Saturated Aqueous Solution Research Articles

Preparation of cellulose microparticles having hierarchical internal structures from multiple emulsion templates

Microparticles having porous walls composed of nanofibers of cellulose were prepared from water-in-oil emulsion templates. This was achieved by emulsifying hot solutions of cellulose in a saturated aqueous solution of Ca(SCN)2 in decane in the presence of sorbitan monooleate as an emulsifier. Cooling the emulsion induced micro-phase separation within droplets of the cellulose solution, during which a three-dimensional network of cellulose nanofibers was formed and solidified the droplets. The particles size could be controlled by changing emulsification conditions such as stirring rate, the amount of emulsifier, and the volume ratio between the cellulose solution and decane. We found multiple emulsions (O/W/O and W/O/W/O emulsions) were formed when high amounts (>40 vol%) of the cellulose solution were emulsified. Particles obtained from the multiple emulsions had unique hierarchical internal structures, including a hollow particle with nanofibrous walls and particles-in-particle type structures where multiple porous particles are contained within a particle.

Dielectric Properties of Upside-Down SrTiO3/Li2MoO4 Composites Fabricated at Room Temperature

In this paper, ceramic upside-down lithium molybdate-strontium titanate (LMO-ST) composites fabricated at room temperature are described. Room temperature fabrication (RTF) is a promising alternative to the time- and energy-consuming high-temperature sintering of electroceramics, which involves mixing of the initial phases, molding with a steel dye, pressing, and drying, while in the last two phases the action of densification takes place. The LMO-ST composites are based on a high ratio of filler ST, coupled with the corresponding LMO binder. Part of the binder is admixed to the ceramic particles and additional part is added as a saturated aqueous solution, which crystallizes during pressing and drying, leading to its deposition on the surface of the filler particles. As a result, sufficient binding with 76–84% relative density was achieved. The deeper insight into the method was provided by various processing aspects and corresponding microstructural investigations. The particle size distribution, pressure, pressing time, ultrasonic treatment, drying time and processing conditions were optimized to obtain improved functional properties of the LMO-ST composites. The results of this study with relative permittivity in the range of 65–78 and dielectric loss tangent values of 0.002–0.05 can attract considerable attention for the use of LMO-ST composites in the industry of electroceramics.

Continuous Flow Process for the Synthesis of Betahistine via Aza-Michael-Type Reaction in Water

A continuous flow process for the preparation of betahistine with a 90% isolated yield has been reported. 2-Vinylpyridine and saturated methylamine hydrochloride aqueous solution were used as start...

Geochemical reactions-induced hydrogen loss during underground hydrogen storage in sandstone reservoirs

Underground hydrogen storage (UHS) appears to be an important means as a large-scale and long-term energy storage solution. A primary concern of UHS is the in-situ geochemical reactions-induced hydrogen loss. In this context, we performed geochemical modelling to examine the hydrogen loss associated with hydrogen dissolution and fluid-rock interactions using PHREEQC (Version 3) as a function of temperature and pressure. We also performed geochemical modelling with kinetics to investigate the potential hydrogen loss in two commercial gas storage reservoirs (Tubridgi and Mondarra) in Western Australia against the reservoir mineralogy, fluid properties, depth and temperature.Our results show that increasing pressure and temperature only slightly increases hydrogen solubility in brines without minerals. Increasing salinity slightly decreases the solubility of hydrogen in brines. The saturated hydrogen aqueous solution almost does not react with silicate and clay minerals, which is favorable for underground hydrogen storage in quartz-rich sandstone reservoirs. However, unlike silicate and clay minerals, carbonates like calcite triggers up to 9.5% hydrogen loss due to calcite dissolution induced hydrogen dissociation process. Kinetic simulations show that Tubridgi only leads to 0.72% of hydrogen loss, and Mondarra causes 2.76% of hydrogen loss as a result of reservoir calcite dissolution and hydrogen dissociation in brines in 30-year time. Nearly over 87% of calcite cement from Mondarra may be dissolved in 30-year, suggesting potential risks associated with wellbore stability. In conclusion, geochemical reactions-induced hydrogen loss would be minor for UHS in porous media, and we argue that deep calcite-free reservoirs together with calcite-free caprocks would be preferable for underground hydrogen storage.

Duality Between Coronavirus Transmission and Air-Based Macroscopic Molecular Communication.

This contribution exploits the duality between a viral infection process and macroscopic air-based molecular communication. Airborne aerosol and droplet transmission through human respiratory processes is modeled as an instance of a multiuser molecular communication scenario employing respiratory-event-driven molecular variable-concentration shift keying. Modeling is aided by experiments that are motivated by a macroscopic air-based molecular communication testbed. In artificially induced coughs, a saturated aqueous solution containing a fluorescent dye mixed with saliva is released by an adult test person. The emitted particles are made visible by means of optical detection exploiting the fluorescent dye. The number of particles recorded is significantly higher in test series without mouth and nose protection than in those with a well-fitting medical mask. A simulation tool for macroscopic molecular communication processes is extended and used for estimating the transmission of infectious aerosols in different environments. Towards this goal, parameters obtained through self experiments are taken. The work is inspired by the recent outbreak of the coronavirus pandemic.

Polymorphic Control of α and βdl‐Methionine through Swift Cooling Crystallization Process

AbstractPolymorphic control and crystal nucleation of α and β polymorphs of dl‐methionine, an essential amino‐acid, is attained from saturated aqueous solution through swift cooling crystallization process by generating wide range of supersaturation (0.02 < σ < 2.19) in the temperature range of 323–274 K. The type of nucleation is very much supersaturation dependent: while lower supersaturation range (0.02 < σ < 0.08) prefers the stable β form, higher supersaturation range (1.20 < σ < 2.19) yields metastable α form. In situ optical microscopy and X‐ray diffraction analyses confirm the morphological and structural distinction of the grown polymorphs.

Preparation and use of trans-2-hexenal microcapsules to preserve ‘Zaosu’ pears

Trans-2-hexenal is a naturally occurring volatile phytochemical with antimicrobial activity. It has not been widely used for the preservation of fruit and vegetables owing to its rapid volatilization. In this study, β-cyclodextrin-trans-2-hexenal microcapsules (β-CTHM) were prepared using the saturated aqueous solution method and their efficacy in preserving pears was evaluated. Results from scanning electron microscopy, thermogravimetric analysis, and Fourier-transform infrared spectroscopy indicated that β-CTHM was successfully prepared with an encapsulation efficiency of 67.52 %. The release of trans-2-hexenal from the microcapsules was dependent on the storage temperature. β-CTHM significantly inhibited the mycelial growth of Alternaria alternata in vitro. Furthermore, β-CTHM at 0.4 g/L fumigation treatment inhibited black rot of ‘Zaosu’ pears, maintained fruit firmness and titratable acidity, and reduced the respiration rate. Our present study suggested that β-CTHM might be used as an alternative to other preservative methods in retaining postharvest fruit quality.

Structure, rheology and possible application of water-in-oil emulsions stabilized by asphaltenes

Asphaltenes and resins remaining after heavy crude oil deasphalting (termed asphaltenes) require rational utilization. Due to their surface activity, such utilization can consist in obtaining and stabilizing water-in-oil emulsions. In this study, several series of emulsions were obtained using di(2-ethylhexyl) sebacate as a continuous phase and water or saturated aqueous solutions of various compounds (urea, NH4NO3, KH2PO4, CH3COONa) as a disperse phase. Asphaltenes were unlimitedly soluble in ester oil and could form dilute, semi-dilute, and concentrated solutions whose rheology was investigated. Even dilute solutions containing 3–5% of asphaltenes were suitable for obtaining stable emulsions without additional using usual surfactants. The rheology and morphology of emulsions containing from 3% to 15% of asphaltenes and from 15% to 85% of the disperse phase were investigated. The use of asphaltenes as surfactants causes agglomeration of water droplets, which leads to viscoelasticity and viscoplasticity of even dilute emulsions. Replacing pure water with saturated solutions of urea or inorganic salts resulted in the growth of both effective viscosity and yield stress of emulsions without radical changes in their rheology. Such emulsions can be potentially used as liquid fertilizers, explosives, or heat accumulators.

Thermodynamic characteristics of L-histidine polymorphs and effect of ethanol on the crystallization

L-Histidine(L-His) has two polymorphs of FormA and FormB. It is known that the crystallization of polymorphs is influenced by antisolvents. In this study, crystal morphology of polymorph was considered from prediction of crystal structures. Next, the effects of ethanol on polymorphs and morphology of L-His were studied by evaluating crystals obtained from saturated aqueous solutions by cooling or adding of ethanol. From the prediction of crystal structures, It is suggested that FormA crystal tend to grow in the long side direction. Experiments show that FormA tends to be obtained from aqueous solvent, on the other hands, FormB tends to be obtained from ethanol existing solution. However, FormB were found to dissolve gradually and transited to FormA. Furthermore, results show high concentration of ethanol change the morphology along its thickness direction, so it suggests that the effect of antisolvents has a big influence on crystallization. Moreover, the results of Thermogravimeter-Differential Thermal Analyzer (TG-DTA) and Differential Scanning Calorimetry (DSC) analysis demonstrate that FormB, which is thought as a metastable form, is possibly favorable in term of thermal stability and suggests the behavior of melting and decomposition of L-His.

Electrochemical performance of spherical LiCoO2 with high stability in neutral aqueous electrolyte

Layer-structured lithium cobalt oxide (LCO) is one of promising electrode materials for secondary aqueous lithium-ion batteries, yet the effect of structural proton insertion in LCO in neutral aqueous electrolytes cannot be ignored. Present study investigates the electrochemical performance of polycrystalline spherical LCO in neutral aqueous saturated Li2SO4 solution. Herein, we for the first time demonstrate the dependence of LCO stability on the discharge cutoff potential. The applied LCO electrodes show good cycling stability within the potential window of 0.65–1.1 V vs. SCE, while electrochemical impedance spectrum (EIS) analysis detects no sign of proton intercalation. Moreover, the spherical LCO free from the proton intercalation exhibits a superior rate capability with 78% discharge capacity retention at 80 C. The lithium-ion chemical diffusion coefficient being seven times than that of irregular shaped LCO sample can be responsible for such significant rate capability. The cyclability testing depicts the better performance of spherical LCO in comparison with the counterpart, especially in terms of electrode activation time. Post cycling electrode characterization displays that the discharge capacity fading of LCO mainly results from the crystal grain deformation due to high potential cycling and can be alleviated by reducing the depth of charge.

ДОСЛІДЖЕННЯ НАНОКРИСТАЛІТІВ, ОТРИМАНИХ НА ОСНОВІ НАНОПОРИСТИХ МЕМБРАН AL2O3 ІЗ НАСИЧЕНИХ ВОДНИХ РОЗЧИНІВ KH2PO4

Розглядається питання отримання та використання нанокомпозитних матеріалів для радіомереж оптичної та терагерцової смуг частот. Приготовлені нанопористі структури анодованого оксиду алюмінію Аl2О3 (АОА) діаметром пор 40 та 75 нм. Отримано та проведено дослідження кристалічного матеріалу KH2PO4 (KDP) у вигляді нанопроводів та нанотрубок при різних варіантах росту на основі мембрани Al2O3 і насиченого водного розчину KDP.

Lidocaine as eutectic forming drug for enhanced transdermal delivery of nonsteroidal anti-inflammatory drugs

Co-application of local anesthetics as lidocaine and nonsteroidal anti-inflammatory drugs (NSAIDs) can enhance local analgesia. Co-formulation of lidocaine with NSAIDs can modulate physicochemical properties like melting point which can affect transdermal delivery. The purpose was to probe lidocaine as eutectic forming drug for enhanced transdermal delivery of a series of NSAIDs with increasing melting points. NSAIDs included ketoprofen, flurbiprofen, aceclofenac, tenoxicam and meloxicam. Each drug was co-ground with lidocaine at increasing molar ratios. The products were characterized by thermal analysis and Fourier-transform infrared (FTIR). Saturated aqueous solutions containing excess of optimum NSAID/lidocaine were evaluated for transdermal delivery with reference to the corresponding saturated aqueous solution of each drug. Thermal analysis and FTIR suggested eutectic system formation. Drugs with lower melting points formed eutectic with smaller proportion of lidocaine. Ketoprofen, flurbiprofen and aceclofenac separated as oily liquid from the saturated aqueous solution of their mixtures with lidocaine. Eutectic mixtures of lidocaine with tenoxicam and meloxicam melted above 50 °C and separated from saturated aqueous solution as solid system. Eutexia increased the transdermal flux of NSAIDs. The extent of increase depended on the melting point of the developed system. The study introduced lidocaine as eutectic co-former for enhanced skin delivery of NSAIDs.

The pH of CO2–saturated aqueous KCl solutions at temperatures between 298 K and 423 K at pressures up to 13.5 MPa

The pH of CO2-saturated brines is of importance in geological carbon storage utilizing saline aquifers as it is a key variable controlling fluid-mineral chemical reactions that affect CO2 storage capacity and security. In this paper, we report experimental measurements of the pH of CO2-saturated aqueous KCl solutions carried out using high-pressure glass and ZrO2pH electrodes, coupled with a Ag/AgCl reference electrode, at a temperatures from (298 to 423 K) and at pressure between (0.2 and 13.5) MPa. The results are in good agreement with values predicted using the Pitzer model with the McInnes convention as implemented in the PHREEQC geochemical simulator software. The pH of CO2-saturated KCl solutions decreases with increasing partial pressure of CO2 and increases with increasing temperature. Increasing the molality of the KCl solutions tends to lower the pH but not as rapidly as is the case the NaCl.

Hydration, Ion Distribution, and Ionic Network Formation in Sulfonated Poly(arylene ether sulfones)

We use molecular dynamics simulations to probe hydration, ion spacing, and cation-anion interaction in two sulfonated polysulfones with different ion distributions along the polymer backbone. At room temperature, these polymers remain in a glassy state even with water contents more than 10%. At the equilibrium water uptake, the ions exhibit a similar level of hydration as they would in their saturated aqueous solution. The framework of Manning's limiting law for counterion condensation is used to examine ionic interactions in the simulated polysulfones. The dielectric constant that the ions experience can be well approximated by a volume-weighted average of the dielectric constants of the polymer backbone and water. Our results show that a reasonable estimate of the average inter-ion distance, b, is obtained by using the distance where the sulfonate-sulfonate coordination number reaches 1. The spacing of the sulfonate ions along the polysulfone backbone plays a role in determining their spatial distribution inside the hydrated polymer. As a result, the value of b is slightly larger for polymers where the sulfonate ions are more evenly spaced along the backbone, which is consistent with experimental evidence. The simulations reveal that the sulfonate ions and sodium counterions form fibrillar aggregates at water contents below the equilibrium water uptake. Such extensive ionic aggregates are expected to facilitate ion transport in sulfonated polysulfone membranes, without the need for long-range chain motion as in the case of traditional rubbery ionic polymers. Our estimates for the dielectric constant and b are used in conjunction with Manning's theory to estimate the fraction of counterions condensed to the fixed ions. The prediction of Manning's theory agrees well with the simulation result.

Suppression of self-induced thermal lensing in stimulated Raman scattering of liquids

Stimulated Raman scattering (SRS), due to the interaction of intense laser beams with Raman active media, provides an effective operational mode for frequency conversion, downgraded (primarily in liquids) by self-induced thermal lensing (TL). Here, a unique setup, including a pump laser beam [green (532 nm), 10 Hz, 5 ns] passing through a rotating cell, filled with a saturated aqueous solution of sodium nitrate ( N a N O 3 ) was tested, for conversion to a yellow (564 nm) beam. This distinct geometry allowed each pump pulse to pass through a “fresh” solution, practically eliminating TL. A sharp enhancement in SRS generation ( ∼ 20 % ) and observation of unexpanded beams’ cross sections at the cell exit verified TL removal. The results and the obtained physical insight from the N a N O 3 model system point to the promise of this approach for suppression of impeding TL in frequency conversion by SRS in liquids.

Controlled release of anticancer drug using o-phenylenediamine functionalized SBA-15 as a novel nanocarrier

In this study, a pH-sensitive drug delivery system was presented by o-phenylenediamine functionalized SBA-15 as a new carrier for controlled release of imatinib mesylate. O-phenylenediamine functionalized SBA-15 mesoporous silica was synthesized and characterized. Powder X-ray diffraction proved the 2D hexagonal mesostructure with p6mm space group for nanoporous materials. The o-phenylenediamine functionalized SBA-15 showed the BET surface area 265 m2g−1 and pore diameter 5.8 nm, based on adsorption–desorption of N2 at 77 oK. The presence of organic groups in the silica framework was demonstrated by FTIR spectrum. Then, the imatinib mesylate was loaded on o-phenylenediamine functionalized SBA-15 in saturated drug aqueous solution at ambient temperature for 1 h. According to the observations on drug release in phosphate buffers, the imatinib mesylate release from o-phenylenediamine functionalized SBA-15 shows a pH-associated behavior, and the rate of imatinib mesylate release was quicker at lower pH than higher pH. In addition, the imatinib mesylate had a slow release pattern in SBF with a constant rate of approximately 1.4 µg h−1 after the first hour. The results illustrated that o-phenylenediamine functionalized SBA-15 is a suitable option for being employed as a new carrier for controlled release of imatinib mesylate.

Ag Electrodeposition from Silver Solvate Ionic Liquid

Ag electrodeposition technics have been used in many fields, such as jewelry, tableware, lead frame of semiconductors, and aerospace materials. The practical Ag plating aqueous baths contain highly toxic cyanides to suppress dendritic growth. Toward the realization of green industry, cyanide-free alternative baths are needed. Ionic liquids (ILs) attract attention as green solvents with less volatility and less flammability and also as functional liquids which enable non-dendritic Ag electrodeposition without cyanides [1,2]. However, there have still been few studies on “silver solvate IL baths”, composed of Ag(I)-oligoether cationic complex and counter anion like other solvate ILs [3-5]. Silver solvate ILs are expected to offer an advantage in mass transport due to high Ag(I) concentration. In this study, we synthesized glyme-based silver solvate IL and investigated Ag electrodeposition.An equimolar mixture of glyme (G2, G3, G4, or G5) and silver bis(trifluoromethylsulfonyl)amide (AgTf2N) resulted in a liquid-state only for G5 at room temperature, which became a colorless and transparent liquid using activated carbon. Electrochemical properties of Ag(G5)Tf2N were examined using Pt plate as working electrode (WE) and Ag wires as reference electrode (RE) and counter electrode (CE). Cyclic voltammogram demonstrates distinct redox waves of Ag plating and stripping, evidencing that Ag(I)-G5 complexes are an electroactive species and this solvate IL can work as an Ag-plating bath. Reductive wave does not show a peak owing to diffusion limitation even though cathodic potential limit is extended up to –3.0 V vs. Ag. The cathodic current density reaches –7.0 mA cm–2 at –3.0 V. For the previously-reported Ag deposition from conventional ILs, poor solubility of salts caused the low current density of deposition. Thus, the large reductive current density from Ag(G5)Tf2N is quite advantageous.A galvanostatic electrodeposition at 0.08 mA cm–2 was performed to investigate the morphology of Ag deposits. Figs. 1c,d demonstrates that the obtained electrodeposits were quite dense and smooth. For comparison, we plated Ag from a diluted AgTf2N-G5 solution (Figs. 1e,f). Unlike the case of Ag(G5)Tf2N, the deposits were coarse and faceted. It is also notable that Tf2N ions have a certain leveling effect in Ag electrodeposition [6]. Therefore, the extremely high concentration of Ag(I) ion and Tf2N– ion is an important factor to form the dense and smooth Ag deposits. Suppose the high concentration is the only determinant, other electrolytes with a high AgTf2N concentration such as aqueous solutions could give dense and smooth Ag deposits. We prepared diluted and saturated AgTf2N aqueous solutions and conducted Ag electrodeposition. From the saturated aqueous solution, however, the shape of Ag has no difference, although from the diluted aqueous solution the morphology of Ag is quite similar to that from the diluted G5 solution. Consequently, not only a high AgTf2N concentration but also solvent is the factor for realizing highly smooth Ag deposits (e.g. difference of Ag(I)-solvent complex, physicochemical property of electrolyte, or electrode/electrolyte interface). This work offers a guideline to design Ag plating baths that have extremely high Ag(I) concentration and can electrodeposit dense and smooth Ag.[1] S. Z. E. Abedin et al., Electrochim. Acta, 54, 5673 (2009).[2] B. H. R. Suryanto et al., Electrochim. Acta, 81, 98 (2012).[3] T. Mandai et al., Chem. Rec, 19, 708 (2019).[4] A. Kitada et al., J. Electrochem. Soc., 165, H121 (2018).[5] A. Kitada et al., J. Electrochem. Soc., 164, H5119 (2017).[6] N. Serizawa et al., Electrochim. Acta, 56, 346 (2010). Figure 1

Screen-Printed Three Electrode-Type Sticker Device with Long-Term Stable Liquid Junction-Type Reference Electrode

A three electrode system is widely used to evaluate the corrosiveness of metal. However, three electrode system normally requires various instruments such as a salt bridge, reference electrode, counter electrode and flask. Thus, the three-electrode-type corrosion test is often applied to lab tests rather than field work. To solve the problem, in this study, we developed a new concept of a three electrode system using a sticker device that enables the simple and accurate measurement just only stick the device on a test metal.The three-electrode-type sticker device was fabricated by screen printing. Figure 1 (a) shows the model of the sticker device. A reference electrode with a liquid junction developed previously in our group1) used for the reference electrode part. A silver layer, a silver-silver chloride layer, a liquid junction layer, and a saturated KCl layer were also forms on the PET substrate by screen printing. A working electrode part of the sticker device has a 2 mm diameter hole. Electrochemical measurements can be performed by attaching this device to the measurement target. In this study, tin-plated copper and copper was used as a substrate.At the reference electrode of the sticker device, a solution is penetrated from the liquid junction layer, and the saturated KCl layer absorbs the solution to form a saturated KCl aqueous solution, and functions as a reference electrode.Figure 1 (b) shows the results of the open circuit potential measurement at the reference electrode of the sticker device. The open-circuit potential was stable at a solution concentration in the range of 10 ppm to 300 ppm after 60 seconds. Also, it was found that open-circuit potential was within ± 15 mV vs. SSE. It was confirmed that the potential after 300 seconds of immersion were almost constant in that each solution concentration, and that the device reference electrode had a stable with potential independent of the solution concentration.Figure 1 (c) shows polarization curve of the tin-plated copper measured using the sticker device. When the working electrode potential was scanned to the noble side, the current drastically increase due to the occurrence of pitting corrosion between -0.2 V and 0.1 V, depending on the solution concentration. The pitting potential was confirmed to have a positive correlation with the chloride ion concentration. Reference 1) M. Komoda, I. Shitanda, Y. Hoshi, and M. Itagaki, Electrochemistry, 87, 65 (2018). Figure 1

Electrochemical Properties and Cell Performance of Pd Core-Pt Shell Structured Catalyst Synthesized By Direct Displacement Reaction Method

1. Introduction Carbon supported Pd core-Pt shell structured catalyst (Pt/Pd/C) was synthesized by a simple direct displacement reaction (DDR) method in which Pd core was spontaneously displaced with a Pt precursor upon stirring in N2 saturated H2SO4 aqueous solution at 70°C [1]. Compared with our previous modified Cu-UPD/Pt displacement method [2], DDR method is a simple and suitable synthetic method for mass production of the catalyst. In DDR method, Pt shell was more uniformly formed and the Pt shell coverage was increased. In this study, oxygen reduction reaction (ORR) activity and durability of the catalyst were examined and single cell performance was evaluated. 2. Experimental Pt/Pd/C catalyst was synthesized by DDR method [1]. 600 mg of Pd/C core (particle size: 5.0 nm, metal loading: 46 wt.%, ISHIFUKU Metal Industry) was dispersed in 800 mL of water and pH was adjusted to 1 by 4 M H2SO4 at 5°C under N2 gas atmosphere. K2PtCl4 corresponding to Pt monolayer shell was added and stirred at 5°C for 0.5 h, followed by stirring at 70°C for 3 h. ORR activity of the catalyst was evaluated by RDE technique performed in O2 saturated 0.1 M HClO4 at 25°C with a positive scan rate of 10 mV/s at 1,600 rpm. Pt/Pd/C catalyst was activated by a high activation protocol HAP performed in Ar saturated 0.1 M HClO4 at 80°C [3]. Durability of the catalyst was evaluated by an accelerated durability test ADT (rectangular potential cycling of 0.6 V (3 s)-1.0 V (3 s) vs. RHE performed in Ar saturated 0.1 M HClO4 at 80°C for 10,000 cycles). A membrane electrode assembly (MEA) with active area of 1 cm2 was fabricated by using 25.4 µm thick NafionTM NR211. Pt loading in Pt/Pd/C cathode was 0.11 mg/cm2. I-V performance of the MEA was evaluated at 80°C with H2-Air feeding of 418 and 988 NmL/min., respectively. 3. Results and Discussion Nonuniform Pt shell formation observed in Pt/Pd/C catalyst synthesized by modified Cu-UPD/Pt displacement method was suppressed in Pt/Pd/C catalyst synthesized by DDR method as demonstrated in Fig. 1. CVs of Pd/C core and Pt/Pd/C catalysts are summarized in Fig. 2. Large hydrogen desorption wave observed on Pd/C core in a potential range of 0.05-0.1 V, which is a character of Pd, was decreased in Pt/Pd/C catalyst synthesized by Cu-UPD method, and the wave was further reduced in Pt/Pd/C catalyst synthesized by DDR method, indicating that Pt shell coverage was increased by DDR method. Since potential difference between Pd and Pt2+ in DDR method could be decreased compared with the difference between Cu and Pt2+ in Cu-UPD method, Pt shell was more slowly and uniformly formed and the coverage was increased in DDR method. Furthermore, number of fine catalyst particles decreased and mean diameter increased in the catalyst synthesized by DDR method, suggesting that fine Pd core particles were preferentially dissolved and re-deposited by Cl- anions released from Pt precursor of K2PtCl4.Change in ORR mass activity of Pt/Pd/C catalysts with HAP and ADT is summarized in Fig. 3. Initial ORR mass activity of Pt/Pd/C catalyst synthesized by DDR method exhibited 1,419 A/g-Pt, which was 3.3 times higher than that of Pt/Pd/C catalyst synthesized by Cu-UPD method. The activity was enhanced to 1,688 A/g-Pt by HAP, corresponding to 5.3-fold of a reference Pt/C catalyst (320 A/g-Pt, TEC10E50E, TKK). After ADT, ORR mass activity of the catalyst decreased to 917 A/g-Pt. Thus, the catalyst exhibited higher durability than the catalyst synthesized by Cu-UPD method (after ADT: 389 A/g-Pt). I-V performance of Pt/Pd/C catalyst synthesized by DDR method overcame the performance of a reference Pt/C catalyst (TEC10E50E, Pt loading: 0.10 mg/cm2, TKK) as demonstrated in Fig. 4. The Pt/Pd/C catalyst exhibited current density of 0.061 mA/cm2 at cell voltage of 0.85 V (IR free), which was 3.7-fold of the Pt/C catalyst. We think that Pt/Pd/C catalyst synthesized by DDR method is a promising candidate for achieving highly active and durable catalyst for ORR. Acknowledgement We thank to Mrs. Daimaru and Mikami for MEA evaluation. This study was supported by NEDO, Japan.

Mechanisms of Hydrogen Evolution in Weak Acid Solution Investigated By Using EIS

EIS was used in this mechanistic study of the electrochemical reaction mechanisms associated with corrosion of mild steel in the presence of weak acids, such as carbonic acid found in CO2 saturated aqueous solutions. Over the past decade, comprehensive mechanistic studies using DC electrochemical techniques have indicated that direct reduction of carbonic acid is not a significant reaction in CO2 aqueous solutions, contrary to what the conventional wisdom was for a long time. The new results suggest that the only cathodic reaction is hydrogen reduction, and that the main role of carbonic acid is to increase the limiting current by the so-called buffering effect. However, the problem is that the same limiting current is obtained theoretically whether one assumes that the direct reduction of carbonic acid or the buffering effect is true. Therefore, by using DC electrochemical techniques it is impossible to distinguish these two mechanisms in the limiting current region which is always seen in the polarization sweeps. An attempt has been made here to use the EIS technique to identify the role of carbonic acid in accelerating the cathodic reaction. Results indicate that the buffering effect is dominant, as recently proposed.