期刊,Journal of Alloys and Compounds 2022年890卷期_国家学术搜索

期刊信息/Journal information

Journal of Alloys and Compounds

Elsevier Science S.A.

主办单位：Elsevier Science S.A.

国际刊号：0925-8388

Journal of Alloys and Compounds/Journal Journal of Alloys and CompoundsSCIISTPEI

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Controllable synthesis of hexagonal WO3 nanorod-cluster films with high electrochromic performance in NIR range

Wang L.Liu Y.Han G.Zhao H....

8页

查看更多>>摘要：Hexagonal WO3 (h-WO3) nanorod-cluster films were controllably synthesized by a facile template-free hydrothermal technique. The pH value and the amount of urea in the precursor have critical influences on the crystal form and morphology of the WO3 film. The obtained uniform WO3 films feature a porous structure of clusters composed of h-WO3 nanorods with diameter of 6–10 nm and length of up to several hundred nanometers. Due to the novel microstructure and crystalline phase, the high electrochromic performance in NIR range with a high optical modulation of 46% in 1600 nm, fast switching speed (2.4 s for coloration and 3.6 s for bleaching), high coloration efficiency (106.1 cm2 C?1 in 1600 nm), and an excellent cycling stability (more than 96% charge capacity retained after 1000 cycles) was achieved.

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NSTL
Elsevier

Enhanced microwave absorption properties of biomass-derived carbon decorated with transition metal alloy at improved graphitization degree

Liu Y.Xu J.Li Y.Shang Y....

11页

查看更多>>摘要：In this work, absorbers with lightweight, low loading, and strong absorption capacity have been made by biomass-derived carbon (BC) with magnetic alloy. Because of an innovative synthetic method, not only the NiFe and CoFe alloy are successfully synthesized on the surface of the BC, but also the graphitization degree of the BC has been improved greatly by transition metals. This way makes the BC acquire superior dielectric, magnetic loss, better impedance matching, and excellent attenuation ability of electromagnetic waves. NiFe exhibits a higher catalytic performance, but the imbalance electromagnetic parameters lead to imperfect impedance matching. Due to the superior balance between attenuation ability and impedance matching, the BC/CoFe composite material shows excellent electromagnetic absorbing capacity. BC/CoFe has a minimum reflection loss of ?54.4 dB with a thickness of 2.2 mm, and the widest effective bandwidth can reach 2.6 GHz with a thickness of 2.4 mm. Results indicate that the BC/CoFe composite material is expected to be a superior electromagnetic wave absorber. These innovative findings and preparation methods provided a new guideline for developing biomass-derived carbon as a low-cost, lightweight, and high-performance microwave absorber.

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Elsevier

Investigation of mechanical properties and microstructural evolution in Cu─Al alloys with gradient structure

Nakatani M.Sharma B.Ameyama K.Fang J....

10页

查看更多>>摘要：Gradient structured (GS) materials have been reported to exhibit an outstanding mechanical properties. However, the influence of processing parameters on the GS specimens with different stacking fault energies (SFEs) and microstructural evolution during tensile are not very clear. In the present work, GS Cu─Al alloys with different SFEs of 28, 12 and 6 mJ/m2 were prepared by surface mechanical attrition treatment (SMAT) for different processing times. Results revealed that the SFE of 6 mJ/m2 specimen for SMAT 15 min exhibited a superior combination of strength and ductility, which had a significant hetero-deformation induced (HDI) stress originating from the accumulation of geometrically necessary dislocations (GNDs). Microstructure observations showed that deformation twins in the SFE of 6 mJ/m2 specimens formed in the gradient layer owing to its lower SFE. Moreover, in-situ electron backscatter diffraction (EBSD) revealed that the GNDs of the SFE of 6 mJ/m2 specimen initially formed at the grain boundaries with gradient grain size. Then, the formation of GNDs gradually migrated to the coarse grain region with increasing strain, which resulted in the HDI strain hardening and HDI stress strengthening. This work provide strategies to optimize properties and an understanding of deformation mechanisms in the GS materials during tensile test.

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NSTL
Elsevier

Room temperature NO2 sensing performance of Ag nanoparticles modified VO2 nanorods

Liang J.Wu W.Lou Q.Wang K....

10页

查看更多>>摘要：Ag-modified VO2 nanorods were prepared by a two-step method to improve the NO2 sensing performance at room temperature (25 °C). VO2 nanorods were synthesized by hydrothermal method, and Ag nanoparticles were decorated on the surface of VO2 nanorods by annealing. The effects of annealing temperature on the microstructure and room temperature NO2 sensing properties were studied. The morphology and crystal structure of the samples were characterized by field emission scanning electron microscope and X-ray diffraction. The results showed that Ag nanoparticles with a diameter of about 45 nm were tightly decorated on the surface of VO2 nanorods when the annealing temperature was 450 °C. The room temperature gas sensing measurement of sensor to NO2 with concentration spanned from 1 to 5 ppm was carried out. The gas sensing test results showed that the sample annealed at 450 °C had the maximum sensitivity, and the response value was up to 2.54–5 ppm NO2. The response value gradually decreases as the relative humidity increases. The sensor also showed good selectivity and reproducibility for detection of NO2 gas. The good sensing performance could be attributed to the catalytic effect of Ag nanoparticles and the changing of the energy band gap. At the same time, the mechanism of Ag-modified VO2 nanorods to NO2 gas response is further discussed. These results are significant to prompt the applications of VO2 in room temperature NO2 gas detection.

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Transport and thermoelectric properties of Nb-doped FeV0.64Hf0.16Ti0.2Sb half-Heusler alloys synthesized by two ball milling regimes

El-Khouly A.Serhiienko I.Chernyshova E.Ivanova A....

7页

查看更多>>摘要：This work presents experimental investigations of the thermoelectric properties of p-type FeV0.64?xNbxHf0.16Ti0.2Sb half-Heusler alloys. Samples of the concerned system were prepared through sequent procedures starting with arc melting. Fine powders of the concerned samples were then obtained by mechanical alloying using two different ball milling regimes. Spark plasma sintering technique was employed for pressing the powders. The thermoelectric properties were studied as functions of temperature from 300 K to 800 K. Alloy scattering of phonons showed great contribution in the reduction of lattice thermal conductivity. High energy ball milled FeV0.39Nb0.25Hf0.16Ti0.2Sb sample possessed the lowest lattice thermal conductivity with a value of 1.81 Wm?1 K?1 at room temperature with a reduction of –82% compared with that of FeVSb. Additionally, the electrical conductivity was improved by the Nb doping leading to notable increase in the material's power factor. As a result, a maximum power factor of 19.5 μW cm?1 K?2 was achieved at 800 K for Nb doped at x = 0.4 of the ball milled samples. The figure of merit was increased from 0.25 for FeV0.64Hf0.16Ti0.2Sb to 0.44 for FeV0.60Nb0.4Hf0.16Ti0.2Sb due to Nb doping. Which means that the figure of merit value is enhanced by –43%. The value was recorded at 725 K.

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A progressive strategy for harvesting mechanical energy using flexible PVDF-rGO-MoS2 nanocomposites film-based piezoelectric nanogenerator

Faraz M.Singh H.H.Khare N.

8页

查看更多>>摘要：Piezoelectric materials can make substantial contributions to resolve the overall energy crisis by providing a renewable energy solution. With the present increase in the number of microscale devices, piezoelectric power generation can provide an appropriate alternative to conventional power sources for low powered electronic devices. In this study, Flexible PVDF, PVDF-MoS2, and PVDF-rGO-MoS2 thin films were prepared by polymer solution casting method and their piezoelectric properties are explored. The structural and morphological characteristics of the synthesized materials and thin films were examined using XRD, FTIR, and PFM techniques. The fabricated flexible film is encapsulated with an insulating layer so that when we tap the device, the electrodes are not affected. The flexible thin film of PVDF-rGO-MoS2 has significantly improved generated voltage which is ~5 times higher than the flexible film of PVDF and ~2 times higher than PVDF-MoS2 flexible film. The mechanism involved in the improved piezoresponse of the flexible thin film was also proposed.

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NSTL
Elsevier

Effect of heat treatment on the microstructure and mechanical property of W/316L multi-material fabricated by selective laser melting

Zhou Y.Duan L.Li F.Chen K....

13页

查看更多>>摘要：W/316L multi-materials can realize the function of W as the plasma facing material and 316 L as the structural material in nuclear fusion reactors. In this study, well-bonded W/316L multi-material was firstly manufactured by selective laser melting (SLM) and the influence of heat treatment on the microstructure and mechanical property of W/316L was investigated. Results showed that the pores and cracks located at the bonding region could be reduced significantly by heat treatment at 1200 oC for 1 h. There was an obvious static recrystallization phenomenon of equiaxed sub-crystals among the bonding region and the existence of secondary Fe3W3C, Fe6W6C intermetallic compounds initiated from primary Fe2W and Fe7W6 matrix. In terms of mechanical properties, 22% increase in micro-hardness obtained at the W/316L bonding region, as well as an increase from 5.2% to 22.8% of the elongation after heat treatment was attributed to the precipitation of more secondary Fe3W3C, Fe6W6 phases, which introduced more nucleation sites and limited the slip of dislocations. This work provides a novel approach to fabricate and optimize W/316L multi-material.

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NSTL
Elsevier

N-type amorphous silicon-germanium thin films with embedded nanocrystals as a novel thermoelectric material of elevated ZT

Ascencio-Hurtado C.R.Torres A.Moreno M.Ambrosio R....

9页

查看更多>>摘要：The state-of-art thermoelectric (TE) materials with high efficiency (i.e., ZT ~ 1) at room temperature require meeting essential features, such as being environmentally friendly (i.e., avoiding the use of rare and toxic elements), cheap to produce, and high ZT. However, the enhancement of ZT has always been a challenge because the Seebeck coefficient, electrical conductivity, thermal conductivity, and absolute temperature are interdependent. In this work, we report the fabrication of amorphous silicon-germanium (a-SiGe) thin films deposited by low-frequency plasma-enhanced chemical vapor deposition (LF-PECVD) with embedded nanocrystals that have a ZT of 2.61 at room temperature. The above is achieved by enhancing the thermoelectric power factor and, simultaneously, keeping the lowest thermal conductivity; both are in concordance with the phonon-glass electron-crystal (PGEC) approach. The power factor enhancement is accomplished by increasing the electrical conductivity through N-type doping and an annealing process at 500 °C to which thin films were subjected to improve their transport properties while avoiding crystallization. Therefore, the room-temperature electrical conductivity increased two orders of magnitude from 1.11E-01 up to 42.79 S/cm. In addition, the growth of nanocrystals (5–15 nm) embedded into the amorphous matrix contribute to the transport of charge carriers. The measured thickness and Seebeck coefficient of thin films were 200 nm and ?1.038 mV/K, respectively. On the other side, the lowest thermal conductivity is reached because the material's amorphous phase is kept despite the applied post-deposition thermal annealing. The experimental value for thermal conductivity was 0.53 W/m·K, almost half of the minimum thermal conductivity proposed by Slack. In summary, the structural characterization (developed by X-ray diffraction, Fourier transform infrared spectroscopy, and Raman spectroscopy) shows that a-SiGe material not only has an amorphous phase despite the applied thermal annealing, but it also possesses nanocrystals, which is demonstrated by transmission electron microscopy in high-resolution mode. Therefore, the a-SiGe material obtained in this research is proposed as a novel and potential thermoelectric material because it has optimized TE properties and meets desirable features, such as being inexpensive, non-hazardous, and environmentally friendly for energy harvesting applications.

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Elsevier

Optical temperature sensing characteristics of Sm3+ doped YAG single crystal fiber based on luminescence emission

Zhou H.Wang L.-G.Ye L.Qiu J....

8页

查看更多>>摘要：A series of YAG: x mol%Sm3+ single crystal (SC) materials, in which x is 0.3, 0.5, 1, 2, respectively, have been synthesized through laser heated pedestal growth (LHPG) method. The down-conversion luminescence properties of prepared fluorescent materials were investigated under a 405 nm laser. According to the results, 0.5 mol% was selected as the optimal doping concentration, and the integrated YAG single crystal fiber (SCF) with end Sm3+ doped was further fabricated. Then the optical temperature sensing characteristics were studied by the technique of the fluorescence intensity ratio (FIR) in detail. It shows that 4F3/2 and 4G5/2 of Sm3+ ions are thermally coupled energy levels. The FIR of the 4F3/2/4G5/2 → 6H5/2 increases monotonously as temperature rises, and its temperature measurement range can be extended to 1178 K. The maximum absolute sensitivity and maximum relative sensitivity are 3.046 × 10?4 K?1(1129 K) and 5.033 × 10?3 K?1 (500 K), respectively. Additionally, the FIRs of various emission bands from 4G5/2 → 6H5/2, 7/2 and the FIR of the emission sub-bands from 4G5/2 → 6H9/2 exhibit temperature dependence in 303–1028 K and 303–878 K, respectively. These results indicate that YAG: Sm3+ SC is a very promising high-temperature sensing material.

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NSTL
Elsevier

Optimization of microstructure and magnetocaloric effect by heat treatment process in LaFe11.7Si1.3 microwire

Zhang R.Zhang X.Qian M.Bahl C.R.H....

8页

查看更多>>摘要：A large magnetocaloric effect and significantly shortened annealing process were obtained simultaneously in melt-extracted LaFe11.7Si1.3 microwires. Large amounts of La(Fe,Si)13 phases were formed within 5 min when annealed at 1353 K via a rapid peritectic reaction, because the nanoscale dendrites and a small amount of nanoscale La(Fe,Si)13 phases discovered inside grains could provide a lot of nucleation sites. Thereby, the main phase in LaFe11.7Si1.3 microwire after annealed at 1353 K for 5 min was La(Fe,Si)13 phase, although a small quantity of α-Fe and La-rich phases still remained in the microstructure. The annealed LaFe11.7Si1.3 microwires exhibited a first-order magnetic transition behavior and a large maximum magnetic entropy change of 7.7 J/kg K under a magnetic field of 1.4 T with negligible magnetic hysteresis. However, the strength of the first-order transition became weakened with the extension of annealing time. Finally, the working temperature range of LaFe11.7Si1.3 microwires was elevated to room temperature by hydrogenation, which expanded the application of LaFe11.7Si1.3 microwires in active magnetic regenerator.

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NSTL
Elsevier