METASTABLE STATE WITH HIGH ELECTRIC CONDUCTIVITY IN LiNaTaNbO SYNTHESIZED AT HIGH PRESSURE

Представлены результаты исследования сегнетоэлектрического твердого раствора LiNaTaNbO со структурой перовскита, основанного на ниобате натрия и синтезированного в условиях высокого давления и температуры. Методом импеданс спектроскопии в области температур 290 - 800 К были определены значения удельных проводимостей на постоянном токе, энергии активации носителей заряда и реальная часть диэлектрической проницаемости. Показана эволюция температурных аномалий удельной проводимости и диэлектрической проницаемости при термоциклировании. Обнаруженые эффекты связанны со структурными фазовыми переходами, определена температура Кюри. LiNaTaNbOпретерпевает фазовый переход второго рода. Установлено, что в LiNaTaNbO образуется метастабильная фаза, обладающая высокой электропроводностью в области комнатной температуры. При нагреве выше температуры Кюри данная фаза разрушается. Обсуждаются возможные механизмы обнаруженных явлений. The results are presented of a study of a ferroelectric solid solution LiNaTaNbO with a perovskite structure based on sodium niobate and synthesized under high pressure and temperature. In the temperature range of 290-800 K, the values of the specific conductivity at direct current, the activation energy of charge carriers, and the real part of the dielectric constant were determined by the method of impedance spectroscopy. Evolution of temperature anomalies of specific conductivity and dielectric constant during thermal cycling is shown. The observed effects are associated with structural phase transitions, and the Curie temperature is determined. The LiNaTaNbO undergoes a second-order phase transition. It was found that a metastable phase is formed in LiNaTaNbO, which has a high electrical conductivity at the room temperature. When heated above the Curie temperature, this phase is destroyed. Possible mechanisms of the discovered phenomena are discussed.

Printed copper-nanoplate conductor for electro-magnetic interference

As one of the conductive ink materials with high electric conductivity, elemental copper (Cu) based nanocrystals promise for printable electronics. Here, single crystalline Cu nanoplates were synthesized using a facile hydrothermal method. Size engineering of Cu nanoplates can be rationalized by using the LaMer model and the versatile Cu conductive ink materials are suitable for different printing technologies. The printed Cu traces show high electric conductivity of 6 MS/m, exhibiting electro-magnetic interference shielding efficiency value of 75 dB at an average thicknesses of 11 μm. Together with flexible alumina ceramic aerogel substrates, it kept 87% conductivity at the environmental temperature of 400 ℃, demonstrating the potential of Cu conductive ink for high-temperature printable electronics applications.

Gel Polymer Electrolyte Based on Methyl Methacrylate for Lithium-Sulfur Batteries

Lithium-sulfur batteries are next-generation battery systems with low cost and high specific energy. However, it is necessary to solve several deficiencies of these batteries such as shuttle effect, and gel polymer electrolyte is a great candidate. These perspective materials can be used as a replacement for liquid electrolytes, and at the same time, they can help to solve the problems of lithium-sulfur batteries. In this work, gel polymer electrolyte (GPE) based on methyl methacrylate was prepared by cross-linking strategy. As cross-link ethylene glycol dimethacrylate (EDMA) was used. Prepared gel with a high electric conductivity was testing in the lithium-sulfur cell (Li/GPE/S). The electrochemical performance of the cell was studied.

The Synergetic Effect Induced High Electrochemical Performance of CuO/Cu2O/Cu Nanocomposites as Lithium-Ion Battery Anodes

Due to the high theoretical capability, copper-based oxides were widely investigated. A facile water bath method was used to synthesis CuO nanowires and CuO/Cu2O/Cu nanocomposites. Owing to the synergetic effect, the CuO/Cu2O/Cu nanocomposites exhibit superior electrochemical performance compared to the CuO nanowires. The initial discharge and charge capacities are 2,660.4 mAh/g and 2,107.8 mAh/g, and the reversible capacity is 1,265.7 mAh/g after 200 cycles at 200 mA/g. Moreover, the reversible capacity is 1,180 mAh/g at 800 mA/g and 1,750 mAh/g when back to 100 mA/g, indicating the excellent rate capability. The CuO/Cu2O/Cu nanocomposites also exhibit relatively high electric conductivity and lithium-ion diffusion coefficient, especially after cycling. For the energy storage mechanism, the capacitive controlled mechanism is predominance at the high scan rates, which is consistent with the excellent rate capability. The outstanding electrochemical performance of the CuO/Cu2O/Cu nanocomposites indicates the potential application of copper-based oxides nanomaterials in future lithium-ion batteries.

Recent Advances in Graphene and Conductive Polymer Composites for Supercapacitor Electrodes: A Review

Supercapacitors (SCs) have generated a great deal of interest regarding their prospects for application in energy storage due to their advantages such as long life cycles and high-power density. Graphene is an excellent electrode material for SCs due to its high electric conductivity and highly specific surface area. Conductive polymers (CPs) could potentially become the next-generation SC electrodes because of their low cost, facile synthesis methods, and high pseudocapacitance. Graphene/CP composites show conspicuous electrochemical performance when used as electrode materials for SCs. In this article, we present and summarize the synthesis and electrochemical performance of graphene/CP composites for SCs. Additionally, the method for synthesizing electrode materials for better electrochemical performance is discussed.

Diatom Species That Characterize Saline Ponds (South of Spain) With The Description of A New Navicula Species

The south of the Iberian Peninsula has a high number of saline ponds where electric conductivity (EC) is an important factor that affects directly aquatic organisms, influencing their distribution and abundance. Environmental factors (such as pH, EC and temperature) were measured and diatom assemblages were sampled in 15 saline shallow ponds in the south of Spain along a range of electric conductivity (1.4 mS to 51.6 mS cm-1) between spring of 2004 to early summer of 2006. Three groups of ponds were defined based on conductivity (oligosaline 1.4 to 5.3 mScm-1, mesosaline 10.9 to 17.3 mScm-1 and euhaline 32.3 to 51.6 mScm-1) and diatom assemblages were studied. PERMANOVA analysis showed significant differences in diatom community composition between the three groups of ponds. Multidimensional scaling analysis (nMDS) showed distinct clusters of diatom assemblages in oligosaline and mesosaline ponds. Dominant diatom species in the eusaline ponds were Tryblionella pararostrata, Halamphora cf. petrusa, Halamphora sp.1 and Cocconeis euglypta; in the mesosaline ponds Navicula veneta, Nitzschia elegantula and Planothidium delicatulum were dominant taxa and the oligosaline ponds were dominated by Navicula veneta, Pseudostaurosira brevistriata and Nitzschia inconspicua. A new diatom species was described in ponds with high electric conductivity (32-56 mS cm-1) and named N. maiorpargemina.A detailed description of N. maiorpargemina sp. nov. is presented in this study based on light and scanning electron microscopy after comparison with morphologically and ecologically related taxa.

Si and SiGe Nanowire for Micro-Thermoelectric Generator: A Review of the Current State of the Art

In our environment, the large availability of wasted heat has motivated the search for methods to harvest heat. As a reliable way to supply energy, SiGe has been used for thermoelectric generators (TEGs) in space missions for decades. Recently, micro-thermoelectric generators (μTEG) have been shown to be a promising way to supply energy for the Internet of Things (IoT) by using daily waste heat. Combining the predominant CMOS compatibility with high electric conductivity and low thermal conductivity performance, Si nanowire and SiGe nanowire have been a candidate for μTEG. This review gives a comprehensive introduction of the Si, SiGe nanowires, and their possibility for μTEG. The basic thermoelectric principles, materials, structures, fabrication, measurements, and applications are discussed in depth.

Fe7Se8 encapsulated in N-doped carbon nanofibers as a stable anode material for sodium ion batteries

Transition metal chalcogenides especially Fe-based selenides for sodium storage have the advantages of high electric conductivity, low cost, abundant active sites, and high theoretical capacity.