Small Amount Of NiO Research Articles

The influence of CeO2 on the oxidation resistance of TaC/Ni composites

The in-situ TaC/Ni composites with different CeO2 content (0 wt%, 1 wt%, 2 wt%) were prepared by reactive sintering method, and their oxidation behavior in air at 1073 K was analyzed by static cyclic oxidation method to investigate the influence mechanism of CeO2 on the oxidation resistance of composites. The results show that the CeO2 particles are distributed around the TaC particles in the Ni matrix, and the oxidation behavior of composites with different CeO2 content conforms to the linear kinetic law. The oxide film is mainly composed of NiTa2O6 and a small amount of NiO. The generation reactions of Ta2O5 and NiTa2O6 induce a high expansion and compressive stress in oxide scale, leading to the formation of nonprotective oxide film with pores and cracks on the surface. As the addition of CeO2 increases from 0 wt% to 2 wt%, the thickness of oxide scale on composites obviously reduces from 505 μm to 122 μm, and the Ni and Ta oxides content decreases, leading to the reduction of pores and cracks in oxide scale. The Ce ion generated from the dissolution of CeO2 particles mainly distributes in the Ta oxides during the oxidation process, which hinders the outward diffusion of Ni and Ta ions, resulted in the improved oxidation resistance of TaC/Ni composites.

Anodized lamellar Ni-Ni3Si template for electrodeposition of micro-nanostructures

The lamellar Ni-Ni3Si template has the potential for various applications, such as magnetic arrays, layered magnetoelectric materials, electrode materials, and supercapacitors via electrodeposition. However, accurately electrodepositing other materials within the microchannels of the lamellar Ni-Ni3Si template remains a challenge. In this work, the lamellar Ni-Ni3Si template was anodized in 0.1 M oxalic acid (H2C2O4) to achieve accurate deposition of other materials within the microchannels of the lamellar Ni-Ni3Si template. After anodization, the non-anodized and anodized lamellar Ni-Ni3Si templates were subjected to various characterization techniques, including electrochemical impedance spectroscopy, Mott-Schottky analysis, X-ray diffraction and X-ray photoelectron spectroscopy. The study revealed that the optimal anodization potential is 1.2 VSCE, which generated a double-layer passivation film mainly comprised of Ni(OH)2 and SiO2, with a small amount of NiO and Ni2SiO4. Furthermore, cobalt was electrodeposited on non-anodized and anodized lamellar Ni-Ni3Si templates. The results showed that the passive film of the anodized lamellar Ni-Ni3Si template effectively inhibits cobalt nucleation on the surface and sidewalls of the β-Ni3Si sheets and facilitates cobalt deposition within the microchannels. This work provides a novel lamellar metallic template for the electrodeposition of micro-nanostructures.

High activity and stability of nano‐nickel catalyst based on LaNiO3 perovskite for methane bireforming

AbstractIn this study, a nano‐nickel Ni0 catalyst for bireforming of methane was in‐situ synthesized from the sol‐gel fabricating LaNiO3 perovskite. The various physico‐chemical methods such as powder X‐ray diffraction (XRD), energy‐dispersive X‐ray spectroscopy (EDS), H2 temperature‐programmed reduction (H2‐TPR), scanning electron microscopy (SEM), and CO2 temperature‐programmed desorption (CO2‐TPD) were used for characterization of the obtained samples. The coke accumulation was investigated via the temperature‐programmed oxidation (TPO) method. The results confirmed the formation of both LaNiO3 perovskite structure and a small amount of NiO with high crystallinity. H2‐TPR profiles and XRD patterns showed that the highly dispersed nanocrystals Ni0 on La2O3 catalysts were formed by in‐situ reduction of LaNiO3 at 800°C for as short as 1 hour or more. The crystal sizes of Ni0 and La2O3 crystals are in the range of 17‐18 nm and 18‐19 nm, respectively. The activity of the catalysts was studied in bireforming of methane by the micro‐flow method in a temperature range of 550‐800°C. LaNiO3‐based catalyst showed excellent performance for methane bireforming reaction. Of which, LaNiO3 sample calcined at 800°C for 1.5 hours and reduced at 800°C for 1.5 hours showed the highest activity when it reached the CH4 conversion of 87% and abnormally high CO2 conversion, reaching 97 % at 700°C and approximately 100 % at 800°C with an ideal H2/CO ratio of approximately 2. At 800°C, the activity of the most outstanding catalyst remained stable for 100 hrs thanks to the high sintering resistance of excellent dispersion of Ni in LaNiO3 lattice and high coke tolerance of the catalyst. The catalytic activity remained stable even when the amount of inert γ‐carbon reached 8.58 mgC/gcat.

B2-ordered NiAl content on microstructure, mechanical and oxidation properties of FeAl intermetallic compounds

B2-ordered FeAl based materials with 0, 10, 20, 30, 40, 50 and 60 wt.% B2-ordered NiAl reinforced phase were prepared by mechanical alloying with subsequent hot-pressing sintering. The microstructure, mechanical properties and oxidation resistance were investigated. The results showed that after adding NiAl, the main phase was composed of B2-ordered NiAl, B2-ordered FeAl phase, a small amount of AlFe3C0.5 and α-Al2O3. With the increase of NiAl content, the hardness and compressive strength of NiAl/FeAl composites first increased and then decreased. When the content of NiAl increased to 30 wt.%, the hardness and compressive strength of NiAl/FeAl composite reached the maximum value of 50.30 HRC and 2053.43 MPa, which was 35.2% and 40.8% higher than FeAl alloy. Besides, with the increase of NiAl content, the formation of dense oxide film on the surface was easier and faster, and the oxidation resistance was gradually improved. When the content of NiAl increased to 60 wt.%, the oxidation weight gain of NiAl/FeAl composite was 0.19 mg/cm2. Compared with FeAl alloy, the oxidation resistance of 60 wt.% NiAl/FeAl was increased by 81%, and the thickness of oxide layer was reduced from 1.527 μm to 0.253 μm. At this time, the oxide on the surface of the oxidized sample was mainly composed of α-Al2O3, α-Fe2O3 and a small amount of NiO.

Preparation of Ni/GO 0.2 -PAC 0.8 particle electrode and its degradation performance of Cu-EDTA complex

Cu-EDTA has strong stability in water and is hard to remove by conventional chemical precipitation methods. The particle electrode that was applied in the electrocatalytic degradation of Cu-EDTA was prepared by impregnation roasting method, using the powdered activated carbon (PAC) and graphene oxide (GO) as the carrier, and nickel as the catalyst. XRD and SEM-EDS were performed to characterize the composition and morphology of the electrode surface. The efficiency and mechanism of Cu-EDTA decomplexation and copper recovery were investigated. The results showed that the optimal conditions of the preparation of particle electrode were: the calcination temperature of 600 ℃, the calcination time of 4 h, and the mass ratio of PAC to GO of 8: 2. The nickel on the particle electrode existed mainly as Ni0, and a small amount of NiO. The decomplexation efficiencies of Cu-EDTA and total complexing copper (TCCu) were 99.6% and 99.4%, respectively. The recovery efficiency of total copper (TCu) was 93.7%. The decomplexation and copper recovery processes were in accordance with pseudo-first order reaction kinetical model. The results of free radical quenching and cyclic voltammetry scanning experiments showed that the decomplexation of Cu-EDTA was completed by electro-reduction. Cu2+ in Cu-EDTA was first reduced to Cu+, then reduced to Cu0 and deposited on the particle electrodes.

High-temperature corrosion of an Fe–Ni-based alloy HR6W under various conditions at 750 °C and 810 °C: Effect of the temperature, water vapor, simulated ash and SO2

The influences of temperature, SO2, water vapor and simulated ash on the high-temperature corrosion of an Fe–Ni-based alloy HR6W at 750 °C and 810 °C for 1000 h was systematically investigated. The weight gains and characterization of the corrosion products formed on the HR6W alloy in various environments were used to obtain the high-temperature corrosion behaviors of the alloy. The results show that weight gains of alloy HR6W under various gas conditions at 750 °C and 810 °C was much lower than that of the samples coated with salt, indicating that alloy HR6W exhibited excellent corrosion resistance due to a Cr2O3-rich scale. The SO2 promoted crackings of the Cr-rich oxide scales at 750 °C and 810 °C. After exposure to air containing water vapor and SO2, the corrosion products were mainly composed of an outer layer of Fe2O3, a small amount of NiO and an inner layer of Cr2O3. Sulfidation of alloy HR6W underneath the Cr-rich oxide scale was clearly observed on the samples exposed to SO2 and on all samples coated with salt. Additional NiO was found on the samples coated with salt exposed to air containing SO2. Alloy HR6W coated with salt exposed to air containing SO2 at 750 °C and 810 °C experienced the most severe corrosion among all samples herein due to the high causticity of the alkali-iron-tri-sulfates. The key elements affecting the high-temperature corrosion of alloy HR6W in the various gas environments were temperature > SO2>water vapor, in the order. Under the gas-molten salt conditions, the SO2 played the most important role in determining the corrosion rate. The key elements were SO2> temperature > water vapor, in that order.

Temperature-Dependent Isothermal Oxidation Behavior of a Ni-20Cr-18W Superalloy in Static Air

The oxidation behavior of superalloys has attracted more attention due to the increasing service temperature of components in aero-engines. In this study, the isothermal oxidation behavior of a Ni-20Cr-18W superalloy has been investigated at 900 and 1000 °C in air. The oxidation kinetics follows a parabolic oxidation law at both temperatures. The outer layer of the oxide scales is mainly composed of mixed oxides of Cr2O3 and NiCr2O4, and the inner layer is Cr2O3 at 900 °C. During oxidizing at 1000 °C, the oxide scales evolve from dense Cr2O3 single-layer structure to double-layer structure which consists of inner Cr2O3 layer and outer layer composed of lots of NiCr2O4, Cr2O3 and a small amount of NiO, and the size and content of NiCr2O4 are relatively larger than that of 900 °C. The internal oxidation zone dispersed with Al2O3 is formed under the oxide scales at both 900 and 1000 °C. The obvious cracks are observed at the interface between the outer layer and the inner layer, which is ascribed to the generation of growth stress and thermal stress. Compared with the oxidation behavior at 900 °C, the cracking and spalling in oxide scales are much severer at 1000 °C due to the greater internal stress. The experimental Ni-20Cr-18W superalloy is oxidized through the inward diffusion of oxygen and the outward diffusion of metal elements.

Hot corrosion behavior at 650 °C of Ni–Al composite coating prepared by electroplating nickel and embedded aluminizing technology

The hot corrosion performance of the Ni–Al composite coating prepared by electroplating nickel and powder embedding aluminizing technology in a mixed salt of Na2SO4:NaCl (3:1 and 3:2, mass ratio) at 650 °C was tested. The results show that the hot corrosion of the coating has an incubation period of 190 h and 96 h for the corrosive agent having 3:1 and 3:2, respectively. The increase of NaCl content in the corrosive agent can accelerate the corrosion process. Only oxidation occurs in the first 48 h of the hot corrosion of the coating, resulting in the formation of Al2O3 and a small amount of NiO on the surface of the coating. When the corrosion time ups to 504 h, the coating has different degrees of internal oxidation and internal sulfidation. The corrosion products include mainly NiO, Ni3S2, Fe2O3, Fe3O4 and Ni(Cr, Fe)2O4, in which Cr2S3 produced in the inner layer having a dark brown color is loose and peeled off in layers.

Cyclic oxidation behavior of Ni3Al-basedsuperalloy

Cyclic oxidation behavior of a polycrystalline Ni3Al-based superalloy under as-cast and solution treated conditions was investigated in detail. SEM equipped with energy dispersive X-ray spectrometer and high-resolution transmission electron microscopy was used for microstructure observation and mechanism analysis. Results showed that oxidation process occurred along eutectic area (γ-γ′) and dual phase area (γ+γ′)interfaces firstly for as-cast alloy and oxide scales along (γ-γ′)/(γ+γ′) interfaces spalled gradually with oxidation process proceeding. As for the solution treated alloy, though oxidation process also occurred along (γ-γ′)/(γ+γ′) interfaces, no obvious spalling of oxide scales was observed under the present conditions. Due to the precipitation of Hf-containing carbides which can increase the adhesion of scales and its segregation to Al2O3 grain boundaries during cyclic oxidation to hinder outward migration of Al, leading to slower growth rate of scales. During the long-time (8–200 h) cyclic oxidation process of the solution treated alloy, O atoms continuously diffused towards the matrix along the pores in scales, resulting in thickening of Al2O3 layer. Moreover, thickening of Al2O3 layer also hindered the outward diffusion of Ni and a small amount of NiO was observed on surface of specimen after long-term cyclic oxidation, meaning the improvement of oxidation resistance.

RWGS reaction employing Ni/Mg(Al,Ni)O − The role of the O vacancies

The performance of Ni supported on Mg(Al)O catalysts was evaluated in the RWGS reaction. The catalysts were characterized by TPR, EPR, TPSR, XRD, XPS, cyclohexane dehydrogenation reaction, atomic absorption and N2 physisorption. Two different catalytic systems were prepared by impregnation using water or ethanol as solvents of the Ni precursor. When ethanol was employed, Ni diffuses into the Mg(Al)O particles generating a homogeneous distribution of this metal through the catalyst particle leading to a Mg(Al,Ni)O solid solution, a very small amount of Nio and NiAl2O4. On the other hand, hydrotalcite is generated on the external layers of Mg(Al)O when water is the solvent. Nickel is trapped in the hydrotalcite structure. After calcination and reduction its concentration on the catalyst surface is higher than the one in the bulk. Both Mg(Al,Ni)O and Nio are observed on the catalyst surface. Oxygen vacancies were also observed for the two catalysts via EPR analyses due to the replacement of Mg by Al in the MgO lattice. The Mg(Al,Ni)O vacancies are active species for the reduction of CO2 to CO. These species and Nio are the catalytic sites of the RWGS reaction. Increasing the Nio concentration on the catalysts surface the activity of the catalysts increases as well. As far as we are concerned, this is the first time that Mg(Al)O or Mg(Al,Ni)O vacancies are associated with the performance of a catalytic system. This work exhibits that Ni/Mg(Al,Ni)O is a promising catalytic system for the RWGS reaction.

Isothermal oxidation of HVAF-sprayed Ni-based chromia, alumina and mixed-oxide scale forming coatings in ambient air

The power generation industry has been progressively shifting towards higher operating steam temperatures and pressures to increase efficiency and reduce CO2 emissions. However, higher operating temperatures lead to more aggressive oxidation of the boiler components. A promising route to improve the durability of degradation-prone components is through deployment of high-performance coatings. In the present work, four Ni-based coatings - Ni21Cr, Ni5Al, Ni21Cr9Mo, and Ni21Cr7Al1Y - thermally sprayed by the high-velocity air fuel (HVAF) technique on boiler steel (16Mo3) substrates were investigated. The isothermal oxidation behavior of the coatings was studied in ambient air environment at 600°C for different time intervals i.e. 1, 5, 10, 24, 48, 96, and 168h. The oxidation behavior of the as-sprayed and polished coatings was compared. The protective α-Al2O3 was not detected on the exposed alumina-forming NiAl coating. On the other hand, Cr2O3 along with a small amount of NiO were the main oxidation products on the surface of the NiCr and NiCrMo coatings, and were found to be relatively less protective. The mixed-oxide scale forming NiCrAlY coatings showed the best oxidation resistance due to the formation of a thin and slow-growing Al2O3 scale along with Ni(Al,Cr)2O4 and Cr2O3. The polished coatings were found to significantly reduce the oxidation rate in each case as the protective scale-forming elements were more uniformly supplied to the surface oxide scale by removing the surface asperities.

Electrochemical Synthesis of Ammonia Using Proton Conducting Solid Electrolyte and Ru-doped BaCe0.9Y0.1O3-δ Electrode Catalyst

The effect of ruthenium (Ru) addition to yttrium doped barium cerate (BaCe0.9Y0.1O3-δ) used as a cathode catalyst for electrochemical synthesis of ammonia in a double chamber reactor cell has been studied. The BaCe0.9Y0.1O3- δ (BCY) and BaCe0.8Y0.1Ru0.1O3- δ (BCYR) powders were synthesized by a co-precipitation method. The Ni-BCY and Ni-BCYR cermet were employed as a cathode and the Ni-BCY cermet was also used as an anode. As an electrolyte, the BCY pellet was synthesized by the sintering at 1300 ºC with small amount of NiO as a sintering aid. Electrochemical synthesis of ammonia from dry nitrogen and wet hydrogen was conducted at 500 ºC using each fabricated cell. The maximum production rate of ammonia was 5.30 × 10-10 mol s-1 cm-2 at applied voltage of –0.6 V vs open circuit voltage using the Ni-BCYR|BCY(NiO)|Ni-BCY cell, indicating the positive effect of Ru addition to BCY.

Polymer-derived mesoporous Ni/SiOC(H) ceramic nanocomposites for efficient removal of acid fuchsin

In this paper, magnetic porous Ni-modified SiOC(H) ceramic nanocomposites (Ni/SiOC(H)) were successfully prepared via a template-free polymer-derived ceramic route, which involves pyrolysis at 600°C of nickel-modified allylhydridopolycarbosilane (AHPCS-Ni) precursors synthesized by the reaction of allylhydridopolycarbosilane (AHPCS) with nickel(II)acetylacetonate (Ni(acac)2). The resultant Ni/SiOC(H) nanocomposites are comprised of in-situ formed nanoscaled Ni socialized with small amounts of NiO and nickel silicides embedded in the amorphous SiOC(H) matrix. The materials show ferromagnetic behavior and excellent magnetic properties with the saturation magnetization in the range of 1.71–7.08emug−1. Besides, the Ni/SiOC(H) nanocomposites are predominantly mesoporous with a high BET surface area and pore volume in the range of 253–344 and 0.134–0.185cm3g−1, respectively. The measured porosity features cause an excellent adsorption capacity towards a template dye acid fuchsin with the adsorption capacity Qt at 10min of 80.7–85.8mgg−1 and the Qe at equilibrium of 123.8–129.8mgg−1.

Electrochemical Synthesis of Ammonia Using Proton Conducting Solid Electrolyte and Ru-Doped BaCe0.8Y0.1Ru0.1O3- d Electrode Catalyst

Introduction Recently, the demands for the renewable energy such as water power, wind power, and solar power have increased around the world. These energy production is affected by the climate, and thus, stable power supply is difficult. In addition, the development of technologies of energy storage and transportation is important for effective utilization of the surplus power. Ammonia is a chemical material produced massively and is used in fertilizer and industrial process such as organic synthesis and nitrate acid. In the recent years, ammonia has been paid attention as an energy carrier substance because its hydrogen content and energy density are significantly high. The current process of ammonia production is a Haber-Bosch process. This process, however, requires the high pressure and temperature condition. Thus, a new synthesis process need to be developed. The electrochemical synthesis of ammonia as shown in Fig. 1 is considered to be an effective process of ammonia synthesis from N2 and H2O and/or H2. However, the formation rate of ammonia for the electrochemical synthesis has not been achieved at the demanded level; thus, there are needed to improve ammonia synthesis performance of electrode catalyst and ion conductivity of electrolyte. Therefore, in the present work, to improve the electrochemical synthesis process of ammonia, we have studied the effect of Ru-doping into yttrium-doped barium cerate as an electrode catalyst. Experimental The proton conducting BaCe0.9Y0.1O3- d (BCY) solid electrolyte was synthesized by a co-precipitation method. The BCY powder was mixed with a small amount of NiO as a sintering aid. The resultant powder was uniaxially pressed at 2 MPa into a pellet, followed by cold isostatic pressing at 200 MPa. The pellet was calcined at 1300 ºC for 12 h to obtain BCY pellet. The BaCe0.8Y0.1Ru0.1O3- d (BCYR) was also prepared by the co-precipitation method. The BCY and BCYR powders were mixed with isometric NiO powders by a planetary ball milling, followed by the calcination at 1200 ºC for 5 h. The NiO-BCYR slurry mixed with polyethylene glycol was pasted on one side of the BCY pellet as the cathode, and then, the sample pellet calcined at 1300 ºC for 5 h. After that, The NiO-BCY slurry mixed with polyethylene glycol was pasted on the other side of the pellet as the anode, followed by the calcination at 1300 ºC for 5 h. The powders and pellet were analyzed using X-ray diffraction (XRD), X-ray fluorescence (XRF) and transmission electron microscopy (TEM). Electrochemical synthesis of ammonia was conducted using the single cell fabricated at 500ºC. A gaseous mixture of N2 and Ar was fed into the working and a gaseous mixture of H2 and Ar was fed into the counter. Before the measurement, the Ni-BCY and Ni-BCYR electrodes were well reduced at 600 ºC for 2 h to activate the electrode. Results and discussion According to XRD analysis, both BCY and BCYR samples were assigned to perovskite-type oxides. In addition, Ru component is considered to be doped into BCY, evidenced from XRF and XRD analyses. As a result of electrolysis experiment, ammonia was synthesized electrochemically on the Ni-BCYR electrode. The maximum rate of ammonia formation was ca. 2.0 × 10-10 mol s-1 cm-2 at -600 mV of applied voltage. TEM images indicate that Ru particles existed on the Ni-BCYR surface after the reduction. Therefore, the reason of improvement is probably that the Ru particles on the electrode catalyzes N-N bond breaking. Faradaic efficiency of the ammonia formation was achieved ca. 3.0%, which means that proton on the cathode is mainly converted to hydrogen molecule. Conclusion Electrochemical synthesis of ammonia was carried out using proton conducting solid electrolyte from N2 and H2. Ammonia formation rate was improved by using Ni/BCYR electrode, because doping of Ru component enhances ammonia formation reaction at the cathode. The maximum rate of ammonia formation was ca. 2.0 × 10-10 mol s-1 cm-2 at 500 ºC. Acknowledgments This work was supported by CREST, Japan Science and Technology Agency. Reference [1] S. Giddey, S.P.S Badwal, A Kulkarni, Int. J. Hydrogen Energy 38 (2013) 14576-14594. [2] A. Skodra, M. Stoukides, Solid State Ionics 180 (2009) 1332-1336. [3] H. Iwahara, Solid State Ionics 77 (1995) 289-298. Figure 1

High methane combustion activity of PdO/CeO2–ZrO2–NiO/γ-Al2O3 catalysts

PdO/CeO2–ZrO2–NiO/γ-Al2O3 catalysts were prepared for the combustion of methane at moderate temperatures. The introduction of a small amount of NiO within the cubic fluorite CeO2–ZrO2 structure as a promoter effectively enhanced the oxygen release and storage abilities of the catalysts, thereby achieving the complete oxidation of methane. The catalyst with the highest activity for methane combustion was 11.3 mass% PdO/20 mass% Ce0.64Zr0.16Ni0.2O1.9/γ-Al2O3, and efficient combustion was realized at a temperature as low as 300 °C.

Use of Nano Seed Crystals To Control Peroxide Morphology in a Nonaqueous Li–O2 Battery

The high theoretical energy density of Li–O2 batteries as required for electrification of transport has pushed Li–O2 research to the forefront. The poor cyclability of this system due to incomplete Li2O2 oxidation is one of the major hurdles to be crossed if it is ever to deliver a high reversible energy density. Here we present the use of nano seed crystallites to control the size and morphology of the Li2O2 crystals. The evolution of the Li2O2 lattice parameters during operando X-ray diffraction demonstrates that the hexagonal NiO nanoparticles added to the activated carbon electrode act as seed crystals for equiaxed growth of Li2O2, which is confirmed by scanning electron microscopy energy-dispersive X-ray spectroscopy (SEM-EDX) elemental maps also showing preferential formation of Li2O2 on the NiO surface. Even small amounts of NiO (∼5 wt %) particles act as preferential sites for Li2O2 nucleation, effectively reducing the average size of the primary Li2O2 crystallites and promoting crystalline growth...

Controlled deposition and utilization of carbon on Ni-YSZ anodes of SOFCs operating on dry methane

Solid oxide fuel cells (SOFCs) are promising power-generation systems to utilize methane or methane-based fuels with a high energy efficiency and low environmental impact. A successive multi-stage process is performed to explore the operation of cells using dry methane or the deposited carbon from methane decomposition as fuel. Stable operation can be maintained by optimizing the fuel supply and current density parameters. An electrochemical impedance analysis suggests that the partial oxidization of Ni can occur at anodes when the carbon fuel is consumed. The stability of cells operated on pure methane is investigated in three operating modes. The cell can run in a comparatively stable state with continuous power output in an intermittent methane supply mode, where the deposition and utilization of carbon is controlled by balancing the fuel supply and consumption. The increase in the polarization resistance of the cell might originate from the small amount of NiO and residual carbon at the anode, which can be removed via an oxidation-and-reduction maintenance process. Based on the above strategy, this work provides an alternative operating mode to improve the stability of direct methane SOFCs and demonstrates the feasibility of its application.

Gas and liquid-fuelled HVOF spraying of Ni50Cr coating: Microstructure and high temperature oxidation

Ni50Cr thermally sprayed coatings are widely used for high temperature oxidation and corrosion in thermal power plants. In this study, a commercially available gas atomised Ni50Cr powder was sprayed onto a power plant alloy (ASME P92) using both gas and liquid fuelled high velocity oxy-fuel (HVOF) thermal spray. Microstructures of the two coatings were examined using SEM-EDX, XRD, oxygen content analysis and mercury intrusion porosimeter. The gas fuelled coating had higher levels of oxygen content and porosity. Shorter term air oxidation tests (4h) of the free-standing deposits in a thermogravimetric analyser (TGA) and longer term air oxidation tests (100h) of the coated substrates were performed at 700°C. The kinetics of oxidation and the oxidation products were characterized in detail in SEM/EDX and XRD. In both samples, oxides of various morphologies developed on top of the Ni50Cr coatings. Cr2O3 was the main oxidation product on the surface of the coatings along with a small amount of NiO and NiCr2O4. Rietveld analysis was performed on the XRD data to quantify the phase composition of the oxides on both Ni50Cr coatings and their evolution with exposure time.

Electrochemical performance of NiO-doped LiFePO4/C cathode materials prepared from amorphous FePO4 · xH2O

LiFePO4/C composites are prepared from amorphous FePO4 · xH2O and are modified with NiO (0.0, 0.01, 0.02, 0.03, and 0.04 mol) by using a solid-state reaction process with a spex milling system. The crystalline structure and the morphology of synthesized powders have been characterized by using X-ray diffraction (XRD) and scanning electron microscope (SEM). The XRD patterns indicate a complete solid solution for all the NiO-doped LiFePO4/C composites. The SEM images show that the sizes of the particles produced are distributed in the range of 200 − 300 nm. The electrochemical performances have been evaluated by using an impedance measurement and a galvanostatic charge/discharge test. The initial properties and impedance measurement reveal different improvements for different amounts of NiO doping in LiFePO4/C. A maximum capacity of 158.8 mAh/g at 0.1 C has been achieved LiFePO4/C doped with NiO at 0.01 mol. The present work reveals that the newly processed composite of LiFePO4/C doped with a small amount of NiO may be a promising material for using in a lithium-ion battery.

Oxidation behaviors of the TiNi/Ti2Ni matrix composite coatings with different contents of TaC addition fabricated on Ti6Al4V by laser cladding

The TiNi/Ti2Ni matrix composite coatings were fabricated on Ti6Al4V by laser cladding the mixtures of NiCrBSi and different contents of TaC (0 wt%, 5 wt%, 15 wt%, 30 wt% and 40 wt%). Scanning electron microscopy (SEM), energy dispersive spectrometry (EDS) and X-ray diffractometry (XRD) were used to examine the microstructures of the coatings. Oxidation behaviors of these coatings were also investigated at 800 °C for 50 h in air. The results showed that the coating without TaC addition was mainly composed of TiNi/Ti2Ni as the matrix and TiC/TiB2/TiB as the reinforcement. TaC was dissolved completely and precipitated again during laser cladding. Ta and C from the added TaC mainly existed as the solute atoms in the solid solutions of TiC, TiB2 and TiB in the coatings with TaC addition. The addition of TaC refined the microstructures of the coatings. In the oxidation test, the oxidation process was divided into the violent oxidation stage and the slow oxidation stage. The oxidation rates of the substrate and the coatings with different contents of TaC (0, 5, 15, 30, 40 wt%) were 0.644, 0.287, 0.173, 0.161, 0.223 and 0.072 mg cm−2 h−1 in the first stage, 0.884, 0.215, 0.136, 0.126, 0.108 and 0.040 mg2 cm−4 h−1 in the second stage, respectively. The weight gain of these samples were 6.70, 3.30, 2.86, 2.64, 2.41 and 1.69 mg cm−2, respectively after the whole oxidation test. The oxidation film formed on the surface of the coating without TaC addition mainly consisted of TiO2, Al2O3, and a small amount of NiO, Cr2O3 and SiO2. Moreover, Ta2O5 was also formed on the surfaces of these coatings with different contents of TaC. The oxides formed during the oxidation test were supposed to be responsible for the improvement in oxidation resistance of these coatings.