Difference In Thermal Expansion Coefficients Research Articles

Effect of SiC whiskers on the anti‐oxidation properties of Yb2Si2O7/mullite/SiC tri‐layer environmental barrier coating for CMCs

AbstractThe mullite and ytterbium disilicate (β‐Yb2Si2O7) powders as starting materials for the Yb2Si2O7/mullite/SiC tri‐layer coating are synthesized by a sol–gel method. The effect of SiC whiskers on the anti‐oxidation properties of Yb2Si2O7/mullite/SiC tri‐layer coating for C/SiC composites in the air environment is deeply studied. Results show that the formation temperature and complete transition temperature of mullite were 800–1000 and 1300°C, respectively. Yb2SiO5, α‐Yb2Si2O7, and β‐Yb2Si2O7 were gradually formed between 800 and 1000°C, and Yb2SiO5 and α‐Yb2Si2O7 were completely transformed into β‐Yb2Si2O7 at a temperature above 1200°C. The weight loss of Yb2Si2O7/(SiCw–mullite)/SiC tri‐layer coating coated specimens was 0.15 × 10−3 g cm−2 after 200 h oxidation at 1400°C, which is lower than that of Yb2Si2O7/mullite/SiC tri‐layer coating (2.84 × 10−3 g cm−2). The SiC whiskers in mullite middle coating can not only alleviate the coefficient of thermal expansion difference between mullite middle coating and β‐Yb2Si2O7 outer coating, but also improve the self‐healing performance of the mullite middle coating owing to the self‐healing aluminosilicate glass phase formed by the reaction between SiO2 (oxidation of SiC whiskers) and mullite particles.

Effect of ball milling and solid solution treatment on the microstructure and interfacial behaviors of ZrMgMo3O12p/2024Al composites

ZrMgMo3O12 is a negative expansion material, while 2024Al alloy is a positive expansion material. The difference in thermal expansion coefficients between them will cause thermal mismatch stress at the interface in ZrMgMo3O12p/2024Al composites. Therefore, the interface behaviors of ZrMgMo3O12–Al determine the properties of ZrMgMo3O12p/2024Al composites to a great extent. The effects of ball milling and solid solution treatment on the microstructure and interface behaviors of 10 vol% ZrMgMo3O12p/2024Al composites were studied to improve the reticular microstructure of ZrMgMo3O12 distributed at the grain boundary of the α-Al matrix. The results showed that with increasing milling energy, the microstructure of the composites changed from reticular to equiaxed, and the distribution of ZrMgMo3O12 reinforcements in the matrix was more uniform. The content and size of the primary phase Al2Cu decreased with increasing solid solution treatment time. In addition, only ZrMgMo3O12–Al, Al2Cu–Al12Mo and Al–Al12Mo interfaces can be observed, but it is difficult to observe the interfaces of ZrMgMo3O12–Al12Mo in the composites milled for 12 h and solution treated for 24 h, which is related to the decomposition mechanism of ZrMgMo3O12. The decomposition mechanism is as follows: Al atoms from the α-Al matrix captured O atoms from ZrMgMo3O12 to form Al2O3. ZrMgMo3O12 simultaneously released Mo, Zr and Mg atoms. Mo atoms were enriched and nucleated in situ and precipitated with Al atoms to form the intermetallic compound Al12Mo, while Zr and Mg atoms entered the α-Al matrix to form a solid solution.

Investigation of thermal damage in continuous wave laser-induced nanowelding

Continuous wave (CW) laser-induced nanowelding holds great promise in micro-and nano-devices. However, because of the lengthy irradiation duration, the heat effect from CW laser irradiation may harm the manufactured devices. The simulation results show that an increase in irradiation duration will slightly improve the welding temperature but greatly expand the heat-affected area when the irradiation time exceeds 100 ms. Experimental results confirm that Cu nanowires irradiated for 20 ms are slightly oxidized. As the irradiation period is increased to 10,000 ms, the oxygen concentration in Cu nanowires significantly increases, and the color of Cu nanowires becomes first black, then green. The electrical property of the oxidized Cu-Au nanojunction shifts from ohmic contact to Schottky contact. Furthermore, the large heat-affected area will weaken the adhesion between the Au pad and the substrate due to the large difference in thermal expansion coefficient between the metal film and the insulating layer. Consequently, CW laser-induced thermal damage not only impairs the electrical properties of nanostructures but also their reliability.

Irradiation Effects on Stability of δ-UZr2 phase in U-50 wt% Zr Alloy

U-50wt%Zr is a candidate metallic nuclear fuel with potential application in light water reactors due to its excellent thermal properties and high radiation tolerance. The Zr-rich UZr fuels possess greater swelling resistance and fission gas release characteristics compared with U-rich UZr fuels. In this current study, the δ-phase U-50wt%Zr is proton irradiated at room temperature to 1 displacement per atom (dpa) to provide insights on phase stability under irradiation conditions. High resolution characterization of Transmission Electron Microscopy (TEM) and Atom Probe Tomography (APT) characterization techniques are used to elucidate microstructural changes due to irradiation. TEM and APT results show highly oriented bcc β-Zr-rich platelet precipitates nucleating adjacent to α-U phases inside the UZr2 matrix. Formation of this platelet morphology is characteristic of Widmänstatten structure which can be attributed to a variety of factors such as differences in thermal expansion coefficient between the phases, grain size, alloy composition, and cooling rate. The phases present are distinctly different than those observed through in situ annealing, but irradiation accelerates diffusion and phase separation kinetics. These microstructural changes in U-50wt%Zr are different from those achieved by pure thermodynamic or high temperature heavy ion irradiation experiments. Our work, together with previous ones, highlight the necessity to study the U-Zr phase diagram under non-equilibrium thermodynamics conditions to support this material's deployment as a viable nuclear fuel form.

Investigation and prediction of thermal cracking and permeability enhancement in ultra-low permeability rocks by in-situ thermal stimulation

Thermal cracking in rocks can cause a significant increase in permeability, which is of great significance for enhancing the oil recovery of ultra-low permeability reservoirs. To evaluate the potential for thermally-induced permeability enhancement in ultra-low permeability rocks, in-situ thermal stimulation (ITS) and pulse-decay gas permeability (PDP) real-time measurement of Chang 8 tight sandstone and Longmaxi shale cores were performed in a specially designed joint test system of the high-temperature pseudo-triaxial core holder and PDP real-time tester at different temperatures and simulated in-situ stresses. Stereo light microscope (SLM) observation and computerized tomography (CT) real-time scanning were applied to qualitatively and quantitatively characterize the dynamic variation in the thermal crack during the ITS, respectively. The experimental results show that above the threshold temperature of about 500 °C, thermal cracks were rapidly initiating, propagating, and forming a multi-scale fracture network in situ, thus leading to an improvement in permeability up to 11.23 and 29.82 times, respectively. By combining lithology and thermal analysis with reservoir physical property measurements in a multi-scale approach, the huge difference in thermal expansion coefficient (DTEC) between minerals caused by the quartz phase transition from α to β (QPT) at 573 °C is proved to be the most crucial mechanism for thermal cracking and permeability enhancement. To describe the intrinsic relationship between thermal crack and permeability with temperature-pressure during the ITS, a mathematical model based on thermoelasticity, fracture mechanics, and percolation theory was proposed. The QPT from α to β was further verified as the crucial mechanism by coupling the DTEC as a function of temperature into the mathematical model and obtaining better fitting results for experimentally measured permeability. Through experimental investigation and mathematical modeling, ITS is demonstrated as a less promising reservoir stimulation strategy for the economic and efficient development of tight oil and shale gas reservoirs.

Influence of the deposition process and substrate on microstructure, phase composition, and residual stress state on as-deposited Cr-Al-C coatings

This paper focuses on the influence of the High Power Pulsed Magnetron Sputtering (HPPMS) and Direct Current Magnetron Sputtering (DCMS) coating deposition processes, the bias voltage, deposition temperature, and substrate on various properties of the as-deposited state of Cr-Al-C thin films. Three substrates with different coefficients of thermal expansion and electrical conductivity were used. To investigate the microstructure, phase composition, residual stress state, and mechanical properties, ex-situ and in situ synchrotron experiments were conducted accompanied by electron microscopy and nanoindentation. As-deposited Cr-Al-C coatings consisted of amorphous and crystalline areas, with the ratio highly dependent on the deposition process and substrate. The crystalline phase was identified as metastable (Cr,Al)2C. The highest crystallinity was determined for DCMS coatings. Increasing temperature and decreasing bias voltage increased coating crystallinity for HPPMS coatings. The influence of the deposition process and bias voltage was highly reduced for the substrate with low electrical conductivity. In-situ investigations of the stress state of amorphous areas revealed, that those were acting as a residual stress buffer. The hardness and Young’s modulus of the coatings were found to increase with crystallinity and were slightly increased for crystalline HPPMS coatings compared to DCMS coatings.

Insights to the microwave effect in formation and performance promotion of iron-based carbon nanofibrous composites for H2S removal

Iron-based carbon nanofibrous composites were synthesized as high-temperature coal gas desulfurization sorbents by electrospinning, pre-oxidation and conventional/microwave carbonizations. Compared with conventional method, microwave carbonization effectively promoted the nucleation and growth of zero-valent iron (ZVI) among nanofibers, which in turn expedited the carbonization process of carbon matrix via the catalytic graphitization. Desulfurization performance evaluations showed that the sorbent carbonized by microwave at 700 °C possessed the highest breakthrough sulfur capacity (3.81 g S 100 g−1 sorbent), which might be attributed to the porous structure and rich content of iron species on the surface of nanofibers. The local high temperature induced by the interaction of microwaves and ZVI imparted the sorbent with porous microstructure. In addition, the rapid and high-temperature carbonization of microwave greatly enhanced the diffusion of Fe to the fiber surface due to the difference in thermal expansion coefficients of Fe and carbon. As a consequence, microwave carbonization involves the advantages of high energy efficiency and structural strengthening effect, suggesting its potential for the preparation of desulfurization sorbent.

Effect of biaxial strain on grain growth in nanocrystalline films: Coupling between grain-boundary energy and strain energy

A primary shortcoming of nanocrystalline materials is that they tend to coarsen at elevated temperatures, which limits their practical application. Nowadays, it is crucial to develop a non-alloying strategy to improve the thermal stability of nanocrystalline materials without changing their chemical composition. This work has demonstrated that varying the biaxial strain in nanocrystalline films can drastically change the grain-growth rate in nanocrystalline Ni films and even enable the tailoring of stable nanograin sizes in nanocrystalline Ni-Mo films. The biaxial strain can be adjusted, in this case, by introducing different thermal strains via using substrates with different coefficients of thermal expansion. Thus the thermal stability of nanocrystalline Ni and Ni-Mo films on Cu substrates is higher than that on W or Ni substrates. The underlying mechanism of this exceptional substrate-dependent thermal stability was revealed by performing thermodynamic model calculations, which provided insights into the effects of coupling between the grain-boundary energy and strain energy on the thermal stability of nanocrystalline films. In addition, the kinetic reasons for the different thermal stabilities of the Ni and Ni-Mo films were assessed, and the effect of the biaxial strain on the kinetic stabilizations was discussed. This work presents a strain-induced stabilization strategy for nanocrystalline materials, which is significant for enhancing the thermal stability of nanocrystalline materials without requiring alloying elements.

Effect of the B4C particles on the brazed joints of SiC ceramics and 2219 aluminum alloy

AbstractA two‐step process, including the premetallization of the SiC ceramic by Ag‐26.7Cu‐4Ti+B4C and the followed brazing with the Al‐based filler alloy, was developed to join 2219 aluminum alloy and the metallized SiC. The influence of metallization temperature and the B4C addition on the microstructure and mechanical properties of the joint was analyzed. The reaction products of Ti and B4C were detected in the brazing seam, such as Ti2B, TiC and graphite. With increasing of metallization temperature and B4C addition content, the shear strength of joint first increased and then decreased. The joint shear strength reached 14.0 MPa when SiC metallized with Ag‐26.7Cu‐4Ti+1%B4C at 930°C for 10 min, which showed that appropriate addition of B4C in Ag‐26.7Cu‐4Ti metallization layer could regulate the coefficient of thermal expansion difference between 2219 aluminum alloy and SiC to relieve the residual stress and improve the shear strength of their brazed joint.

Revealing the mechanism of laser welded aluminum alloy joints in-situ reinforced by carbon nanotubes based on microstructural evolution

In-situ addition of carbon nanotubes (CNTs) was innovatively applied to laser welding Al-Cu-Mg alloys to form composite joints, and the mechanism of CNTs strengthening joints was revealed from the viewpoint of microstructure evolution. Tensile test showed that the average tensile strength of the CNTs-reinforced joint increased by 37.3% to 306 MPa. Initially, microscopic observation and elemental analysis found that part of the CNTs were combined with the precipitate, and part of the CNTs were dispersed in the matrix, which provided conditions for the transfer of the load from the matrix to the CNTs. In addition, the fusion zone (FZ) grains of the joints in-situ strengthened by CNTs are finer and isotropic compared to the joints without CNTs. Since CNTs and aluminum alloys have remarkable differences in thermal expansion coefficients to form thermal mismatches, and part of CNTs may act as grain boundaries, resulting in dislocations cannot cut through them to form Orowan strengthening. As a result, CNTs-reinforced joints achieved significant improvements thanks to these primary strengthening mechanisms. The mechanism of CNTs-strengthened aluminum alloy joints is comprehensively and deeply revealed from the microscopic level, which provides a reference for the design of Al/CNTs composite joints and performance regulation.

Adhesion of nanodiamond composite films on Ti substrates at room temperature via hybrid ion etching gun and coaxial arc plasma deposition

It has been extremely difficult for nanodiamond composite (NDC) films to be deposited on Ti due to a large thermal expansion coefficient difference. The native oxide layer on Ti is another problem preventing the appropriate adhesion of NDC films and subsequent delamination. In this work, innovative room temperature adhesion of 3 μm NDC films with 54 GPa hardness on Ti substrates was accomplished via a hybrid system of ion etching gun and coaxial arc plasma deposition (CAPD). Ar+ plasma etching is capable to terminate the superficial TiO2 layer and manipulates substrate morphology during CAPD provides instantaneous deposition of NDC films at room temperature.

Design, preparation, and performance characterization of low temperature environment-resistant composite resin matrix in rocket fuel

Cryogenic technology is a vital part of our society, not only in our lives, but also in the field of cutting-edge technology. The research and application of cryogenic technology is involved in many important projects in many countries and even in the world, such as aviation, aerospace, energy, transportation, and medicine. With its high specific strength and high specific modulus, carbon fiber reinforced resin matrix composite materials have gradually become the key material for aerospace vehicles, with significant advantages in reducing structural weight and improving structural efficiency. However, in the ultra-low temperature environment such as liquid hydrogen and liquid oxygen, the overall structure of carbon fiber reinforced resin matrix composites is severely tested by the environment, and it is extremely important to evaluate the mechanical properties of the composites under ultra-low temperature due to the difference of their material structure and properties from those of traditional materials, and the difference of thermal expansion coefficients between the reinforcing material carbon fiber and the resin matrix in rocket fuel. In this paper, the epoxy resin-based composite system was prepared by modifying TDE-85 epoxy resin with low-viscosity cyanate resin through molecular structure design, which is suitable for ultra-low temperature environment. The surface tension and dynamic contact angle of the modified epoxy resin are better than those of the pure epoxy resin, and it can form a good infiltration with carbon fiber and the interfacial properties of the composite are excellent. Secondly, the modified epoxy resin-based composite unidirectional plate was prepared by wet winding molding process, and the low-temperature mechanical property test specimens were prepared according to the relevant test standards. The mechanical properties were tested at −196℃, −150℃, −90℃ and room temperature 25℃ to obtain the low-temperature mechanical properties of the composite system, which provided the basis for the design of the composite system in the ultra-low temperature environment. Finally, the microstructure of the epoxy matrix composites was characterized by SEM method after the different temperature tests. The material structure, morphology, and composition were characterized by field emission scanning electron microscopy (FESEM, M400 FEI) with energy dispersive X-ray spectroscopy (EDS). In this paper, TDE-85 epoxy resin was modified with low viscosity cyanate resin to produce a modified epoxy resin suitable for ultra-low temperature environment, and the process properties of the epoxy resin were characterized. The surface tension of the modified epoxy resin was 43.405 mN/m, which was significantly lower than that of the pure epoxy resin at room temperature of 48.814 mN/m. Therefore, the modified epoxy resin had better flowability and required less time to wet the fibers during the molding process, resulting in higher molding efficiency.

Simulation of crack patterns in quasi-brittle materials under thermal shock using phase field and cohesive zone models

Complex crack patterns are usually formed on the surface of brittle and quasi-brittle solids under thermal shock. In this paper, the phase field coupled cohesive zone model is established to simulate the brittle and quasi-brittle fracture processes in three-dimensional solids, especially to reproduce the complex crack patterns under thermal shock. Several examples are given to illustrate the effectiveness of the model to complex fracture problems under thermal shock: from uniaxial tensile and thermal shrinkage fracture of a one-dimensional rod to nucleation, propagation, and crack pattern formation of thermal shock crack of a three-dimensional ceramic bottle. In addition, the formation mechanism of crack patterns in ceramic bottle is discussed, especially the dominant role of the difference in thermal expansion coefficients between the ceramic matrix layer and the glaze layer in the formation of crack patterns and the final crack density.

Lanthanum Strontium Cobalt Ferrite (LSCF) perovskites by Sol-Gel Method for Potential Application in Solid Oxide Fuel Cells (SOFC)

Fuel cells are one of the most efficient and effective solutions to environmental problems and high energy demand. They are devices which change chemical energy into electrochemical energy, allowing much higher efficiency than conventional thermomechanical conversion methods. Lanthanum Strontium Cobalt Ferrite (LSCF) perovskites have been widely studied for application as cathodes in solid oxide fuel cells (SOFC) due to their high electrical conductivity, high thermal and chemical stability, low difference in thermal expansion coefficient, and physico-chemical compatibility with the other cells components. The aim of this work was to synthesize perovskitas type La0.7Sr0.3Co0.5Fe0.5O3 by sol-gel method and evaluate the potential for application as a cathode for fuel cell. The results obtained by X-ray powder diffraction (XRD) indicate that the sol-gel method calcined at 900ºC obtained an amount of the perovskite phase above 95%. The Field Emission Gun-Scanning Electron Microscope (FEG-SEM) images of LSCF film produced with 4 layers showed a better quality. Thus, the results obtained by XRD and FEG-SEM, indicate that the sol-gel method calcined at 900ºC has a potential application as cathode in solid oxide fuel cells.

GaN/Al2O3 heterostructure and intrinsic lattice constant of GaN

The relaxation process of the thermal strain in a GaN film due to the thermal expansion coefficient difference in the GaN(000l)/ a-Al2O3(0001) heterostructure is studied by varying the film thickness of GaN in a wide range from 1 to 1200 µm. The lattice constant c has a large value of 5.191 A at a film thickness less than a few microns, while it decreases to about 150, m, and becomes constant above 150, m, indicating that the strain is almost completely relaxed. The intrinsic lattice constants of wurtzite GaN free from the strain, a0 and c0 are determined to be 3.1892±0.0009 and 5.1850 ± 0.0005 A, respectively.

Stress Engineering in Germanium-Silicon Heterostructure Using Surface Activated Hot Bonding

The manufacturing of heterostructures is interesting in fields such as photonics(1), solar energy production(2) and quantum technologies(3). This paper, dedicated to germanium on silicon heterostructure manufacturing and stress engineering, builds up on Ref. (4) findings.We are using the differences in terms of coefficients of thermal expansion (CTE) between germanium and silicon, to induce a tensile stress in a thin germanium layer transferred by the Smart CutTM [1] technique onto a silicon substrate. In this approach, a bulk germanium wafer is directly bonded on a bulk silicon wafer, using surface activated bonding (SAB)(5,6). Process integration advantages are the low defect density of bulk germanium and the tensile stress that can be tuned using the bonding temperature.The adherence of SAB was high during bonding at relatively high temperatures (~250°C). Without any further heat treatment, the adherence was found to be 3500mJ/m2 by the double cantilever beam method (under prescribed displacement control and in an anhydrous atmosphere). This remarkable adherence prevented the Ge/Si heterostructure from sliding, debonding and cracking (7). The CTE difference could thus generate a large amount of tensile stress during the heterostructure cooling and splitting steps.First of all, using finite elements simulation, a model was designed to predict the bow and the in-plane internal stress after bonding and cooling of the heterostructure. Thanks to it, we could also evaluate those two values after layer transfer (splitting step). This numerical approach was more accurate than the former analytic method (Timoshenko), which did not include the non-linearity of CTE with temperature and for large displacements. Figure 1 shows the bow and the in-plane stress expected for a bonding at 250°C of, respectively, a Si/Si homostructure (Figure1.a) and a strained Ge/Si heterostructure (Figure1.b), when cooled down to room temperature. The former is flat while the bow of the latter is large indeed.Then, based on indications collected from simulations, we performed the bonding of a Si/Si homostructure in an EVG®ComBond® at 250°C. The same bonding conditions were used for an implanted germanium on silicon heterostructure. As shown in Figure 2, both bond pairs exhibited a bow close to that from FE simulations.After that, a splitting step was carried out, resulting in a thin germanium film on a silicon wafer (200mm), as shown in Figure 3. The film was transferred almost to the whole surface. The bow after splitting was of 10µm, a value not so far from the simulated value of 28.6 µm.As far as tensile stress was concerned, we used X-Ray Diffraction to gain access to the lattice parameter deformation and thus the tensile stress, 0.05% and 72 MPa, respectively (Figure 4). In comparison, FE simulation gives us 107 MPa of tensile stress after splitting. The main advantage of our approach is the lack of misfit dislocations in the Ge film, at variance with Ge epitaxy on Si (with a threading dislocations density typically around 107 cm-2, then).The presentation will focus, first, on the simulation tool and the manufacturing process used to fabricate such stressed germanium films. Then, stress calculus will be detailed. Finally, TEM imaging of cross-sections, XRD and bow measurements will help us better understand the specificities of such thin Ge films transferred on Si bulk wafers. Higurashi E. Heterogeneous integration based on low-temperature bonding for advanced optoelectronic devices. Jpn J Appl Phys. 1 avr 2018;57(4S):04FA02.King RR, Law DC, Edmondson KM, Fetzer CM, Kinsey GS, Yoon H, et al. 40% efficient metamorphic GaInP∕GaInAs∕Ge multijunction solar cells. Appl Phys Lett. 30 avr 2007;90(18):183516.Scappucci G, Kloeffel C, Zwanenburg FA, Loss D, Myronov M, Zhang JJ, et al. The germanium quantum information route. Nat Rev Mater. oct 2021;6(10):926-43.Abadie K, Fournel F, Morales C, Vignoud L, Colona JP, Widiez J. Manufacturing of Optimized Ge Substrates Using a Covalent Bonding Process. ECS Meet Abstr. 23 nov 2020;MA2020-02(22):1623.Takagi H, Kikuchi K, Maeda R, Chung TR, Suga T. Surface activated bonding of silicon wafers at room temperature. Appl Phys Lett. 15 avr 1996;68(16):2222-4.Rebhan B, Vanpaemel J, Dragoi V. 200 mm Ge Wafer Production for Oxide-Free Si-Ge Direct Wafer Bonding. ECS Trans. 8 sept 2020;98(4):87-100.Chao YL, Tong QY, Gösele UM. Thermomechanical stress in silicon on quartz wafer bonding and Smart Cut® process. MRS Proc. 2001;681:I5.10. [1] Trademark from S.O.I.T.E.C. .S.A. Figure 1

Fabrication of AAO-Based Four-Stack Thin Film Solid Oxide Fuel Cells for the Low-Temperature Operation Using Sputtering Method

Anodic Aluminium Oxide (AAO) based four thin-film solid oxide fuel cell (TF-SOFC) stack was fabricated. The fuel cell stack was tested and analyzed at the low-temperature window. Since the low-temperature operation has many advantages, such as lowering the system cost and widening the material selection, there has been much effort to reduce conductive resistance, mainly at the electrolyte, which is the most problematic issue in low-temperature operation. One of the solutions is TF-SOFC deposited on the various substrates or supporting materials. AAO, a non-conductive and nanoporous substrate, has been widely used in fabricating TF-SOFC as a substrate because of its uniformly arranged pores and highly developed manufacturing process.However, AAO is a poor template for stacking TF-SOFCs because it has lower mechanical strength than metal, has no electrical conductivity, and has a different coefficient of thermal expansion from metal. In this study, therefore, planarly stacked TF-SOFC were fabricated to expand its limits of use as a template for the stacked fuel cell. Nickel-based anode, yttria-stabilized zirconia (YSZ) electrolyte with functional layers, and platinum cathode and current collector were sequentially deposited using sputtering and atomic layer deposition methods. All thin-film components of four cells were deposited on the AAO at the same time, making good connections between each electrode. By effectively setting the deposition process, unnecessary pores of AAO were blocked, and current collecting layers were stably formed in between the structure of the cells with a step difference.Then, the stacked TF-SOFC were electrochemically analyzed, including the current density-voltage-power density curve (i-V-P curve) and electrochemical impedance spectroscopy (EIS) being compared to a single cell. The microstructure of the fuel cell and its electrically connected structures were observed by scanning electron microscopy (SEM) and focused ion beam (FIB) cross-sectional SEM analyses. The cell’s overall voltage was comparable to four times that of a single cell, and the power density was obtained. We revealed the correlation between the electrochemical performance and the microstructure of individual cells and the whole stack. The full stack achieved electrochemical and mechanical stability by forming a complete fuel cell structure and enhanced the applicability of the planar cell stack on the AAO substrate.

Study on removal mechanism of oxide film in direct current straight polarity tungsten arc welding of aluminum alloy

The Direct Current Straight Polarity (DCSP) TIG welding process of 2219 aluminum alloy was realized by removing oxide film on aluminum alloy surface with the activating flux. The effect of activating flux removing 2219 aluminum alloy surface anode oxide film and welding slag distribution morphology under the action of welding arc were analyzed. The results showed that the activating flux can effectively remove the anode oxide film, and welding slag with discontinuous floccules was distributed on the basic surface of aluminum, which was easy to remove. The difference in thermal expansion coefficient between Al and Al2O3 oxide films caused Al2O3 oxide films to crack under the action of high-temperature electric arc in TIG welding, but the oxide films cannot be removed. However, the weld surface coated with fluoride activating flux, fluoride can permeate between the oxide film and the aluminum matrix from the place where the oxide film cracked, causing defects at the film/matrix interface, which was conducive to peeling off the oxide film on the weld surface.

Employment of 3D-Printed Bilayer Structures with Embedded Continuous Fibers for Thermal Management Applications: An Axial Cooling 4D-Printed Fan Application Case Study.

Bi-material composite structures with continuous fibers embedded on polymer substrates exhibit self-morphing under thermal stimulus induced by the different coefficients of thermal expansion (CTE) between the two constituent materials. In this study, a series of such structures are investigated in terms of fiber patterns and materials to achieve programmable and reversible transformations that can be exploited for thermal management applications. Stemming from this investigation’s results, an axial cooling fan prototype is designed and fabricated with composite blades that passively alter their shape, specifically their curvature and twist angle, under different operating temperatures. A series of computational fluid dynamics (CFD) simulations are performed, subjecting the fan’s geometry to different flow temperatures to measure differences in airflow deriving from the induced shape transformations. Corresponding experimental trials are additionally performed, aiming to validate the simulation results. The results indicate the potential of utilizing bilayer self-morphing configurations for the fabrication of smart components for cooling purposes.

Non-thermal and thermal effects on mechanical strain in substrate-transferred wafer-scale hBN films

Wafer-scale thin films of hexagonal boron nitride have exceptional thermal and mechanical properties, which harness the potential use of these materials in two-dimensional electronic, device applications. Along with unavoidable defects, grains, and wrinkles, which develop during the growth process, underlying substrates influence the physical and mechanical properties of these films. Understanding the interactions of these large-scale films with different substrates is, thus, important for the implementation of this 2D system in device fabrication. MOVPE-grown 2 and 30 nm hBN/sapphire films of size 2 in. diameter are delaminated chemically and transferred on quartz, SiO2/Si, and sapphire substrates. The structural characteristics of these films are investigated by employing Raman spectroscopy. Our results suggest that not only the roughness but also the height modulation at the surface of the substrates play a pivotal role in determining substrate-mediated mechanical strain inhomogeneity in these films. The statistical analysis of the spectral parameters provides us with the overall characteristics of the films. Furthermore, a Stark difference in the thermal evolution of strain in these films depending on substrate materials is observed. It has been demonstrated that not only the differential thermal expansion coefficient of the substrates and the films, but also slippage of the latter during the thermal treatment determines the net strain in the films. The role of the slippage is significantly higher in 2 nm films than in 30 nm films. We believe that the observations provide crucial information on the structural characteristics of the substrate-coupled wafer-scale hBN films for their future use in technology.