Low Temperature Densification Research Articles

Design of 0–3 type nanocomposites using hydrothermal sintering

We report here the successful design of 0–3 type nanocomposites where 30 nm ferromagnetic metallically conducting cores of manganite La0.66Sr0.34MnO3 (LSMO) are discretely distributed in an insulating silica matrix. Starting from LSMO@SiO2 core@shell nanoparticles, hydrothermal sintering process was used as a low temperature densification route (300 °C, 350 MPa, 90 min) in presence of 0.2 M aqueous sodium hydroxide solution. This process based on a pressure solution creep in the contact zones between nanoparticles allows the design of complex microstructures preventing the grain growth of the cores and the formation of interphases between the cores and the matrix.

Low-temperature densification, microstructures and mechanical properties of ZrB<sub>2</sub>–SiC composites with Cr<sub>3</sub>C<sub>2</sub> additives

Low-temperature densification, microstructures and mechanical properties of ZrB<sub>2</sub>–SiC composites with Cr<sub>3</sub>C<sub>2</sub> additives

Low-temperature densification of ceramics and cermets by the intermediary stage activated sintering method

The article explores new concepts in order to promote ceramic and cermet materials sintering at lower temperatures between 1200 and 1300 °C. The principle of the new process method called intermediary stage activated sintering (ISAS) involves the preparation of the ceramic powder with dispersed doping agents, such as nanotubes and fibers, which shape the pore structure at pressed pellets with stable interconnected thin cylinders between the grains. This feature resembles and extends the condition found during the intermediary stage sintering, which enhances the ions diffusion rate along tubular pores to increase shrinkage. Carbon nanotubes (CNT) and nanofibers are homogenized into cubic zirconia and alumina in amounts ranging from 1 to 10 vol% at high-energy milling devices and ultrasound disruptor under ethanol media. Ni, Cu and Mo/MoO3 can be also added to provide tubular channel filling. Sintering of uniaxially pressed pellets is carried out in a dilatometer and tubular furnaces at 1200/1300 °C under air, argon and controlled oxygen partial pressure atmospheres. TG/DTA/MS analyses of sample pellets reveal the oxidation and gas release temperature and duration. The results demonstrate the ISAS process concept is valid since it further increases the ceramic final density by 8% of the theoretical density at 1200 °C, leading to close the porosity at 1300 °C, compared to 1500–1600 °C temperatures at conventional process. Short CNT and cellulose nanofiber were found to be the best additives in this sense.

Densification of ZrB2–SiC nanocomposites prepared using ZrSi2, B4C, and C additives

Abstract

Low-temperature densification of Mg-doped hydroxyapatite fine powders under hydrothermal hot processing conditions

Abstract Densification of calcium hydroxyapatite fine powders doped with different concentrations of Mg (2, 4 and 6 mol% Mg, MgHA) was successfully achieved for the first time in a nearly fully dense state using the hydrothermal hot pressing (HHP) technique at low temperatures. Consolidation of MgHA powders was studied under different temperatures (150–240 °C), reaction times (1–6 h), and powder particle size (20 nm–1.5 µm). X-Ray diffraction analyses indicated that the particle densification under HHP conditions proceeded without any variation in the crystalline structure and regardless of the Mg content. The results from this work showed that an increase in temperature accelerates the reaction between MgHA particles and water (solvent) mixed during the hydrothermal treatment. Particle packing associated with bulk densification was achieved through a massive dissolution-recrystallisation mechanism, which induced the formation of small particles that rapidly crystallised on the surface of the partially dissolved original MgHA particles. The optimum conditions to obtain pellets with a high apparent density of 3.0758 ± 0.001 g/cm3 and tensile strength value of 12.6 ± 0.6 MPa were 10 wt% of water at a temperature of 240 °C with a 6 h reaction time and 6 mol% of Mg (MgHA3). The use of the HHP technique coupled with the fine particle size and reactivity of the MgHA precursor powders with water allowed us to produce disks that were compacted to a nearly full dense state with a low content of open porosity of 2.0%.

Low-temperature densification of Al-doped Li7La3Zr2O12: a reliable and controllable synthesis of fast-ion conducting garnets

A hybrid sol–gel solid-state procedure employing 3 h calcination at 1100 °C is used to produce fast-ion conducting Al-doped Li7La3Zr2O12.

Formation and Characterization of a Well-Packed Particulate Structure Consisted of Cu Nanoparticles By Capillary Force for Low Resistivity at Low Temperature

Cu nanoparticles (NPs) have been studied extensively to develop nano ink for printable electronics on flexible substrates because of its low cost, high conductivity and low sintering temperature. Although there are many synthesis methods with low resistivity which normally require high temperature, high pressure, toxic regent and special equipment, it was difficult to achieve the practical use of Cu NPs because the synthesis methods are expensive. We have developed a facile and green synthesis method of Cu NPs by using water, citric acid, ascorbic acid as solvent, complex/capping agent and reducing agent, respectively. The particle size of the citric acid modified Cu NPs can be controlled from 30 nm to 10 µm by varying pH and concentrations of Cu ion and ascorbic acid. For low resistivity, a high packing density of the Cu NPs is required to increase the interparticulate junction area before heat treatment because the well-packed particulate structure leads to a low temperature densification reaction of metal NPs. We have succeeded in increasing the interparticulate junction area by combining with the Cu NPs and the micro-sized particles (MPs). The bimodal size distribution leads to the high packing density because small particles are placed in voids of packing large particles. However, the resistivity of the Cu particles (32 µΩ・cm) after heat treatment at 200oC is far from that of bulk Cu (1.7 µΩ・cm) because the Cu MPs prevent low temperature sintering of the mixture. Therefore, a well-packed particulate structure consisted only of Cu NPs is require for low resistivity at low temperature. In this study, capillary forces generated from solvents evaporation were utilized to obtain the high packing density of the Cu NPs for low resistivity at low temperature because capillary forces have been applied to obtain closely packed various NPs. For characterizations of Cu films prepared from the Cu NPs, XRD, FT-IR, SEM and XPS measurement were carried out. Besides, the electrical resistivity of Cu films after heat treatment was measured. Since the citric acid modified Cu NPs can well disperse in alcohols and boiling points of alcohols are relatively low as compared other organic solvents, alcohols are suitable to form stable Cu ink and use capillary forces. Cu films were prepared from drop casting of the Cu alcohol ink and doctor blade process using Cu NPs paste consisted of the Cu NPs and α-terpineol as a traditional method. The weight of these Cu films is controlled to be approximately the same. After dry treatment of the Cu films, the thickness of the Cu film (8 µm) prepared from the Cu alcohol ink is much thinner than that (30 µm) of prepared from the Cu paste. The high packing density of the Cu NPs arises from capillary forces during alcohol evaporation. After heat treatment at 200oC under Ar+H2 (98%+2%), the resistivities of the Cu films obtained from the Cu ink and the Cu paste are 7 µΩ・cm and 80 µΩ・cm, respectively. It was found that the well-packed particulate structure consisted only of Cu NPs by capillary forces facilitates a densification by heat treatment, resulting in the low resistivity at low temperature. In our presentation, detailed results about the Cu films prepared from the Cu ink will be introduced. This work was supported by JSPS KAKENHI Grant-in-Aid for Young Scientists (B) 15K16155.

Reactive hot pressing of SiC-ZrC composites at low temperature

SiC-ZrC composites with relative density in excess of 99% were prepared by reactive hot pressing (RHP) of SiC and ZrH2 at 1800°C for 1h. The reaction between SiC and ZrH2 resulted in the formation of ZrC1-x. The formation process and densification behavior during RHP process were investigated. Low temperature densification of SiC-ZrC composites is attributed to the formed nonstoichiometric ZrC1-x and the removal of SiO2 impurity on the surface of SiC particles. As reinforced phase, ZrC1-x has inhibiting effect on the abnormal grain growth of SiC, resulting in homogeneous microstructure of fine SiC grains. Adding 10wt% ZrH2 to SiC, the formed SiC-4.62vol% ZrC composite exhibited better mechanical properties (Vickers hardness of 27.6±0.7GPa, flexure strength of 448±38MPa, fracture toughness of 6.0± 0.3MPa·m1/2, respectively) than monolithic SiC ceramic.

Low-temperature densification of nano Si-C powder containing Al-C additives prepared by high-energy ball-milling

This study investigates the low-temperature sintering of nano Si-C powder containing Al-C additives prepared by high-energy ball-milling. The synthesized powder was composed of ultra-fine β-SiC crystallites (~5nm) and amorphous Si-C matrix. TEM-EDS analysis showed a relatively homogeneous distribution of Al in the synthesized powder (d50: 170nm). The relative density of SiC containing 6.5wt% additives was 98.1% after sintering at 1650°C for 30min at a pressure of 20MPa. The SiC could be densified at 1800°C when the additive content decreased to 3.3wt%. The Al content in the Si-C powders changed, e.g., from 4.11 to 2.6wt%, after sintering at 1650°C, which value was much higher than the solubility limit (0.26wt% at 1800°C) due to the homogeneous distribution of Al within the powder and the low sintering temperature. Al was segregated at the grain boundary while liquid phase formation was not identified by TEM analysis, indicating that grain boundary diffusion was the main densification mechanism. The mechanical properties of the sintered specimens were similar to those of a SiC-Al4SiC4 system, which has the same chemical components but containing large amount of sintering additives (5.6 vs. 13wt%), sintered using higher pressure (20 vs. 60MPa) and temperature (1650 vs. 1800°C).

HoAlO3: A novel liquid aid for low temperature densification of SiC ceramics

In this communication, a novel liquid sintering aid consisting of Ho-Al-O elements was analyzed, using the complementary techniques of electron back-scattered diffraction (EBSD) and transmission electron microscopy (TEM). This liquid forming additive was demonstrated to be HoAlO3, showing an exact stoichiometric ratio; it had good wettability with the adjacent SiC grains.

Decoupling grain growth from densification during sintering of oxide nanoparticles

Unique shrinkage mode of oxide nanoparticles enables densification without grain growth.

On the Low Temperature Densification of Reactively Hot Pressed Non-Stoichiometric ZrC and (Zr,Ti)C

Reactive hot pressing (RHP) as a low temperature processing route is explored in the present work. For this purpose, metal-carbide mixtures, 1:1 molar ratio of zirconium (Zr): zirconium carbide (ZrC) and titanium (Ti): ZrC, are chosen, along with a temperature of 900°C and 50 MPa pressure. Further, pressureless reaction sintering (RS) is done at 1300-1600°C temperature. It has been found that after 1400°C RS, both the compositions reach almost full density. Ti, ZrC composition shows higher hardness (13 vs 11 GPa) than the Zr, ZrC composition. This process would allow dense products to be made by RHP more economically at lower temperature.

Low-temperature densification sintering and properties of CaAl2Si2O8 ceramics with MeO·2B2O3 (Me = Ca, Sr, Ba)

Dense CaAl2Si2O8 ceramics were prepared via a two-step sintering process at temperatures below 1000°C. First, pre-sintered CaAl2Si2O8 powders containing small amounts of other crystal phases were obtained by sintering a mixture of calcium hydroxide and kaolin powders at 950°C for 6 h. Subsequently, the combination of the pre-sintered ceramic powders with MeO·2B2O3 (Me = Ca, Sr, Ba) flux agents enabled the low-temperature densification sintering of the CaAl2Si2O8 ceramics at 950°C. The sintering behavior and phase formation of the CaAl2Si2O8 ceramics were investigated in terms of the addition of the three MeO·2B2O3 flux agents. Furthermore, alumina and quartz were introduced into the three flux agents to investigate the sintering behaviors, phase evolvements, microstructures, and physical properties of the resulting CaAl2Si2O8 ceramics. The results showed that, because of their low-melting characteristics, the MeO·2B2O3 (Me = Ca, Sr, Ba) flux agents facilitated the formation of the CaAl2Si2O8 ceramics with a dense microstructure via liquid-phase sintering. The addition of alumina and quartz to the flux agents also strongly affected the microstructures, phase formation, and physical properties of the CaAl2Si2O8 ceramics.

Effects of dual-layer coatings on microstructure and thermal conductivity of diamond/Cu composites prepared by vacuum hot pressing

Diamond/Cu composites with high density and good thermal properties are fabricated by vacuum hot pressing via designing dual layers on the diamond particles. Different types of inner tungsten layers are coated on diamond after annealing with the loose tungsten powder, and the outer copper layer is then deposited using electroless plating. The effects of dual layers on the microstructure and thermal conductivities of diamond/Cu composite are investigated. The results indicate that the tungsten coating exhibits integrated and uniform structure when the diamond is treated with tungsten powder at 900°C for 2h. This tungsten coating improves the interfacial bonding and minimizes the thermal boundary resistance between the diamond and the copper matrix. Moreover, the outside copper coating promotes the sintering process, and hence favors the low-temperature densification of diamond/Cu composites. The thermal conductivity of diamond/Cu composites reaches 721Wm−1K−1, which is close to the theoretical value.

Comparison of microstructure and chemical durability of Ce0.9Gd0.1PO4 ceramics prepared by hot-press and pressureless sintering

Gd-doped monazite-(Ce) ceramics (Ce0.9Gd0.1PO4) have been fabricated by hot-press sintering (HPS) and pressureless sintering (PLS). The influence of sintering temperature and holding time on the bulk density and microstructure was investigated. The results show all of HPS samples are denser than the PLS samples, even if the optimal PLS temperature is as high as 1400°C and the HPS temperature is only 1150°C. Low-temperature densification of the HPS ceramics should be attributed to particle rearrangement under pressure. In addition, chemical durability testing was carried out using the standard MCC-1 static leach test method. The results indicate that the normalized elemental leach rates of HPS samples are higher than those of PLS sintered specimens before 21 days, and remained almost unchanged (RL (Ce)≤6.0×10−6gm−2d−1, RL (Gd)≤1.8×10−5gm−2d−1) in both HPS and PLS ceramics after 28 days. The low-temperature HPS process to prepare monazite-based ceramic is a promising method for immobilizing trivalent minor actinide.

Low-temperature densification of Mg2SnO4 ceramics with LiF-Fe2O3-V2O5 additive

The effects of LiF-Fe2O3-V2O5 (LFV) additive on the sinterability, microstructure, phase composition, and microwave dielectric properties of Mg2SnO4 is investigated. By adding LFV additive, the densification temperature of Mg2SnO4 ceramics is significantly lowered from 1550°C to 1050°C. XRD shows all doped samples are single-phase Mg2SnO4 with Fd3m space group. TEM image and EDS spectra indicate that an amorphous phase is formed in the intergranular region, and Fe3+ ions presents in Mg2SnO4 matrix. Mg2SnO4 with 4wt.% LFV additive sintered at 1050°C provides the attractive combination of dense microstructure and excellent dielectric properties: εr=7.90, Q×f=41,400GHz and τf=−82ppm/°C. In addition, the ceramic is compatible with Ag/Pd electrodes, suggesting the potential application in millimeter-wave communication.

Low-temperature densification of diamond/Cu composite prepared from dual-layer coated diamond particles

High-density diamond/Cu composites with good thermal properties were fabricated by low-temperature hot-press sintering via designing dual layers on diamond. The microstructure observations indicate that a good interface bonding is obtained between diamond and copper. The inner tungsten coating on diamond is uniform and the formed carbides establish chemical and covalent interaction at the interface. The outside copper coating changes the sintering system of diamond–copper to copper–copper and thus favors the low-temperature densification of diamond/Cu composites. Finally, the sintered composites with dual-layer coated diamond have excellent thermal conductivity of 695 W m−1 K−1 compared with the single coating diamond composites of 386 W m−1 K−1.

Low Temperature Densification of ZnO-Based Ceramic Using Phenolic Resin as Binder

ZnO-based ceramic was densified at low temperature by using PSP as binder. The results showed that phenolic resin filled in the ZnO grain boundary layer. The sample has a well hardness of 0.8 GPa and bending strength of 78 MPa. The effect of temperature on the microstructure and mechanical properties was also investigated. It was found that the samples sintered at 300 °C showed higher density and better mechanical properties.

Improvement of strength of carbon nanotube-dispersed Si3N4 ceramics by bead milling and adding lower-temperature sintering aids

Studies on the dispersion of carbon nanotubes (CNTs) in silicon nitride (Si3N4) ceramics to provide the latter with electrical conductivity have been carried out in recent years. The density and the strength of Si3N4 ceramics were degraded, however, because the CNTs prevented Si3N4 from densifying. The CNTs disappeared after firing at high temperatures owing to the reaction between CNTs and Si3N4 or SiO2, or both Si3N4 and SiO2. In order to improve the density and suppress the reaction, sintering aids for lower-temperature densification of Si3N4 are needed. In this study, we added HfO2 as a sintering aid to a Si3N4–Y2O3–Al2O3–AlN–TiO2 system to fabricate CNT-dispersed Si3N4 ceramics at lower temperatures. Furthermore, bead milling was applied to disperse the CNTs homogeneously. Agglomerates of CNTs were pulverized by bead milling without obvious changes in morphology to eliminate larger fracture origins in CNT-dispersed ceramics. As a result of both the addition of HfO2 and bead milling, we successfully fabricated dense CNT-dispersed Si3N4 ceramics with high strength and electrical conductivity.

Ni–YSZ-supported tubular solid oxide fuel cells with GDC interlayer between YSZ electrolyte and LSCF cathode

Highly sinterable gadolinia doped ceria (GDC) powders are prepared by carbonate coprecipitation and applied to the GDC interlayer in Ni–YSZ (yttria stabilized zirconia)-supported tubular solid oxide fuel cell in order to prevent the reaction between YSZ electrolyte and LSCF (La0.6Sr0.4Co0.2Fe0.8O3−δ) cathode materials. The formation of highly resistive phase at the YSZ/LSCF interface was effectively blocked by the low-temperature densification of GDC interlayer using carbonate-derived active GDC powders and the suppression of Sr diffusion toward YSZ electrolyte via GDC interlayer by tuning the heat-treatment temperature for cathode fabrication. The power density of the cell with the configuration of Ni–YSZ/YSZ/GDC/LSCF–GDC/LSCF was as high as 906 mW cm−2, which was 2.0 times higher than that (455 mW cm−2) of the cell with the configuration of Ni–YSZ/YSZ/LSM(La0.8Sr0.2MnO3−δ)–YSZ/LSM at 750 °C.