hybrids were also measured. The results show that the size of the silica particle was markedly reduced by the introduction of the coupling agent, which made the PE/SiO2 hybrid films become transparent. Furthermore, thermal stability, residual solvent in the membrane film and structural ruination of membranes were analyzed by thermal gravimetric analysis (TGA). The effects of SiO2 nanoparticles on the glass transition temperature (Tg) of the prepared nanocomposites were studied by differential scanning calorimetry (DSC). Moreover, their mechanical properties were also characterized. It can be observed that the Young's moduli (E) of the hybrid films increase linearly with the silica content. The results obtained from gas permeation experiments with a constant pressure setup showed that adding SiO2 nanoparticles to the polymeric membrane structure increased the permeability of the membranes.

Citric Acid and Vitamin C as Coupling Agents for the Surface Coating of ZrO2 Nanoparticles and Their Behavior on the Optical, Mechanical, and Thermal Properties of Poly(vinyl alcohol) Nanocomposite Films

A series of bio-nanocomposites (BNC)s were fabricated through solution casting method. At first, the surfaces of ZrO2 NPs were functionalized with citric acid and Vitamin C as green modifier agents. Then, PVA as polymer matrix was embedded with different contents (4, 8 and 12 wt%) of modified ZrO2 (m-ZrO2) NPs with the aim of ultrasonic irradiation process. The resulting BNCs were studied by various techniques. Thermal stability of obtained BNCs was enhanced after NPs’ addition to the PVA matrix. Optical activity of these new BNCs makes them potential candidate for UV shielding material. Lastly, the tensile strengths of the BNCs were increased in comparison to the pure PVA.

Ultrasonik Ses Dalgası Ortamında Polielektrolit Varlığında Kalsiyum Karbonat Sentezi, Karakterizasyonu ve Deneysel Tasarım

In this study, calcium carbonate (CaCO 3 ) was synthesized by means of ultrasonic irradiation process in the presence of the water-soluble polyelectrolyte Poly(Vinyl Sulfonic Acid) (PVS). Synthesized CaCO 3 crystals were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), particle size and thermal analysis (TGA-DTA). The effects of the amplitude of sonicator, polymer concentration and the application time of ultrasound on the obtained CaCO 3 with respect to particle size of final product was investigated by applying the 2 k Factorial design. The experimental design was studied at two levels. All the selected process parameters were found to be very effective on the particle size of calcium carbonate obtained in the presence of PVS.

Synthesis and characterization of polyester bionanocomposite membrane with ultrasonic irradiation process for gas permeation and antibacterial activity

Optically active bionanocomposite membranes composed of polyester (PE) and cellulose/silica bionanocomposite (BNCs) prepared with simple, green and inexpensive ultrasonic irradiation process. It is a novel method to enhance the gas separation performance. The novel optically active diol containing functional trifluoromethyl groups was prepared in four steps reaction and it was fully characterized by different techniques. Commercially available silica nanoparticles were modified with biodegradable nanocellulose through ultrasonic irradiation technique. Transmission electron microscopy (TEM) analyses showed that the cellulose/silica composites were well dispersed in the polymer matrix on a nanometer scale. The mechanical properties nanocomposite films were improved by the addition of cellulose/silica. Thermo gravimetric analysis (TGA) data indicated an increase thermal stability of the PE/BNCs in compared to the pure polymer. The results obtained from gas permeation experiments showed that adding cellulose/silica to the PE membrane structure increased the permeability of the membranes. The increase in the permeability of the gases was as follows: PCH4 (38%) <PN2 (58%) <PCO2 (88%) <PO2 (98%) Adding silica nanoparticles into the PE matrix, improved the separation performance of carbon dioxide/methane and carbon dioxide/nitrogen gases. Increasing the cellulose/silica mass fraction in the membrane increased the diffusion coefficients of gases considered in the current study. Further, antimicrobial test against pathogenic bacteria was carried out.

Ultraviolet/ultrasound-activated persulfate for degradation of drug by zinc selenide quantum dots: Catalysis and microbiology study

In this study, wet chemical method used for ZnSe quantum dots (QDs) and characterized by, UV–vis, photoluminescence spectroscopy, X-ray diffraction and transmission electron microscopy. The crystallites size of ZnSe QDs was 4.0nm. The average diameters of ZnSe QDs were 3.0–5.3nm. Ritalin was degraded using the UV/ZnSe QDs/persulfate process. The several parameters investigated for the influence of Rtialin degradation were the temperature, the persulfate concentration, and the initial Ritalin concentration. The values of optimum parameters ware room temperature, concentration persulfate 5mmol/L and initial Ritalin concentration 0.09mmol/L. Comparative analyses showed the maximum degradation of Ritalin was found for ZnSe/persulfate under ultra-visible and ultra-sonic irradiation process. Comparative analysis showed the maximum degradation of Ritalin was found for ZnSe/persulfate under ultra-visible and ultra-sonic irradiation process. The values of first-order rate constants from degradation of Ritalin at 25°C were 0.96×10−2, 1.09×10−2, 1.59×10−2 and 2.19×10−2 for US/PS, UV/PS, ZnSe/US/PS and ZnSe/UV/PS system, respectively. The antibacterial activity evaluation against two bacterials, including Gram-positive bacteria Staphylococcus aureus (ATCC 43300), Bacillus megaterium (ATCC 14581) and Gram-negative bacteria Pseudomonas aeruginosa (ATCC 27853), Micrococcus luteus (ATCC 4698) was considered. It was found that the MIC values for the antibacterial assay in the presence of ZnSe QDs were around 0.30mM with 64.0, 66.0, 79.2, and 83.5% inhibition for the S. aureus, B. megaterium, P. aeruginosa and M. luteus bacterial strains, respectively. Then, results show that the ZnSe QDs have antibacterial activity.

Calcium silicate nanowires – An effective alternative for improving mechanical properties of chitosan-hydroxyethyl methacrylate (HEMA) copolymer nanocomposites

Nanowires of calcium silicate were successfully synthesized by ultrasonic irradiation process and incorporated into chitosan and hydroxyetheyl methacrylate (HEMA) copolymer matrix by solution blending for efficacious preparation of biodegradable nanocomposites. Remarkable improvement in mechanical properties of the nanocomposites was noticed after micro-tensile analysis. Enlarged surface area and higher aspect ratio of CaSiO3 nanowires were the key factors responsible for such improvement. This was supported by EDS and XRD analysis in terms of proper distribution of nanofiller through the copolymer matrix and corresponding rise in percentage crystallanity respectively. Contact angle and biodegradation studies further clarified that nano-CaSiO3 did not affect the hydrophilicity and general degradation route of chitosan copolymer respectively. This renders the nano-CaSiO3 as an ideal substitute for preparing high performance nanocomposites to be applicable for biomedical applications.

Medium-high frequency ultrasound and ozone based advanced oxidation for amoxicillin removal in water

In this study, treatment of an antibiotic compound amoxicillin by medium-high frequency ultrasonic irradiation and/or ozonation has been studied. Ultrasonic irradiation process was carried out in a batch reactor for aqueous amoxicillin solutions at three different frequencies (575, 861 and 1141kHz). The applied ultrasonic power was 75W and the diffused power was calculated as 14.6W/L. The highest removal was achieved at 575kHz ultrasonic frequency (>99%) with the highest pseudo first order reaction rate constant 0.04min−1 at pH 10 but the mineralization achieved was around 10%. Presence of alkalinity and humic acid species had negative effect on the removal efficiency (50% decrease). To improve the poor outcomes, ozonation had been applied with or without ultrasound. Ozone removed the amoxicillin at a rate 50 times faster than ultrasound. Moreover, due to the synergistic effect, coupling of ozone and ultrasound gave rise to rate constant of 2.5min−1 (625 times higher than ultrasound). In the processes where ozone was used, humic acid did not show any significant effect because the rate constant was so high that ozone has easily overcome the scavenging effects of natural water constituents. Furthermore, the intermediate compounds, after the incomplete oxidation mechanisms, has been analyzed to reveal the possible degradation pathways of amoxicillin through ultrasonic irradiation and ozonation applications. The outcomes of the intermediate compounds experiments and the toxicity was investigated to give a clear explanation about the safety of the resulting solution. The relevance of all the results concluded that hybrid advanced oxidation system was the best option for amoxicillin removal.

RETRACTED: Surface modification of TiO2 nanoparticles with biodegradable nanocellolose and synthesis of novel polyimide/cellulose/TiO2 membrane

In this paper, novel polyimide/cellulose/TiO2 bionanocomposites (PI/BNCs) were prepared via a simple and inexpensive ultrasonic irradiation process. PI was synthesized by direct polycondensation reaction of novel monomer dianhydride with 4-(2-(4-aminophenyl)-1,1,1,3,3,3-hexafluoropropan-2-yl)benzenamine. Due to the high surface energy and tendency for agglomeration the surface of nanoparticles was modified with cellulose. PI/BNCs containing 5, 10, and 15% of cellulose/TiO2 (BNCs) were successfully fabricated through ultrasonic irradiation technique. The obtained PI/BNCs were characterized by Fourier transform-infrared (FT-IR) spectroscopy, thermogravimetry analysis, X-ray powder diffraction, field emission-scanning electron microscopy (FE-SEM), and transmission electron microscopy (TEM). Thermogravimetric analysis data indicated an increase thermal stability of the PI/BNC polymers in compared to the pure polymer. From TEM image of PI/BNCs it can be found that the surface modified TiO2 with diametric size of less than 50nm, uniformly dispersed in the obtained PI matrix. The results obtained from gas permeation experiments with a constant pressure setup indicated that adding cellulose/TiO2 to the polymeric membrane structure increased the permeability of the membranes.

Role of surface modification of SiO2 with bio-safe citric acid on the morphological and thermal properties of nanocomposites based on N-trimellitylimido-l-methionine diacid and 4,4′-diaminodiphenyl ether: using ultrasound irradiation and ionic liquid

In this work, the surface of SiO2 NPs was modified with citric acid (CA) to prevent agglomeration of SiO2 nanoparticles (NP)s in the poly(amide-imide) (PAI) matrix. The PAI was synthesized from polymerization reaction of N-trimellitylimido-l-methionine with 4,4′-diaminodiphenyl ether using molten tetra-n-butylammonium bromide and triphenyl phosphite. PAI–SiO2/CA nanocomposites (PSCN)s were prepared via a fast ultrasonic irradiation process. The PSCNs were characterized by Fourier transform infrared spectroscopy, X-ray diffraction, field emission scanning electron microscopy, transmission electron microscopy and thermogravimetric analysis.

Chiral nanocomposites based on thermally stable poly(amide–imide) having S-valine groups and α-Fe2O3 nanoparticles

A novel chiral poly(amide–imide) (PAI) containing triptycene and S-valine moieties was prepared from the polycondensation reaction of N,N′-(pyromellitoyl)-bis-S-valine diacid chloride with bis(4-aminophenoxy)phenyl triptycene. The new PAI/α-Fe2O3 nanocomposites were prepared via ultrasonic irradiation process by dispersing silane coupling agent modified α-Fe2O3 nanoparticles in the polymer matrix. The resulting nanocomposites were characterized by Fourier transform infrared, powder X-ray diffraction, transmission electron microscopy (TEM), and thermogravimetric analysis (TGA). The TEM results indicated that the nanoparticles were dispersed homogeneously in PAI matrix on nanoscale. TGA confirmed that the thermal stability of the nanocomposite was improved in the presence of α-Fe2O3 nanoparticles.

Effective Immobilization of Nanostructured Materials Aiming Performant Electrochromic Electrodes

The layer-by-layer technique was presented as an interesting way to produce different architectures for electrochromic applications. The present work will show some of the newest insights into film formation by LbLtechnique. Nanotechnology has become the focus of research for many applications. In the field of electrochromism, nanomaterials have been widely studied providing physical and chemical properties to ensure short response times and fast charge compensation during the redox process leading to high performing electrochromic devices. Different syntheses of nanomaterials have been reported both to inorganic and organic materials. The preparation of inorganic nanoparticles such as nickel hydroxide, nickel oxide, Prussian blue, tungsten oxide and conducting polymers and viologens were reported and some examples of the use of these nanoparticles in electrochromic applications can be found. The development of reliable, low cost methodologies for the immobilization of nanomaterials is required. This work will discuss comparatively with LbLother interesting type of film formation: Electrophoretic Deposition (EPD), that can be achieved by the motion of charged particles towards an opposite charged surface due an external applied electric field, where parameters such as deposition time, distance between electrodes and applied potential can be easily controlled in order to obtain different morphologies and thicknesses. The films formation and performance of them will be compared. The electrostatic layer-by-layer deposition technique is limited due to the lack of electrical connectivity and low ionic diffusion between layers, leading to an irreversible behavior and longer response times, while an electrophoretic deposition technique opens new opportunities of studies in this area overcoming these problems. Thicker films with fast switching times and high durability and reproducibility were obtained. The comparison between LbL and EPD methodologies was done by studying the electrochromic response of doped nickel hydroxide nanoparticles immobilized onto ITO electrodes. The nanoparticles were synthesized by means of ultrasonic radiation reaching particles of 5 nm in diameter. The LbL electrodes were modified by intercalating PDDA between nanoparticle layers and the EPD was achieved by applying an electric field of 1.15 V cm-1 during different times. It was verified that all electrochromic parameters suffered a huge enhancement, in special the electrode durability was extremely high, the electrode was cycled continuously for over 20 hours keeping its contrast. The remarkable electrochromic properties of the EPD electrodes over LbLelectrodes were attributed to the absence of a non-conductive polymeric layer between the inorganic nanoparticle layers allied to the high roughness obtained by the EPD. Other nanostructures such as WO3 nanoplatelets and Au@Pedot nanoparticles were immobilized by using this promising method. WO3 nanoparticles with 50 nm average size were synthesized in non-aqueous solvent using an ultrasonic irradiation process, deposited by EPD process onto ITO substrates using acetonitrile as solvent. The protic ionic liquid N-methyl-pyrrolidinium tetrafluoroborate was chosen as electrolyte replacing traditional aqueous solvent. Coloration efficiency of films was 52 cm2/C in good agreement with other nanostructured WO3 films. The proton intercalation/desintercalation reaction was achieved satisfactory resulting in fast coloration/bleaching color changing. The results using PIL as electrolyte, instead of H2SO4, show that all electrochromic parameters were improved, including, the cyclic durability that was higher using PIL. Core-shell Au@PEDOT nanoparticles of about 2-8 nm were prepared by one-pot synthesis and immobilized by EPD onto ITO electrodes. The very low hysteresis viewed in the transmittance signal for the EPD modified electrode is related to the effective ionic diffusion through in/out the solid material and this fact can be also corroborated by the very low response time presented, in the order of 60 ms. The combination of nanoparticles, chomophore organic molecules, transition metal complexes and conducting polymers together with the simplicity of the LbL method for preparing electrodes with defined architectures controlled at nanoscale level, seem to be the novel direction in electrochromics. The LbL deposition is a low cost and easily handled technique where nanoparticles, organic molecules and polymers can be alternately deposited. Depending on their electrochromic behavior, many colorations can be achieved, without counter-electrode modification. The number of publications in this field is increasing sharply indicating that patents and commercial applications in large scale are becoming real in the not so far future. Superficially charged nanostructures can also be employed for electrophoretic deposition (EPD), which can be used alternatively to LBL when the electrical connection of nanomaterials is limited. On the hand, compact thicker films can be prepared easily with the concomitant increase of chromatic contrast. [i] Vidotti, M., Torresi, S.I.C. (2009) Electrostatic layer-by-layer and electrophoretic depositions as methods for electrochromic nanoparticle immobilization, Electrochimica Acta, 54, (10), 2800-2804.

Preparation of nanoporous silver micro-particles through ultrasonic-assisted dealloying of Mg-Ag alloy ribbons

Nanoporous silver (NPS) micro-particles were prepared successfully by combining high-intensity ultrasonic irradiation (UI) and chemical dealloying process of rapidly solidified Mg-Ag precursors. The length scale of the ligaments in NPS is 100±30 nm, which is insensitive to the concentration of the hydrochloric acid (HCl) solution and the intensity of the UI. However, smaller NPS micro-particles with a size of 50±20 μm can be obtained by dealloying the precursor ribbons in a much more concentrated HCl solution under UI. It is supposed that the cavitation phenomena induced by UI treatment may play a key role in disaggregating the precursor ribbons into the present NPS micro-particles during dealloying.

Preparation and characterization of optically active and flame-retardant poly(amide–imide)/SiO2 nanocomposites having N-trimellitylimido-l-methionine linkages using ultrasonic irradiation

In the present investigation, at first, 2,3,4,5-tetrabromo-6-[(4-hydroxyphenyl)carbamoyl] benzoic acid (TBHBA) was synthesized and characterized by Fourier transform infrared (FTIR). Silica nanoparticles (SiO2 NPs) were treated with TBHBA as coupling agent with ability of flame retardancy to introduce organic functional groups on the surface of SiO2 and improved the dispersion of NPs. Furthermore, novel optically active and flame-retardant poly(amide–imide)/SiO2 nanocomposites (PAI/SiO2 NCs) were successfully synthesized via a simple and inexpensive ultrasonic irradiation process. For this purpose at first, PAI was selected as a polymer matrix and was synthesized by direct polycondensation reaction of N-trimellitylimido-l-methionine with 4,4′-diaminodiphenylether in molten tetra-n-butyl ammonium bromide/triphenyl phosphite as a green condensing agent. The resulting PAI/SiO2 NCs were characterized by various techniques including FTIR, X-ray diffraction, and thermal gravimetric analysis (TGA), and their morphology were investigated by field-emission scanning electron microscopy (FE-SEM) and transmission electron microscopy (TEM) analysis. TEM and FE-SEM images showed that NPs were dispersed into the polymer matrix at nanoscale. TGA results showed that the addition of SiO2 NPs into the NCs enhanced the thermal stability of the samples compared to the pure PAI.