This document summarizes research on joining titanium alloy Ti6Al4V to ceramic Al2O3 using reactive nickel-titanium (Ni/Ti) nanomultilayers as an interlayer. Ni/Ti multilayers with modulation periods of 12, 25, and 60 nm were deposited via magnetron sputtering on the material surfaces. Diffusion bonding was performed at 750-800°C for 60 minutes under 5 MPa pressure. Microstructural characterization found the interfaces mainly composed of NiTi and NiTi2 phases. Nanoindentation revealed the hardness and modulus across the interfaces reflected the observed microstructure. The joints processed at 800°C using the three modulation periods were successful, demonstrating the feasibility of using these nan
IRJET- Study on Process Parameters of Diffusion Bonding of Titanium with ...IRJET Journal
This document studies the process parameters for diffusion bonding of titanium to stainless steel 304 and aluminum 6061. Diffusion bonding is a solid-state joining process that occurs through atomic transfer at the interface when materials are bonded under heat and pressure. The key parameters that influence bonding are temperature, time, and pressure. Experiments explored bonding titanium to stainless steel at 900°C for 90 minutes at 5MPa and bonding titanium to aluminum at 450°C for 90 minutes at 10MPa. Microhardness tests found these parameter combinations produced the highest bonding strengths at the interfaces. Optimization of diffusion bonding parameters is important for joining dissimilar metals like titanium.
The document summarizes a study that investigated brazing 304L stainless steel corner joints using a nickel-based filler metal. Specifically:
- Brazing was performed under vacuum using a nickel-based shim and wire on 304L stainless steel sheets of different thicknesses.
- Microstructural examination found differences in the diffusion depth of nickel in the sheets based on their thicknesses. Microhardness was also affected by nickel diffusion.
- The nickel-based filler metal provided reasonable strength for the brazed joints between the 304L sheets of different thicknesses, as well as sufficient diffusion and filling for vacuum applications.
Preparation and Investigation on Properties of Cryogenically Solidified Nano ...IJERA Editor
In the present work, AL-alloy containing 12% silicon (LM 13) matrix nano composites were fabricated in sand moulds by using copper end blocks of copper end chill thickness 10 &15 nm with cryogenic effect . The size of the reinforcement (NanoZro2) ranges from 50-80nm being added ranges from 3 to 15 wt % in steps of 3 wt % . Cryogenically solidified Nano Metal Matrix Composites were compressed by using hydraulic compression machine. Specimens were prepared according to ASTM standards and tested for their strength, hardness and fracture toughness. Micro structural studies of the fabricated Nano Composites indicate that there is uniform distributions of reinforcements in the matrix materials (LM 13). An increasing trend of hardness, UTS & fracture toughness has been observed. The best results have been obtained at 12 wt %. The results were further justified by comparing two copper end chill thickness 10 &15 mm. Finally the Volumetric Heat Capacity of the cryo-chill is identified as an important parameter which affects mechanical properties.
Synthesis Of Various Forms Of Carbon Nanotubes by ARC Discharge Methods – Com...IRJET Journal
This document reviews various methods for synthesizing carbon nanotubes, specifically arc discharge, laser ablation, and chemical vapor deposition. It discusses the structure of single-walled and multi-walled carbon nanotubes and how they are formed. It also reviews research on reinforcing aluminum matrix composites with carbon nanotubes to improve mechanical properties like strength and stiffness. Strengthening mechanisms for aluminum-carbon nanotube composites include thermal mismatching, Orowan looping, and shear lag effects between the matrix and reinforcement.
Effect of Nano-Tio2addition on Mechanical Properties of Concrete and Corrosio...IJERA Editor
Concrete science is a multidisciplinary area of research where nanotechnology potentially offers the opportunity to enhance the understanding of concrete behavior, to engineer its properties and to lower production and ecological cost of construction materials. The main objective of this research was to evaluate the effect of nanoTiO2on compressive strength,bond strength and corrosion behavior of reinforcement bars. It has been found that the compressive strength, bond strength and corrosion resistance was increased with increasing nano-TiO2to 1.5wt. % as replacement of cement. Beyond this value, these properties decrease.
IRJET- Study on Process Parameters of Diffusion Bonding of Titanium with ...IRJET Journal
This document studies the process parameters for diffusion bonding of titanium to stainless steel 304 and aluminum 6061. Diffusion bonding is a solid-state joining process that occurs through atomic transfer at the interface when materials are bonded under heat and pressure. The key parameters that influence bonding are temperature, time, and pressure. Experiments explored bonding titanium to stainless steel at 900°C for 90 minutes at 5MPa and bonding titanium to aluminum at 450°C for 90 minutes at 10MPa. Microhardness tests found these parameter combinations produced the highest bonding strengths at the interfaces. Optimization of diffusion bonding parameters is important for joining dissimilar metals like titanium.
The document summarizes a study that investigated brazing 304L stainless steel corner joints using a nickel-based filler metal. Specifically:
- Brazing was performed under vacuum using a nickel-based shim and wire on 304L stainless steel sheets of different thicknesses.
- Microstructural examination found differences in the diffusion depth of nickel in the sheets based on their thicknesses. Microhardness was also affected by nickel diffusion.
- The nickel-based filler metal provided reasonable strength for the brazed joints between the 304L sheets of different thicknesses, as well as sufficient diffusion and filling for vacuum applications.
Preparation and Investigation on Properties of Cryogenically Solidified Nano ...IJERA Editor
In the present work, AL-alloy containing 12% silicon (LM 13) matrix nano composites were fabricated in sand moulds by using copper end blocks of copper end chill thickness 10 &15 nm with cryogenic effect . The size of the reinforcement (NanoZro2) ranges from 50-80nm being added ranges from 3 to 15 wt % in steps of 3 wt % . Cryogenically solidified Nano Metal Matrix Composites were compressed by using hydraulic compression machine. Specimens were prepared according to ASTM standards and tested for their strength, hardness and fracture toughness. Micro structural studies of the fabricated Nano Composites indicate that there is uniform distributions of reinforcements in the matrix materials (LM 13). An increasing trend of hardness, UTS & fracture toughness has been observed. The best results have been obtained at 12 wt %. The results were further justified by comparing two copper end chill thickness 10 &15 mm. Finally the Volumetric Heat Capacity of the cryo-chill is identified as an important parameter which affects mechanical properties.
Synthesis Of Various Forms Of Carbon Nanotubes by ARC Discharge Methods – Com...IRJET Journal
This document reviews various methods for synthesizing carbon nanotubes, specifically arc discharge, laser ablation, and chemical vapor deposition. It discusses the structure of single-walled and multi-walled carbon nanotubes and how they are formed. It also reviews research on reinforcing aluminum matrix composites with carbon nanotubes to improve mechanical properties like strength and stiffness. Strengthening mechanisms for aluminum-carbon nanotube composites include thermal mismatching, Orowan looping, and shear lag effects between the matrix and reinforcement.
Effect of Nano-Tio2addition on Mechanical Properties of Concrete and Corrosio...IJERA Editor
Concrete science is a multidisciplinary area of research where nanotechnology potentially offers the opportunity to enhance the understanding of concrete behavior, to engineer its properties and to lower production and ecological cost of construction materials. The main objective of this research was to evaluate the effect of nanoTiO2on compressive strength,bond strength and corrosion behavior of reinforcement bars. It has been found that the compressive strength, bond strength and corrosion resistance was increased with increasing nano-TiO2to 1.5wt. % as replacement of cement. Beyond this value, these properties decrease.
IJERA (International journal of Engineering Research and Applications) is International online, ... peer reviewed journal. For more detail or submit your article, please visit www.ijera.com
Applications of SiC-Based Thin Films in Electronic and MEMS DevicesMariana Amorim Fraga
Mariana Amorim Fraga, Rodrigo Sávio Pessoa, Marcos Massi and Homero Santiago Maciel (2012). Applications of SiC-Based Thin Films in Electronic and MEMS Devices, Physics and Technology of Silicon Carbide Devices, Dr. Yasuto Hijikata (Ed.), InTech, DOI: 10.5772/50998. Available from: https://www.intechopen.com/books/physics-and-technology-of-silicon-carbide-devices/applications-of-sic-based-thin-films-in-electronic-and-mems-devices
Enhancement of coating thickness and microhardness of ni sic nanocompositeIAEME Publication
This document analyzes the effects of varying bath parameters on the thickness and microhardness of electroplated Ni-SiC nanocomposite coatings. Experiments were conducted with variations in SiC loading, current density, and bath temperature. Results showed that coating thickness increased with higher current density and bath temperature up to a peak, then decreased. Microhardness initially increased with these parameters, reaching a maximum at intermediate levels, then decreased. The optimal coating properties were found at a SiC loading of 4g/L, current density of 3A/dm2, and bath temperature of 55°C, producing a uniform coating with high thickness and microhardness.
The developing of the composite materials produce a new generations Functionally graded material (FGM) where the materials characteristics are changing linearly depending to the composition materials variations. However, this piece of research presents an attemp to design, manufacturing and multi Ti/TiO2 combined characterization into each functionally graded materials. The supposed in this design is to better the general Ti/TiO2 characteristics. These materials were designed in order to contain a compositional differences or a gradually microstructure within the body in one piece or single material.
Fabrication and Micro structural Analysis of Carbon Nano Tube Materials by Ad...IJERA Editor
The application spectrum of low cost material reinforced metal matrix composites is growing rapidly in various
engineering fields due to their superior mechanical and thermal properties. In the present study it is proposed to
explore the possibilities of reinforcing aluminum alloys (AlSiC and Al6061) with locally available inexpensive
rice husk and fly ash for developing a new composite material. A sample of TiB2 also added to one sample to
get better phenomena’s in matrix composites. A rice husk and fly ash particles of 5, 10 and15% each by weight
are proposed to develop metal matrix composites using liquid metal processing route. Stir cast and in-situ
methods are used to prepare composites. Fabrication did by considering constant stirrer RPM. The fabricated
samples analyzed to study internal bonding applications and properties by using SEM and OM. Thermal
conductivity voltage constants also observed in microstructure analysis and flow of material also analyzed.
Thermal Barrier Coatings (TBCs) are coatings applied to gas turbine engine components to increase their high-temperature capability. TBCs typically have four layers: a superalloy substrate, bond coat, thermally grown oxide layer, and yttria-stabilized zirconia ceramic topcoat. TBCs allow gas turbine blades to operate at temperatures up to 1500°C, significantly increasing engine efficiency. However, TBCs can fail over time due to thermal expansion mismatches and oxidation of the bond coat, reducing the operating life of coated components.
Tunability of Thin Film Tantalum Nitride Grown by SputteringOnri Jay Benally
This document provides a literature review on the tunability of thin film tantalum nitride grown by sputtering. It discusses how the nitrogen concentration in TaN can be varied to achieve different material properties. Lower nitrogen concentrations produce metallic and electrically conductive TaN, while higher concentrations result in an insulating material. The document outlines common deposition methods for TaN including facing-target, direct current, and radio frequency magnetron sputtering. It reviews how nitrogen concentration affects the surface roughness, crystal structure, electrical resistivity, and mechanical hardness of sputtered TaN films.
Improving the properties of Ni-Based Alloys by Co AdditionIRJET Journal
1) The document discusses improving the properties of nickel-based alloys through the addition of cobalt.
2) Cobalt addition leads to grain refinement in the alloys, which influences both microstructure and corrosion resistance. Finer grain size improves hardness.
3) Samples of Ni-5Cr-5Al-xCo (where x is the cobalt content from 0-30%) were produced by vacuum arc melting and characterized through XRD, optical microscopy, and Vickers hardness testing.
4) Results showed that increasing the cobalt content refined grain size and improved hardness, while also enhancing corrosion resistance properties over the substrate material alone.
Effect of dilution on microstructure and hardness of a nickel-base hardfacing...RAMASUBBU VELAYUTHAM
1) The document examines the effect of dilution on the microstructure and hardness of a nickel-base hardfacing alloy deposited on an austenitic stainless steel substrate.
2) Electron probe microanalysis revealed considerable dilution of the hardfacing alloy by the substrate material within the first 2.5mm of the deposit, altering the chemistry, microstructure, and decreasing the hardness in this region.
3) Beyond 2.5mm from the interface, the hardness increases to levels comparable to the undiluted alloy as subsequent deposit layers approach, due to decreasing dilution effects farther from the substrate.
This document summarizes research on producing dissimilar metal composites of pure copper foil and 1050 aluminium using a process called Composite Metal Foil Manufacturing (CMFM). CMFM uses metal foils layered with a brazing paste, then heated and pressed to join the foils. Tests were conducted on lap shear joints of varying thickness, peel specimens, and tensile dog-bone specimens made by CMFM. Microstructural analysis showed a large proportion of bonded area between the foils. Comparative tensile tests found the CMFM aluminium-copper composite fractured at a load 11% higher than aluminium alone but lower than copper. This created a new composite material with properties between the original
Electrospun Nanofibers Reinforced Aluminium Matrix Composites, A Trial to Imp...IJAMSE Journal
A comparison between TiO2 nanofibers and carbon nanofibers as fibers reinforced metal matrix composites with respect to mechanical properties improvements have been made in this paper. Al and Mg have been chosen as metal matrices. The used carbon and ceramic nanofibers (Titanium Oxide) were successfully synthesized using electrospinning technique. Various weight percentage of calcined
electrospun TiO2 and carbon nanofibers (1, 3, 5 and 10%) were mixed with metal matrix and fabricated by route of powder metallurgy using High Frequency Induction heat Sintering (HFIHS). Mechanical properties of the sintered composites have been investigated. The manufactured pellets were tested for compression test, hardness and microstructures by the field emission scanning electron microscopes (FESEM), which reveals the homogeneous distribution of nanofibers in the Al/Mg matrices. In addition,
energy-dispersive X-ray spectroscopy (EDS) was employed to obtain the chemical analysis of each composite. The result shows that, the ultimate compressive strength increased to 415 MPa at 5% TiO2, which is 13.5% more than the pure Al. The hardness increased up to 64% in case of using the ceramic nanofibers as reinforcement. While using CNFs as reinforcement to the Al matrix deteriorates the
mechanical properties.
The document summarizes an investigation into brazing BZT-Ti6Al4V and Alumina-Ti6Al4V for RF window applications under high vacuum conditions. BZT ceramic pellets were prepared via conventional solid-state reaction and sintering. Brazing was performed with active (Ticusil, Cusil-ABA) and non-active (BAg8) brazing alloys under high vacuum. Optical microscopy, SEM-EDS, and shear testing were used to characterize the brazed joints. The results showed formation of reaction layers, metallurgical bonding between ceramic and metal, and shear strengths sufficient for the intended application.
Correlation between the Interface Width and the Adhesion Strength of Copper F...IOSRJAP
1) The document examines how applying a negative bias voltage to carbon steel substrates during copper film deposition via magnetron sputtering affects the adhesion strength and interface width between the film and substrate.
2) Adhesion strength, measured via scratch testing, increased with higher bias voltage. The critical load reached 18.5g at -600V bias compared to 9.5g for an unbiased substrate.
3) Interface width, measured by Auger electron spectroscopy, also increased with higher bias voltage. The width was 335nm at -600V bias versus 180nm for an unbiased substrate.
4) The results suggest that bias voltage promotes diffusion and mixing at the interface, widening it. This, along
IRJET- Development of MGO-EPOXY Composites with Enhanced Thermal ConductivityIRJET Journal
This document discusses the development of MgO-epoxy composites with enhanced thermal conductivity. Researchers successfully prepared MgO-epoxy composites by infiltrating magnesium oxide (MgO) powder into epoxy resin. Testing found that thermal conductivity increased with MgO content, reaching a maximum of 0.207 W/(mK) at 20 wt% MgO, higher than neat epoxy. This demonstrates a potential method for manufacturing epoxy composites with extremely high thermal conductivity suitable for electronic device packaging and heat dissipation applications. The document provides background on thermal interface materials and discusses various ceramic fillers used to increase the thermal conductivity of polymer composites.
This document discusses using magnetic permeability to store information in a way that is insensitive to magnetic fields and temperature changes. It summarizes methods for creating regions of different permeability in two materials - Metglas films and permalloy/copper bilayers. For the bilayers, annealing or ohmic heating can convert high permeability permalloy to low permeability by causing copper diffusion. Metglas bits as small as 300 nm can be written by laser heating to change the material from amorphous to crystalline phase. Permeability bits in both materials were read using magnetic tunnel junction sensors and were found to withstand gamma radiation, suggesting suitability for long-term storage.
Evaluation Performance ofan Annular Composite Fin by UsingMATLAB ProgrammingIJERA Editor
The aim of this project is analysis the efficiency ratio in an annular fin by the variation of heat transfer coefficient for any surface condition by using MATLAB software to calculate the base fin efficiency and the coated fin efficiency by the variation of heat transfer coefficient, radius ratio and base fin thickness of an annular fin and compare the coating fin efficiency to base fin efficiency. If the heat transfer coefficient is 50W/m2K the increase efficiency ratio is 10.46 – 28.02% for zinc coating fin from the literature but the MATLAB result is 9.3 - 25.54% , the gain efficiency ratio at thicker base fin (d=0.001m) is 11.72%, at the thinner base fin (d=0.0002m) is 33.57% from the literature but the MATLAB result is 7.45% (d=0.001m) and 32.14% (d=0.0002m) for zinc coating fin and the gain efficiency ratio at thicker base fin (d=0.001m) is 11.92%, at the thinner base fin (d=0.0002m) is 33.61% from the literature but the MATLAB result is 7.51% (d=0.001m) and 32.16% (d=0.0002m) for zinc alloy coating fin.
This document provides a review of research on electrical discharge machining (EDM) of non-conductive ceramic materials. It discusses how ceramics can be made electrically conductive through doping with conductive materials like titanium carbide. It then summarizes several studies that investigated EDM of doped ceramics and the effects of process parameters on material removal rate and surface finish. It also describes an "assisting electrode method" where a conductive layer forms on the ceramic surface during EDM, allowing discharges and machining to occur even for insulating materials. The document aims to demonstrate the feasibility of EDM for machining ceramics and potential applications of this innovative processing technique.
To ensure good adhesion between a 200 nm thick silicon dioxide layer and a 4.5 μm thick hardcoat polymeric coating, a better understanding of mechanisms of adhesion at this interface is needed. To reach this purpose, focus is placed on two axes: characterizing mechanical properties of materials composing the system and in parallel, finding an applicable and effective method to quantify adhesion. Small dimension of SiO2 thin film makes it challenging to accurately characterize it. Hence the use of both nano-indentation and AFM to attempt assessment of SiO2 thin film elastic modulus Ef; taking into account limitations and uncertainty associated with each technique. Elastic modulus of SiO2 thin film determined by nano-indentation is roughly 50 GPa on a wafer substrate and 15 GPa on a lens substrate. As for AFM, modulus measured is approximately 56 GPa on a wafer substrate and 22 GPa on a lens substrate. This highlights significant influence of substrate for both techniques. Impact on mechanical properties between SiO2 thin films under different intrinsic stresses was also investigated. Results suggest that higher density of SiO2 thin film leads to higher elastic modulus.
To quantify adhesion, micro-tensile and micro-compression tests were performed. Micro-tensile experiments give ultimate shear strengths of hardcoat-substrate interface ranging from 9 to 14 MPa. Values of energy release rates of SiO2 / Hardcoat, range from 0.1 J/m² to 0.5 J/m², depending on moduli values found on wafer or lens substrate.
Your One-Stop Shop for Python Success: Top 10 US Python Development Providersakankshawande
Simplify your search for a reliable Python development partner! This list presents the top 10 trusted US providers offering comprehensive Python development services, ensuring your project's success from conception to completion.
Best 20 SEO Techniques To Improve Website Visibility In SERPPixlogix Infotech
Boost your website's visibility with proven SEO techniques! Our latest blog dives into essential strategies to enhance your online presence, increase traffic, and rank higher on search engines. From keyword optimization to quality content creation, learn how to make your site stand out in the crowded digital landscape. Discover actionable tips and expert insights to elevate your SEO game.
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Similar to Joining of Ti6Al4V to Al2O3 Using Nanomultilayers.pdf
IJERA (International journal of Engineering Research and Applications) is International online, ... peer reviewed journal. For more detail or submit your article, please visit www.ijera.com
Applications of SiC-Based Thin Films in Electronic and MEMS DevicesMariana Amorim Fraga
Mariana Amorim Fraga, Rodrigo Sávio Pessoa, Marcos Massi and Homero Santiago Maciel (2012). Applications of SiC-Based Thin Films in Electronic and MEMS Devices, Physics and Technology of Silicon Carbide Devices, Dr. Yasuto Hijikata (Ed.), InTech, DOI: 10.5772/50998. Available from: https://www.intechopen.com/books/physics-and-technology-of-silicon-carbide-devices/applications-of-sic-based-thin-films-in-electronic-and-mems-devices
Enhancement of coating thickness and microhardness of ni sic nanocompositeIAEME Publication
This document analyzes the effects of varying bath parameters on the thickness and microhardness of electroplated Ni-SiC nanocomposite coatings. Experiments were conducted with variations in SiC loading, current density, and bath temperature. Results showed that coating thickness increased with higher current density and bath temperature up to a peak, then decreased. Microhardness initially increased with these parameters, reaching a maximum at intermediate levels, then decreased. The optimal coating properties were found at a SiC loading of 4g/L, current density of 3A/dm2, and bath temperature of 55°C, producing a uniform coating with high thickness and microhardness.
The developing of the composite materials produce a new generations Functionally graded material (FGM) where the materials characteristics are changing linearly depending to the composition materials variations. However, this piece of research presents an attemp to design, manufacturing and multi Ti/TiO2 combined characterization into each functionally graded materials. The supposed in this design is to better the general Ti/TiO2 characteristics. These materials were designed in order to contain a compositional differences or a gradually microstructure within the body in one piece or single material.
Fabrication and Micro structural Analysis of Carbon Nano Tube Materials by Ad...IJERA Editor
The application spectrum of low cost material reinforced metal matrix composites is growing rapidly in various
engineering fields due to their superior mechanical and thermal properties. In the present study it is proposed to
explore the possibilities of reinforcing aluminum alloys (AlSiC and Al6061) with locally available inexpensive
rice husk and fly ash for developing a new composite material. A sample of TiB2 also added to one sample to
get better phenomena’s in matrix composites. A rice husk and fly ash particles of 5, 10 and15% each by weight
are proposed to develop metal matrix composites using liquid metal processing route. Stir cast and in-situ
methods are used to prepare composites. Fabrication did by considering constant stirrer RPM. The fabricated
samples analyzed to study internal bonding applications and properties by using SEM and OM. Thermal
conductivity voltage constants also observed in microstructure analysis and flow of material also analyzed.
Thermal Barrier Coatings (TBCs) are coatings applied to gas turbine engine components to increase their high-temperature capability. TBCs typically have four layers: a superalloy substrate, bond coat, thermally grown oxide layer, and yttria-stabilized zirconia ceramic topcoat. TBCs allow gas turbine blades to operate at temperatures up to 1500°C, significantly increasing engine efficiency. However, TBCs can fail over time due to thermal expansion mismatches and oxidation of the bond coat, reducing the operating life of coated components.
Tunability of Thin Film Tantalum Nitride Grown by SputteringOnri Jay Benally
This document provides a literature review on the tunability of thin film tantalum nitride grown by sputtering. It discusses how the nitrogen concentration in TaN can be varied to achieve different material properties. Lower nitrogen concentrations produce metallic and electrically conductive TaN, while higher concentrations result in an insulating material. The document outlines common deposition methods for TaN including facing-target, direct current, and radio frequency magnetron sputtering. It reviews how nitrogen concentration affects the surface roughness, crystal structure, electrical resistivity, and mechanical hardness of sputtered TaN films.
Improving the properties of Ni-Based Alloys by Co AdditionIRJET Journal
1) The document discusses improving the properties of nickel-based alloys through the addition of cobalt.
2) Cobalt addition leads to grain refinement in the alloys, which influences both microstructure and corrosion resistance. Finer grain size improves hardness.
3) Samples of Ni-5Cr-5Al-xCo (where x is the cobalt content from 0-30%) were produced by vacuum arc melting and characterized through XRD, optical microscopy, and Vickers hardness testing.
4) Results showed that increasing the cobalt content refined grain size and improved hardness, while also enhancing corrosion resistance properties over the substrate material alone.
Effect of dilution on microstructure and hardness of a nickel-base hardfacing...RAMASUBBU VELAYUTHAM
1) The document examines the effect of dilution on the microstructure and hardness of a nickel-base hardfacing alloy deposited on an austenitic stainless steel substrate.
2) Electron probe microanalysis revealed considerable dilution of the hardfacing alloy by the substrate material within the first 2.5mm of the deposit, altering the chemistry, microstructure, and decreasing the hardness in this region.
3) Beyond 2.5mm from the interface, the hardness increases to levels comparable to the undiluted alloy as subsequent deposit layers approach, due to decreasing dilution effects farther from the substrate.
This document summarizes research on producing dissimilar metal composites of pure copper foil and 1050 aluminium using a process called Composite Metal Foil Manufacturing (CMFM). CMFM uses metal foils layered with a brazing paste, then heated and pressed to join the foils. Tests were conducted on lap shear joints of varying thickness, peel specimens, and tensile dog-bone specimens made by CMFM. Microstructural analysis showed a large proportion of bonded area between the foils. Comparative tensile tests found the CMFM aluminium-copper composite fractured at a load 11% higher than aluminium alone but lower than copper. This created a new composite material with properties between the original
Electrospun Nanofibers Reinforced Aluminium Matrix Composites, A Trial to Imp...IJAMSE Journal
A comparison between TiO2 nanofibers and carbon nanofibers as fibers reinforced metal matrix composites with respect to mechanical properties improvements have been made in this paper. Al and Mg have been chosen as metal matrices. The used carbon and ceramic nanofibers (Titanium Oxide) were successfully synthesized using electrospinning technique. Various weight percentage of calcined
electrospun TiO2 and carbon nanofibers (1, 3, 5 and 10%) were mixed with metal matrix and fabricated by route of powder metallurgy using High Frequency Induction heat Sintering (HFIHS). Mechanical properties of the sintered composites have been investigated. The manufactured pellets were tested for compression test, hardness and microstructures by the field emission scanning electron microscopes (FESEM), which reveals the homogeneous distribution of nanofibers in the Al/Mg matrices. In addition,
energy-dispersive X-ray spectroscopy (EDS) was employed to obtain the chemical analysis of each composite. The result shows that, the ultimate compressive strength increased to 415 MPa at 5% TiO2, which is 13.5% more than the pure Al. The hardness increased up to 64% in case of using the ceramic nanofibers as reinforcement. While using CNFs as reinforcement to the Al matrix deteriorates the
mechanical properties.
The document summarizes an investigation into brazing BZT-Ti6Al4V and Alumina-Ti6Al4V for RF window applications under high vacuum conditions. BZT ceramic pellets were prepared via conventional solid-state reaction and sintering. Brazing was performed with active (Ticusil, Cusil-ABA) and non-active (BAg8) brazing alloys under high vacuum. Optical microscopy, SEM-EDS, and shear testing were used to characterize the brazed joints. The results showed formation of reaction layers, metallurgical bonding between ceramic and metal, and shear strengths sufficient for the intended application.
Correlation between the Interface Width and the Adhesion Strength of Copper F...IOSRJAP
1) The document examines how applying a negative bias voltage to carbon steel substrates during copper film deposition via magnetron sputtering affects the adhesion strength and interface width between the film and substrate.
2) Adhesion strength, measured via scratch testing, increased with higher bias voltage. The critical load reached 18.5g at -600V bias compared to 9.5g for an unbiased substrate.
3) Interface width, measured by Auger electron spectroscopy, also increased with higher bias voltage. The width was 335nm at -600V bias versus 180nm for an unbiased substrate.
4) The results suggest that bias voltage promotes diffusion and mixing at the interface, widening it. This, along
IRJET- Development of MGO-EPOXY Composites with Enhanced Thermal ConductivityIRJET Journal
This document discusses the development of MgO-epoxy composites with enhanced thermal conductivity. Researchers successfully prepared MgO-epoxy composites by infiltrating magnesium oxide (MgO) powder into epoxy resin. Testing found that thermal conductivity increased with MgO content, reaching a maximum of 0.207 W/(mK) at 20 wt% MgO, higher than neat epoxy. This demonstrates a potential method for manufacturing epoxy composites with extremely high thermal conductivity suitable for electronic device packaging and heat dissipation applications. The document provides background on thermal interface materials and discusses various ceramic fillers used to increase the thermal conductivity of polymer composites.
This document discusses using magnetic permeability to store information in a way that is insensitive to magnetic fields and temperature changes. It summarizes methods for creating regions of different permeability in two materials - Metglas films and permalloy/copper bilayers. For the bilayers, annealing or ohmic heating can convert high permeability permalloy to low permeability by causing copper diffusion. Metglas bits as small as 300 nm can be written by laser heating to change the material from amorphous to crystalline phase. Permeability bits in both materials were read using magnetic tunnel junction sensors and were found to withstand gamma radiation, suggesting suitability for long-term storage.
Evaluation Performance ofan Annular Composite Fin by UsingMATLAB ProgrammingIJERA Editor
The aim of this project is analysis the efficiency ratio in an annular fin by the variation of heat transfer coefficient for any surface condition by using MATLAB software to calculate the base fin efficiency and the coated fin efficiency by the variation of heat transfer coefficient, radius ratio and base fin thickness of an annular fin and compare the coating fin efficiency to base fin efficiency. If the heat transfer coefficient is 50W/m2K the increase efficiency ratio is 10.46 – 28.02% for zinc coating fin from the literature but the MATLAB result is 9.3 - 25.54% , the gain efficiency ratio at thicker base fin (d=0.001m) is 11.72%, at the thinner base fin (d=0.0002m) is 33.57% from the literature but the MATLAB result is 7.45% (d=0.001m) and 32.14% (d=0.0002m) for zinc coating fin and the gain efficiency ratio at thicker base fin (d=0.001m) is 11.92%, at the thinner base fin (d=0.0002m) is 33.61% from the literature but the MATLAB result is 7.51% (d=0.001m) and 32.16% (d=0.0002m) for zinc alloy coating fin.
This document provides a review of research on electrical discharge machining (EDM) of non-conductive ceramic materials. It discusses how ceramics can be made electrically conductive through doping with conductive materials like titanium carbide. It then summarizes several studies that investigated EDM of doped ceramics and the effects of process parameters on material removal rate and surface finish. It also describes an "assisting electrode method" where a conductive layer forms on the ceramic surface during EDM, allowing discharges and machining to occur even for insulating materials. The document aims to demonstrate the feasibility of EDM for machining ceramics and potential applications of this innovative processing technique.
To ensure good adhesion between a 200 nm thick silicon dioxide layer and a 4.5 μm thick hardcoat polymeric coating, a better understanding of mechanisms of adhesion at this interface is needed. To reach this purpose, focus is placed on two axes: characterizing mechanical properties of materials composing the system and in parallel, finding an applicable and effective method to quantify adhesion. Small dimension of SiO2 thin film makes it challenging to accurately characterize it. Hence the use of both nano-indentation and AFM to attempt assessment of SiO2 thin film elastic modulus Ef; taking into account limitations and uncertainty associated with each technique. Elastic modulus of SiO2 thin film determined by nano-indentation is roughly 50 GPa on a wafer substrate and 15 GPa on a lens substrate. As for AFM, modulus measured is approximately 56 GPa on a wafer substrate and 22 GPa on a lens substrate. This highlights significant influence of substrate for both techniques. Impact on mechanical properties between SiO2 thin films under different intrinsic stresses was also investigated. Results suggest that higher density of SiO2 thin film leads to higher elastic modulus.
To quantify adhesion, micro-tensile and micro-compression tests were performed. Micro-tensile experiments give ultimate shear strengths of hardcoat-substrate interface ranging from 9 to 14 MPa. Values of energy release rates of SiO2 / Hardcoat, range from 0.1 J/m² to 0.5 J/m², depending on moduli values found on wafer or lens substrate.
Similar to Joining of Ti6Al4V to Al2O3 Using Nanomultilayers.pdf (20)
Your One-Stop Shop for Python Success: Top 10 US Python Development Providersakankshawande
Simplify your search for a reliable Python development partner! This list presents the top 10 trusted US providers offering comprehensive Python development services, ensuring your project's success from conception to completion.
Best 20 SEO Techniques To Improve Website Visibility In SERPPixlogix Infotech
Boost your website's visibility with proven SEO techniques! Our latest blog dives into essential strategies to enhance your online presence, increase traffic, and rank higher on search engines. From keyword optimization to quality content creation, learn how to make your site stand out in the crowded digital landscape. Discover actionable tips and expert insights to elevate your SEO game.
Taking AI to the Next Level in Manufacturing.pdfssuserfac0301
Read Taking AI to the Next Level in Manufacturing to gain insights on AI adoption in the manufacturing industry, such as:
1. How quickly AI is being implemented in manufacturing.
2. Which barriers stand in the way of AI adoption.
3. How data quality and governance form the backbone of AI.
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Webinar Recording: https://www.panagenda.com/webinars/hcl-notes-and-domino-license-cost-reduction-in-the-world-of-dlau/
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Skybuffer SAM4U tool for SAP license adoptionTatiana Kojar
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2. Nanomaterials 2022, 12, 706 2 of 15
Brazing allows successful joints to be obtained between metallic and ceramic base
materials as it does not involve melting the base materials, thus reducing the formation of
residual stresses [1,2,8–12]. Nevertheless, the most reported brazing alloys in the literature
for brazing Al2O3 to Ti6Al4V are Ag-based alloys which, despite requiring a low processing
temperature, promote the formation of (Ag), which compromises the service temperature
of the joints [1].
Diffusion bonding [13–18] can be a more appropriate joining technology for dissimilar
bonding between titanium alloys and advanced ceramics. However, the conventional
diffusion bonding process involves high temperature, pressure, and dwell time which
causes thermal stress due to a mismatch in coefficient of thermal expansion (CTE) and
thermal conductivity; consequently, cracks come up at the joint’s interface, mainly during
cooling [1]. Thus, several approaches have been developed to join dissimilar materials by
diffusion bonding, like applying interlayers between the base materials to be joined [17–24].
The interlayer has a crucial role in reducing the temperature and pressure of the bonding
process, and consequently, the thermal stress, besides increasing the contact area that favors
achieving high strength joints. In the last years, dissimilar metals have been joined by
diffusion bonding using as interlayers reactive multilayer thin films with nanometric bilayer
thickness (modulation period (Λ)) [25–27]. The success of the multilayers’ application
depends on the chemical elements that constitute them, for example, Ti/Al [25], Ni/Al [26]
or Ni/Ti [27], whose exothermic reaction works as an additional localized heating source.
For Ti/Al, Ni/Al and Ni/Ti multilayers, the heat released is ~434, ~562 and ~551 J/g,
respectively [28]. This additional heat source allows sound joints to be obtained under less
demanding conditions, without compromising the mechanical properties. Nevertheless,
this approach has not been widely studied for joining metals to ceramics. Only a few reports
are available in literature using alternating nanolayers to join metals to ceramics [20,29,30].
Zhu and Włosiński [29] deposited Ti films onto aluminum nitride (AlN) surface by
RF sputtering and joined the coated AlN to Cu by diffusion bonding at 900 ◦C for 30 min
under a pressure of 6 MPa. The shear tests showed a strength value of ~35 MPa. The
element distribution across the interface shows intense diffusion of Cu and Al from the base
materials and an interface rich in Ti. Moreover, the authors coated some Cu samples with
Ni-Al films deposited by plasma spraying (~800 µm thick), increasing the shear strength
up to ~60 MPa [29].
Cao et al. [30] investigated the joining between TiAl and TiC using an interface formed
by Ni/Al multilayers with a total thickness of ~30 µm deposited by magnetron sputtering.
The joints were processed by diffusion bonding at 700 ◦C, dwell time of 10 min under
a pressure of 40 MPa. The microstructure revealed intense diffusion of Ti from the TiAl
base metal to the interface. However, it was not identified Ti in the zone adjacent to TiC.
The Ni diffusion occurred with less intensity from the interface towards the TiAl. The
microstructural characterization showed that several layers formed at the interface; AlNi3,
AlNi3 + AlNi, Ni3(AlTi), Ni2AlTi, (Ni, Al, Ti) phases.
Yi et al. [20] investigated the joining between copper and alumina by diffusion bonding
using Ti/Al multilayers with different modulation periods and Al:Ti atomic ratios. The
joints were processed at 900 ◦C for 15 min under 5 MPa. The results showed that sound
joints could be obtained, and the shear tests revealed that the best result (~68 MPa) was
achieved using higher periods (880 nm) and a total thickness of 38 µm [20].
Preliminary authors’ work [23] on the diffusion bonding of Al2O3 to Ti6Al4V using a
reactive Ni/Ti multilayer with a 50 nm modulation period confirmed that this could be an
interesting approach for joining these base materials. However, the applied pressure was
too high, which caused a significant plastic deformation of the Ti6Al4V alloy. The decrease
of pressure is a crucial aspect for implementing this approach.
In this context, the present work’s objective is to study the feasibility of joining Ti6Al4V
to Al2O3 by diffusion bonding using Ni/Ti reactive multilayer thin films prepared by
magnetron sputtering and reducing the pressure to avoid the plastic deformation of the
Ti alloy. Moreover, the influence of different nanometric modulation periods (12, 25,
3. Nanomaterials 2022, 12, 706 3 of 15
and 60 nm) was studied. The bilayer thickness (period) of the multilayers is a critical
parameter since it influences their reactivity and grain size. According to the work of
Adams et al. [31], the peak reactivity of free-standing Ni/Ti multilayers is observed at
~10–15 nm, although a high reaction velocity is observed up to a ~60 nm bilayer thickness.
The use of the nanostructured multilayers as an interlayer material aims at increasing
the diffusivity at the interface, promoting the formation of an interface without chemical
and structural discontinuities. The total thickness of these nanomultilayers is close to
2.5–3.0 µm. The bonding experiments were conducted at 750 and 800 ◦C under a pressure
of 5 MPa. The microstructural characterization of the joint’s interface was performed by
scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDS),
and electron backscatter diffraction (EBSD), while the mechanical characterization was
performed by nanoindentation across the joint’s interface.
2. Materials and Methods
2.1. Base Materials
Ti6Al4V alloy and Al2O3 were purchased from Goodfellow in rods with diameters
of 7 and 6 mm, respectively. They were cut ~5 mm in length, ground carefully to obtain
parallelism between the two surfaces of each substrate, followed by polishing down to 1 µm
diamond suspension and 0.06 µm colloidal silica. The rods of the Al2O3 were encapsulated
by cold mounting in epoxy resin before the cut to avoid cracks and surfaces damage. The
base materials were cleaned with acetone, ethanol, and deionized water in an ultrasonic
bath and dried with heat blow air before the depositions. After applying the metallographic
procedure, the average surface roughness (Ra) was ~0.06 and ~0.10 µm for Ti6Al4V and
Al2O3, respectively.
2.2. Deposition of Ni/Ti Nanomultilayer Thin Films
Nickel and Titanium nanolayers were alternately deposited onto the polished surfaces
of both base materials (substrates) by direct current(d.c.) magnetron sputtering using
titanium (99.99% pure) and nickel (Ni-7V wt.%) targets (150 mm × 150 mm × 3–7 mm
thick). After achieving a base pressure below 5 × 10−4 Pa in the sputtering chamber, Ar
was introduced (P~1.5 × 10−1 Pa), and the substrates were cleaned by heating followed
by Ar+ (current of 20A) etching using an ion gun. The Ni/Ti depositions, carried out at
a 4 × 10−1 Pa Ar pressure, started immediately after the substrates’ cleaning. To avoid
excessive substrate heating and thus prevent reactions during the deposition process, the
substrates were glued with a silver drop to a thick copper block substrate holder that acted
as a heat sink. In addition, a silicon sheet was also glued to the copper block to obtain
nanomultilayer thin films similar to those deposited onto the Ti alloy and alumina. The
coated Si contributed to identifying the morphology and structure of the nanomultilayers
and to obtaining the total thickness and average chemical composition of the nanolayered
films. The total thickness was measured by profilometry (Perthometer SP4, with laser
probe (Mahr Perthometer SP4, Göttingem, Germany)) on the Si substrates. Figure 1 shows
a scheme of the deposition chamber.
The power density applied to the Ni and Ti targets was ~2.8 × 10−2 Wmm−2 and
~7.2 × 10−2 Wmm−2, respectively, in order to obtain a near equiatomic average chemical
composition (50 at. % Ni: 50 at.% Ti). The Ni target has vanadium to eliminate its
ferromagnetism [32]. As the third element in B2 -NiTi (cubic austenite phase), vanadium can
be in both Ni and Ti substitutional sites [33]. The distance between the targets and substrates’
surface was 90 and 75 mm for Ni and Ti targets, respectively. The substrate holder’s rotation
speed defines the time that the rotating substrates are in front of each target, determining
the thickness of the individual layers, and consequently, the period or bilayer thickness.
The Ni/Ti nanomultilayer thin films were produced with modulation periods (Λ) of 12,
25, and 60 nm and the rotation speed of the substrates was ~8, 3.3, and 2 rpm, respectively.
These periods were selected based on the reactivity of Ni/Ti multilayers and on previous
dissimilar joining of metallic materials by diffusion bonding [31,34]. A deposition time
4. Nanomaterials 2022, 12, 706 4 of 15
of ~30 min was selected for a total thickness close to 2.5–3.0 µm. Titanium’s bottom
nanolayer ensured a good adhesion to the base materials [24]. Adhesion between Ni/Ti
thin films and substrate is particularly relevant for the Al2O3 base material because the lack
of adhesion can compromise the diffusion bonding process. The adhesive strength between
nanomultilayer thin films and Al2O3 substrate was evaluated in a previous work [23].
The top nanolayer was Ni to prevent the Ti-O interaction and, thus, the oxidation of
the nanomultilayers.
thickness of the individual layers, and consequently, the period or bilayer thickness. The
Ni/Ti nanomultilayer thin films were produced with modulation periods (Λ) of 12, 25, and
60 nm and the rotation speed of the substrates was ~8, 3.3, and 2 rpm, respectively. These
periods were selected based on the reactivity of Ni/Ti multilayers and on previous dissim-
ilar joining of metallic materials by diffusion bonding [31,34]. A deposition time of ~30
min was selected for a total thickness close to 2.5–3.0 µm. Titanium’s bottom nanolayer
ensured a good adhesion to the base materials [24]. Adhesion between Ni/Ti thin films
and substrate is particularly relevant for the Al2O3 base material because the lack of adhe-
sion can compromise the diffusion bonding process. The adhesive strength between na-
nomultilayer thin films and Al2O3 substrate was evaluated in a previous work [23]. The
top nanolayer was Ni to prevent the Ti-O interaction and, thus, the oxidation of the nano-
multilayers.
Figure 1. Scheme of the deposition chamber of the magnetron sputtering equipment used to prepare
the Ni/Ti nanomultilayer thin films.
2.3. Diffusion Bonding Process
The joints were performed in an apparatus consisting of a mechanical testing ma-
chine (LLOYD Instruments LR 30K (AMETEK Test Calibration Instruments Lloyd Ma-
terials Testing, West Sussex, UK), vertical infrared radiation furnace (Termolab Electrical
Furnace, Agueda, Portugal), molybdenum punctures to apply pressure, quartz tube, and
vacuum system described in previous work [27]. A scheme of the diffusion bonding ap-
paratus used in this work is presented in Figure 2. The diffusion bonding experiments
were performed at a vacuum level better than 10−2 Pa using Ni/Ti reactive nanomultilayers
with different modulation periods to evaluate their feasibility of enhancing joining
Ti6Al4V to Al2O3. The diffusion bonding was carried out at 750 and 800 °C, by applying 5
MPa for 60 min. The heating rate was 10 °C.min−1 up to the bonding temperature, and the
cooling rate was 5 °C.min−1 up to 500 °C, followed by 3 °C.min−1 down to room tempera-
ture.
ubstrates
Target 1
Target 2
hamber
otating
motor
eat sink
ubstrate holder
Figure 1. Scheme of the deposition chamber of the magnetron sputtering equipment used to prepare
the Ni/Ti nanomultilayer thin films.
2.3. Diffusion Bonding Process
The joints were performed in an apparatus consisting of a mechanical testing machine
(LLOYD Instruments LR 30K (AMETEK Test Calibration Instruments Lloyd Materials
Testing, West Sussex, UK), vertical infrared radiation furnace (Termolab Electrical Furnace,
Agueda, Portugal), molybdenum punctures to apply pressure, quartz tube, and vacuum
system described in previous work [27]. A scheme of the diffusion bonding apparatus used
in this work is presented in Figure 2. The diffusion bonding experiments were performed
at a vacuum level better than 10−2 Pa using Ni/Ti reactive nanomultilayers with different
modulation periods to evaluate their feasibility of enhancing joining Ti6Al4V to Al2O3. The
diffusion bonding was carried out at 750 and 800 ◦C, by applying 5 MPa for 60 min. The
heating rate was 10 ◦C.min−1 up to the bonding temperature, and the cooling rate was
5 ◦C·min−1 up to 500 ◦C, followed by 3 ◦C·min−1 down to room temperature.
2.4. Microstructural Characterization of the Nanomultilayers and Joints’ Interface
The microstructural and chemical characterization of the nanomultilayers and joints
interface was carried out by scanning electron microscopy (SEM) (Thermo Fisher Scientific
QUANTA 400 FEG SEM, Thermo Fisher Scientific, Hillsboro, OR, USA) operating at
an accelerating voltage of 15 keV, coupled with energy-dispersive X-ray spectroscopy
(EDS (EDAX Inc. (Ametek), Mahwah, NJ, USA)). The EDS measurements were made
at an accelerating voltage of 15 keV by the standardless quantification method. The
results obtained by this method provide a fast quantification with automatic background
subtraction, matrix correction, and normalization to 100% for all the elements in the peak
identification list. Monte Carlo simulations of electron trajectories using CASINO software
estimated the volume of interaction. The estimated values for the lateral spread and depth
of the interaction volume are, respectively, 1.5 and 1.4 µm for the Ti6Al4V and 1.2 and
5. Nanomaterials 2022, 12, 706 5 of 15
0.8 µm for the NiTi and NiTi2. The cross-sections of the films and joint interfaces were
prepared using standard metallographic procedures.
Nanomaterials 2022, 12, x FOR PEER REVIEW 5 of 16
Figure 2. Schematic draw of the diffusion bonding apparatus.
2.4. Microstructural Characterization of the Nanomultilayers and Joints’ Interface
The microstructural and chemical characterization of the nanomultilayers and joints
interface was carried out by scanning electron microscopy (SEM) (Thermo Fisher Scien-
tific QUANTA 400 FEG SEM, Thermo Fisher Scientific, Hillsboro, OR, USA) operating at
an accelerating voltage of 15 keV, coupled with energy-dispersive X-ray spectroscopy
(EDS (EDAX Inc. (Ametek), Mahwah, NJ, USA)). The EDS measurements were made at
an accelerating voltage of 15 keV by the standardless quantification method. The results
obtained by this method provide a fast quantification with automatic background sub-
traction, matrix correction, and normalization to 100% for all the elements in the peak
identification list. Monte Carlo simulations of electron trajectories using CASINO soft-
ware estimated the volume of interaction. The estimated values for the lateral spread and
depth of the interaction volume are, respectively, 1.5 and 1.4 μm for the Ti6Al4V and 1.2
and 0.8 μm for the NiTi and NiTi2. The cross-sections of the films and joint interfaces were
prepared using standard metallographic procedures.
EBSD data were analyzed using TSL OIM Analysis 5.2 2007 (EDAX Inc. (Ametek),
Mahwah, NJ, USA). To identify the crystallographic phases formed at the joint interface,
analyses were conducted using an acceleration voltage of 15 keV to obtain Kikuchi pat-
terns. The indexation of the patterns was made by ICDD PDF2 (2006) database.
2.5. Mechanical Characterization
Nanoindentation tests were carried out across the joints’ interfaces using Micro Ma-
terials-NanoTest equipment with a Berkovich diamond indenter (NanoTest, Micro Mate-
rials Limited, Wrexham, UK). The depth-sensing indentation tests were performed in load
control mode, up to a maximum load of 5 mN. Indentation matrixes formed by 8 rows
and 12 columns (96 measurements) were defined along the joint interface. Each matrix
starts on the Ti6Al4V side, crosses the joint interface, and finishes on the alumina side.
The distance between columns was 3 µm to guarantee that some indentations fall in the
region corresponding to the interface, and the distance between rows was 5 µm. Fused
quartz was used as reference material to determine the Berkovich tip area function. Hard-
ness and reduced Young’s modulus were determined by the Oliver and Pharr method
[35]. Before the indentation tests, the joints were polished using standard metallographic
procedures.
3. Results and Discussion
3.1. Ni/Ti Nanomultilayers Characterization
Ni/Ti nanomultilayer thin films with different modulation periods were deposited
onto Ti6Al4V and Al2O3 substrates. The deposition onto silicon substrates allowed the
Figure 2. Schematic draw of the diffusion bonding apparatus.
EBSD data were analyzed using TSL OIM Analysis 5.2 2007 (EDAX Inc. (Ametek),
Mahwah, NJ, USA). To identify the crystallographic phases formed at the joint interface,
analyses were conducted using an acceleration voltage of 15 keV to obtain Kikuchi patterns.
The indexation of the patterns was made by ICDD PDF2 (2006) database.
2.5. Mechanical Characterization
Nanoindentation tests were carried out across the joints’ interfaces using Micro
Materials-NanoTest equipment with a Berkovich diamond indenter (NanoTest, Micro
Materials Limited, Wrexham, UK). The depth-sensing indentation tests were performed in
load control mode, up to a maximum load of 5 mN. Indentation matrixes formed by 8 rows
and 12 columns (96 measurements) were defined along the joint interface. Each matrix
starts on the Ti6Al4V side, crosses the joint interface, and finishes on the alumina side. The
distance between columns was 3 µm to guarantee that some indentations fall in the region
corresponding to the interface, and the distance between rows was 5 µm. Fused quartz
was used as reference material to determine the Berkovich tip area function. Hardness and
reduced Young’s modulus were determined by the Oliver and Pharr method [35]. Before
the indentation tests, the joints were polished using standard metallographic procedures.
3. Results and Discussion
3.1. Ni/Ti Nanomultilayers Characterization
Ni/Ti nanomultilayer thin films with different modulation periods were deposited
onto Ti6Al4V and Al2O3 substrates. The deposition onto silicon substrates allowed the
modulation periods and average chemical composition to be obtained. The modulation
period was estimated by dividing the total thickness by the product between deposition
time and substrates’ rotation speed. Later, the period was checked by SEM. Short period
Ni/Ti films were deposited onto Si at high rotation speeds to evaluate the average chemical
composition by SEM/EDS and confirm that it is close to the equiatomic one. After achieving
the desired average chemical composition, the depositions were carried out maintaining
the power density applied to each target and varying the substrates’ rotation speed. The
deposition of nanolayered films onto ceramics is a critical step due to the difficulty of good
metallographic preparation of the surfaces and the low thermal conductivity. Figure 3
shows the cross-section of as-deposited nanomultilayers onto silicon and Al2O3 substrates.
It can be seen that the nanolayered structure was preserved in both substrates, which
means that no reactions occurred during the sputtering process. Another characteristic that
can be observed is the typical columnar growth morphology, commonly reported in the
6. Nanomaterials 2022, 12, 706 6 of 15
literature for multilayer thin films deposited by magnetron sputtering [36–38]. Although in
Figure 3a,b the nanolayers are barely distinguished using SEM, modulation periods near
12 nm can be measured for both substrates. In Figure 3c,d modulation periods slightly
above 60 nm are observed, with Ti dark grey and Ni light grey layers clearly distinguishable.
maintaining the power density applied to each target and varying the substrates’ rotation
speed. The deposition of nanolayered films onto ceramics is a critical step due to the
difficulty of good metallographic preparation of the surfaces and the low thermal
conductivity. Figure 3 shows the cross-section of as-deposited nanomultilayers onto
silicon and Al2O3 substrates. It can be seen that the nanolayered structure was preserved
in both substrates, which means that no reactions occurred during the sputtering process.
Another characteristic that can be observed is the typical columnar growth morphology,
commonly reported in the literature for multilayer thin films deposited by magnetron
sputtering [36–38]. Although in Figure 3a,b the nanolayers are barely distinguished using
SEM, modulation periods near 12 nm can be measured for both substrates. In Figure 3c,d
modulation periods slightly above 60 nm are observed, with Ti dark grey and Ni light
grey layers clearly distinguishable.
(a) (b)
(c) (d)
Figure 3. Electron backscattered (BSE) SEM images of Ni/Ti nanomultilayer thin films deposited
onto (a) Si with Λ ≈ 12 nm, (b) Al2O3 with Λ ≈ 12 nm, (c) Si with Λ ≈ 60 nm and (d) Al2O3 with
Λ ≈ 60 nm.
3.2. Diffusion Bonding Using Ni/Ti Nanomultilayers
Microstructural and mechanical characterizations assessed the feasibility of joining
Ti6Al4V to Al2O3 using Ni/Ti nanomultilayers with different modulation periods. The
joints were processed at 750 and 800 ◦C, by applying a pressure of 5 MPa for 60 min.
Figure 4 presents SEM images of the cross-section of the joints obtained by solid-state
diffusion bonding using nanomultilayers with three different modulation periods (Λ~12,
25 and 60 nm). A thin thickness characterizes the joints’ interfaces and no microstructural
change or plastic deformation of the titanium alloy was observed when using an optimized
pressure of 5 MPa. The modulation period seems to influence the success of bonding, as
well as the bonding temperature. The number of layers observed at the interface and their
morphology also depend on the period and bonding temperature. SEM images revealed
7. Nanomaterials 2022, 12, 706 7 of 15
interfaces with apparent soundness, except the joint processed at 750 ◦C using ~12 nm
period nanomultilayers. In this case, unbonded areas and cracks are observed throughout
the joint interface (Figure 4a). Although the 12 nm period is the closest to the peak reactivity
of Ni/Ti multilayers, periods ≥ 25 nm seem more promising for assisting the diffusion
bonding process of dissimilar materials. This result corroborates previous authors’ works
on the diffusion bonding of metallic materials using nanoscale metallic multilayer thin
films [38].
With the increase of the modulation period, at 750 ◦C, a few defects are observed at
the interface (Figure 4c,e). For higher bonding temperature, fewer layers are observed at
the interface, and a greater extent of diffusion of the interface elements towards Ti6Al4V
is observed. At 750 ◦C, the interfaces obtained with the three modulation periods can be
divided into three layers: layer 1 close to the Al2O3, layer 2 at the middle of the interface,
and layer 3 close to the Ti6Al4V. As the temperature increases to 800 ◦C, the difference is
the observation of only two layers at the interface, one on the Al2O3 side and a thicker one
on the Ti6Al4V side.
Nanomaterials 2022, 12, x FOR PEER REVIEW 8 of 16
composition consists mainly of Ti (50.3 at.%) and Ni (45 at.%), which suggests that the
NiTi phase was formed. On the opposite side, adjacent to Ti6Al4V (areas marked as Z2,
Z3, and Z4), the main elements have average values of 62.3 ± 1.9 at% Ti and 33.1 ± 2.8 at%
Ni, indicating that the NiTi2 phase is present.
(a) (b)
(c) (d)
Figure 4. Cont.
8. Nanomaterials 2022, 12, 706 8 of 15
Nanomaterials 2022, 12, x FOR PEER REVIEW 9 of 16
(e) (f)
Figure 4. BSE SEM images of diffusion bonded Ti6Al4V/Al2O3 joints using Ni/Ti nanomultilayers
processed using 5 MPa during 1 h at (a) 750 °C (Λ ≈ 12 nm), (b) 800 °C (Λ ≈ 12 nm), (c) 750 °C (Λ ≈
25 nm), (d) 800 °C (Λ ≈ 25 nm), (e) 750 °C (Λ ≈ 60 nm), (f) 800 °C (Λ ≈ 60 nm).
(a) (b)
Figure 5. SEM image and EDS profiles across the joints processed at 800 °C/5 MPa/1 h using Ni/Ti
nanomultilayers with (a) Λ ≈ 12 nm and (b) Λ ≈ 60 nm.
Diffusion bonding using nanomultilayers with Λ ≈ 25 nm (Figure 3c,d) was
successful at 750 and 800 °C. Both joints present interfaces with similar chemical
composition and thickness. The EDS results suggest the phase NiTi2 was formed adjacent
to Ti6Al4V, and on the oppositive side, close to Al2O3, the NiTi phase was identified.
However, for the joint processed at 750 °C, a thin layer (Figure 4c, zone Z7) with a higher
amount of Al (19.6 at.%) is present. However, a part of this Al can be attributed to the
interaction volume with the alumina substrate. In Figure 4d the darker line indicated as
Z7 can be regarded as a Ti-rich bond line, as already observed in previous works
[26,27,41].
Figure 4. BSE SEM images of diffusion bonded Ti6Al4V/Al2O3 joints using Ni/Ti nanomulti-
layers processed using 5 MPa during 1 h at (a) 750 ◦C (Λ ≈ 12 nm), (b) 800 ◦C (Λ ≈ 12 nm),
(c) 750 ◦C (Λ ≈ 25 nm), (d) 800 ◦C (Λ ≈ 25 nm), (e) 750 ◦C (Λ ≈ 60 nm), (f) 800 ◦C (Λ ≈ 60 nm).
Figure 5 shows the EDS profiles for the joints processed at 800 ◦C using ~12 and 60 nm
period Ni/Ti nanomultilayers. Based on EDS profiles, it is clear that the interfaces are
mainly composed of Ti and Ni elements. A brighter phase with a higher amount of V is
also identified due to the presence of this element in the as-deposited nanomultilayer thin
films. Zones located close to Ti6Al4V present Ni-rich zones, confirming the diffusion of
this element towards Ti6Al4V, increasing the β-Ti phase close to the interface since Ni is
a β-stabilizer element. Similar results were obtained in diffusion bonding assisted with
Ni/Ti multilayers [23,27]. The Ni and Ti diffusivities in Ti6Al4V and NiTi at 800 ◦C are
significantly different which promotes a net diffusion of Ni from the interface towards
the Ti6Al4V and Ti from the Ti6Al4V to the interface [39]. The diffusion of Ni from the
interface towards Ti6Al4V, due to its high diffusivity, gives rise to a high amount of this
element in the β-Ti phase. As the bonding temperature increases, an intense diffusion of Ni
is promoted, resulting in a greater amount of β-Ti close to the interface. The EDS maps in
Figure 6 clearly show that this interface is characterized by a Ni-rich layer near Al2O3 and
a Ti-rich layer close to Ti6Al4V.
To identify the possible phases constituting the reaction layers formed at the interfaces,
EDS chemical analyses were performed in conjunction with SEM observations and com-
bined with the information provided by the Ni-Ti [40] and Ti-Al-Ni [40] phase diagrams.
Table 1 presents the EDS results of each selected zone marked in the SEM images of Figure 4.
The joint interface processed at 800 ◦C using the Ni/Ti film with ~12 nm modulation
period (Figure 3b) exhibits a continuous interface with a thickness similar to that obtained
at 750 ◦C, but no cracks were detected. The interface consisted of two different layers. The
layer adjacent to alumina (area marked as Z5) has a thickness of ~2.3 µm, and its chemical
composition consists mainly of Ti (50.3 at.%) and Ni (45 at.%), which suggests that the NiTi
phase was formed. On the opposite side, adjacent to Ti6Al4V (areas marked as Z2, Z3, and
Z4), the main elements have average values of 62.3 ± 1.9 at.% Ti and 33.1 ± 2.8 at.% Ni,
indicating that the NiTi2 phase is present.
Diffusion bonding using nanomultilayers with Λ ≈ 25 nm (Figure 3c,d) was successful
at 750 and 800 ◦C. Both joints present interfaces with similar chemical composition and
thickness. The EDS results suggest the phase NiTi2 was formed adjacent to Ti6Al4V, and
on the oppositive side, close to Al2O3, the NiTi phase was identified. However, for the joint
processed at 750 ◦C, a thin layer (Figure 4c, zone Z7) with a higher amount of Al (19.6 at.%)
9. Nanomaterials 2022, 12, 706 9 of 15
is present. However, a part of this Al can be attributed to the interaction volume with the
alumina substrate. In Figure 4d the darker line indicated as Z7 can be regarded as a Ti-rich
bond line, as already observed in previous works [26,27,41].
Nanomaterials 2022, 12, x FOR PEER REVIEW 9 of 16
(e) (f)
Figure 4. BSE SEM images of diffusion bonded Ti6Al4V/Al2O3 joints using Ni/Ti nanomultilayers
processed using 5 MPa during 1 h at (a) 750 °C (Λ ≈ 12 nm), (b) 800 °C (Λ ≈ 12 nm), (c) 750 °C (Λ ≈
25 nm), (d) 800 °C (Λ ≈ 25 nm), (e) 750 °C (Λ ≈ 60 nm), (f) 800 °C (Λ ≈ 60 nm).
(a) (b)
Figure 5. SEM image and EDS profiles across the joints processed at 800 °C/5 MPa/1 h using Ni/Ti
nanomultilayers with (a) Λ ≈ 12 nm and (b) Λ ≈ 60 nm.
Diffusion bonding using nanomultilayers with Λ ≈ 25 nm (Figure 3c,d) was
successful at 750 and 800 °C. Both joints present interfaces with similar chemical
composition and thickness. The EDS results suggest the phase NiTi2 was formed adjacent
to Ti6Al4V, and on the oppositive side, close to Al2O3, the NiTi phase was identified.
However, for the joint processed at 750 °C, a thin layer (Figure 4c, zone Z7) with a higher
amount of Al (19.6 at.%) is present. However, a part of this Al can be attributed to the
interaction volume with the alumina substrate. In Figure 4d the darker line indicated as
Z7 can be regarded as a Ti-rich bond line, as already observed in previous works
[26,27,41].
(a) (b)
Figure 5. SEM image and EDS profiles across the joints processed at 800 ◦C/5 MPa/1 h using Ni/Ti
nanomultilayers with (a) Λ ≈ 12 nm and (b) Λ ≈ 60 nm.
Nanomaterials 2022, 12, x FOR PEER REVIEW 10 of 16
(a) (b)
(c) (d)
Figure 6. (a) SEM image and EDS elemental maps of (b) Ti (c) Ni and (d) V of the joint process at
750 °C/5 MPa/1 h using a Ni/Ti nanomultilayer with Λ ≈ 25 nm.
Table 1. Chemical composition (at.%) obtained by EDS of the zones marked in Figure 4.
Temperature/
Modulation Period Λ
Zone
Element (at.%)
Possible Phases
Ti Al V Ni
800 °C/12 nm
1 88.6 9.7 1.7 - α-Ti
2 65.0 3.5 2.3 29.2 NiTi2
3 60.8 1.5 2.6 35.1 NiTi2
Figure 6. (a) SEM image and EDS elemental maps of (b) Ti (c) Ni and (d) V of the joint process at
750 ◦C/5 MPa/1 h using a Ni/Ti nanomultilayer with Λ ≈ 25 nm.
10. Nanomaterials 2022, 12, 706 10 of 15
Table 1. Chemical composition (at.%) obtained by EDS of the zones marked in Figure 4.
Temperature/
Modulation Period Λ
Zone
Element (at.%)
Possible Phases
Ti Al V Ni
800 ◦C/12 nm
(Figure 4b)
1 88.6 9.7 1.7 - α-Ti
2 65.0 3.5 2.3 29.2 NiTi2
3 60.8 1.5 2.6 35.1 NiTi2
4 61.0 1.0 3.0 35.0 NiTi2
5 50.3 1.4 3.3 45.0 NiTi
750 ◦C/25 nm
(Figure 4c)
1 88.4 9.9 1.7 - α-Ti
2 74.9 4.6 14.0 6.5 β-Ti + NiTi2
3 76.4 6.2 7.4 10.0 β-Ti + NiTi2
4 64.0 3.8 2.2 30.0 NiTi2
5 63.0 1.0 2.9 33.1 NiTi2
6 50.5 0.5 3.6 45.4 NiTi
7 48.5 19.6 2.6 29.3 α2-Ti3Al +AlNi2Ti + NiTi2
800 ◦C/25 nm
(Figure 4d)
1 86.0 11.0 3.0 - α-Ti
2 65.0 4.4 1.8 28.8 NiTi2
3 63.3 2.8 2.4 31.5 NiTi2
4 65.0 1.8 3.0 30.2 NiTi2
5 54.0 1.0 4.0 41.0 NiTi2+ NiTi
6 50.7 1.5 3.8 44.0 NiTi
7 68.0 3.0 29.0 NiTi2
750 ◦C/60 nm
(Figure 4e)
1 88.1 10.1 1.8 - α-Ti
2 63.7 2.9 1.7 31.7 NiTi2
3 50.5 0.6 3.4 45.5 NiTi
4 53.0 0.6 3.8 43.6 NiTi+ NiTi2
5 45.4 0.7 3.3 50.6 NiTi
800 ◦C/60 nm
(Figure 4f)
1 87.0 11.0 2.0 - α-Ti
2 63.0 3.0 2.0 32.0 NiTi2
3 60.0 0.9 3.0 36.1 NiTi2
4 48.0 3.3 3.5 45.2 NiTi
Figure 4e,f show images of the interfaces processed using Ni/Ti films with Λ ≈ 60 nm
at 750 and 800 ◦C, respectively. The interfaces present chemical compositions similar to
the other interfaces and it is possible to detect NiTi2 and NiTi layers. Figure 4f shows the
interface of the joint obtained at 800 ◦C, and according to the EDS chemical compositions, a
NiTi2 phase adjacent to Ti6Al4V is identified, while a NiTi phase formed adjacent to Al2O3.
The EBSD technique was used to confirm the phases at the interface; this technique
allows Kikuchi patterns to be obtained in thin zones with a small interaction volume.
Figure 7 displays EBSD Kikuchi patterns obtained for joints processed at 800 ◦C for 60 min
using Ni/Ti films with ~12 and 60 nm periods. These results confirm the presence of the
NiTi2 phase adjacent to Ti6Al4V. On the opposite side, close to Al2O3, the formation of the
NiTi phase is identified. The joint produced with Λ ≈ 12 nm exhibits a thin layer close
to the Al2O3 which has been identified as NiTi2 (Figure 7a). This layer was not identified
by EDS due to its small size. As the period increases, this layer is not observed. The
formation of layers composed of NiTi2 aligned grains has already been reported in previous
works [27,36,41] when Ni/Ti multilayer thin films were used to assist the diffusion bonding
of titanium alloys. The formation of the NiTi2 grains can be explained due to the decrease
of the solubility of Ti in NiTi with the cooling from the bonding temperature. It can be also
confirmed with this EBSD analysis that the β-Ti phase increases near the interface with the
Ti6Al4V alloy due to the Ni diffusion, in accordance with the study of Cavaleiro et al. [42].
11. Nanomaterials 2022, 12, 706 11 of 15
Nanomaterials 2022, 12, x FOR PEER REVIEW 12 of 16
(a)
(b)
Figure 7. SEM images and EBSD Kikuchi patterns indexed as NiTi, NiTi2 and β-Ti phases of zones
marked on the joints processed at 800 °C/5 MPa/1 h using Ni/Ti nanomultilayers with (a) Λ ≈ 12 nm
and (b) Λ ≈ 60 nm.
In previous authors’ work [23], without interlayer material, unsuccessful joining
between Al2O3 and Ti6Al4V was reported at 800 °C during 60 min under 50 MPa of
pressure. The joints produced using Ni/Ti nanomultilayers improved the contact surface,
the diffusivity through the interface, and reduced residual stress allowing the success of
the joining process at 800 °C/5 MPa/60 min, as well as at 750 °C/5 MPa/60 min. During the
diffusion bonding process, Ni/Ti nanomultilayers acted as a localized heat source,
releasing heat to the system and allowing the bonding conditions to be reduced, namely
the temperature and pressure [26,27,30,41,43].
Nanoindentation experiments were performed across the interface and zones
adjacent to the base materials in order to obtain the joints’ hardness and reduce Young´s
modulus (Er) distribution maps. Figure 8 shows hardness and Er maps for the joints
processed at 800 °C using nanomultilayers with three different modulation periods, and
for the joint processed at 750 °C using the highest modulation period Ni/Ti thin film.
Figure 7. SEM images and EBSD Kikuchi patterns indexed as NiTi, NiTi2 and β-Ti phases of zones
marked on the joints processed at 800 ◦C/5 MPa/1 h using Ni/Ti nanomultilayers with (a) Λ ≈ 12 nm
and (b) Λ ≈ 60 nm.
The microstructural characterization of the joints is in agreement with studies carried
out on the microstructural evolution of Ni/Ti multilayer thin films with nanometric periods.
In-situ thermal evolution studies [34,37,42] indicated that the first crystalline phase formed
is NiTi (reacted multilayer), at temperatures of 375–400 ◦C, for Ni/Ti multilayers with
different modulation periods, as a result of the Ni + Ti exothermic reaction. The formation
of the NiTi2 phase at the interface has been reported in dissimilar diffusion bonding
using Ni/Ti multilayer thin films when at least one of the base materials was the Ti6Al4V
alloy [27,34,38,43]. Due to the diffusion of Ti from the Ti6Al4V alloy towards the interface
and of Ni in the opposite direction already mentioned, a Ti enrichment is observed which
promotes the formation of the NiTi2 layer close to this base material. Ni diffusion towards
the Ti6Al4V also promotes the increase of the β-Ti phase close to the interface because Ni is
a β-stabilizer element.
In previous authors’ work [23], without interlayer material, unsuccessful joining
between Al2O3 and Ti6Al4V was reported at 800 ◦C during 60 min under 50 MPa of
pressure. The joints produced using Ni/Ti nanomultilayers improved the contact surface,
the diffusivity through the interface, and reduced residual stress allowing the success of
the joining process at 800 ◦C/5 MPa/60 min, as well as at 750 ◦C/5 MPa/60 min. During
the diffusion bonding process, Ni/Ti nanomultilayers acted as a localized heat source,
12. Nanomaterials 2022, 12, 706 12 of 15
releasing heat to the system and allowing the bonding conditions to be reduced, namely
the temperature and pressure [26,27,30,41,43].
Nanoindentation experiments were performed across the interface and zones adjacent
to the base materials in order to obtain the joints’ hardness and reduce Young´s modulus
(Er) distribution maps. Figure 8 shows hardness and Er maps for the joints processed at
800 ◦C using nanomultilayers with three different modulation periods, and for the joint
processed at 750 ◦C using the highest modulation period Ni/Ti thin film.
Nanomaterials 2022, 12, x FOR PEER REVIEW 13 of 16
SEM Hardness Reduced Young´s modulus
800
°C
(Λ
≈
12
nm)
(a) (b) (c)
800
°C
(Λ
≈
25
nm)
(d) (e) (f)
750
°C
(Λ
≈
60
nm)
(g) (h) (i)
800
°C
(Λ
≈
60
nm)
(j) (k) (l)
Figure 8. SEM images with the nanoindentation matrices marked, and hardness and reduced
Young´s modulus (Er) maps across the joints processed using Ni/Ti nanomultilayers at (a–c) 800 °C
(Λ ≈ 12 nm), (d–f) 800 °C (Λ ≈ 25 nm), (g–i) 750 °C (Λ ≈ 60 nm) and (j–l) 800 °C (Λ ≈ 60 nm).
Figure 8. SEM images with the nanoindentation matrices marked, and hardness and reduced
Young´s modulus (Er) maps across the joints processed using Ni/Ti nanomultilayers at (a–c) 800 ◦C
(Λ ≈ 12 nm), (d–f) 800 ◦C (Λ ≈ 25 nm), (g–i) 750 ◦C (Λ ≈ 60 nm) and (j–l) 800 ◦C (Λ ≈ 60 nm).
13. Nanomaterials 2022, 12, 706 13 of 15
The hardness maps show that the interface has a hardness value closer to Ti6Al4V,
although a hardness increase is observed in the regions adjacent to the Ti alloy, identified
as NiTi2. The variations of the hardness and Er values obtained by nanoindentation
are expected due to the different phases that compose the interface. The distribution
maps make it possible to clearly distinguish the NiTi and NiTi2 layers present at the
interfaces. A lower Young’s modulus at the interface was expected near the Ti6Al4V
side, since according to Young’s modulus values reported in the literature [44,45] ENiTi2
ENiTi, ETi6Al4V. Nevertheless, higher Er values were obtained in the layer identified
as NiTi2, in accordance with previous dissimilar diffusion bonding experiments using
Ni/Ti reactive nanomultilayers [23,34,43]. As the temperature increases, the hardness of
the interface becomes more homogeneous (Figure 8h,k). This is related to the fact that
increasing the bonding temperature results in more diffusion, which promotes homogeneity
of the microstructure and chemical composition of the interface. Regarding the modulation
period, it is noted that there is a decrease in the interface hardness with its increase. This
may be related to the fact that the shorter the multilayer period, the smaller the grain
size of the phases that form upon reaction during the joining process, as already reported
in previous works [36,38]; as a result interfaces with slightly different hardness values
are obtained.
The use of nanomultilayers as interlayer material proved to be a suitable approach
that allows the joining of Ti6Al4V to Al2O3 without plastic deformation of the titanium
alloy. The multilayers’ period has an influence on the microstructure of the interface and on
the mechanical properties of the joints obtained. As the period decreases, the grain size also
decreases, resulting in joints with higher hardness at the interface, which can be detrimental
to the mechanical behavior. In addition, the hardness and reduced Young modulus maps
revealed more homogeneous interfaces when using Ni/Ti nanomultilayers with Λ ≥ 25 nm,
which confirms that these periods are more promising for joining purposes.
4. Conclusions
Diffusion bonding of Ti6Al4V to Al2O3 was processed at 750 and 800 ◦C, dwell time
of 60 min and under an optimized pressure of 5 MPa using magnetron sputtered Ni/Ti
multilayers with nanometric periods. The use of these nanomultilayers proves to be an
effective approach since, without an interlayer, it was not possible to obtain sound joints
between these base materials under the selected conditions.
The modulation period and the bonding temperature influence the number of layers
formed at the joint interface, and as a consequence, the hardness and reduced Young’s mod-
ulus distribution maps. These nanoindentation maps highlight the different mechanical
properties of the phases present across the joint interfaces. According to the microstructural
analysis and mechanical behavior of the joints, the optimum multilayer periods are between
25 and 60 nm.
The joints’ interfaces are mainly composed of NiTi and NiTi2 phases. The layers
adjacent to Ti6Al4V were identified as NiTi2 phase, while NiTi is identified in the layer
adjacent to Al2O3. The intense interdiffusion of Ti and Ni between the Ti6Al4V and the
interlayer material induces the formation of a higher amount of β-Ti phase close to the
interface of this base material.
The use of the Ni/Ti nanomultilayers in the diffusion bonding of Ti6Al4V to Al2O3
presents a clear advantage in relation to the process without an interlayer material. The
nanomultilayers improve the contact between the joining surfaces and enhance the joining
between alumina and titanium alloy due to the improved reactivity and diffusivity resulting
from their nanometric character.
Author Contributions: Conceptualization, M.S.J.; methodology, S.S., A.S.R. and M.T.V.; validation,
S.S., A.S.R. and M.T.V.; investigation, M.S.J., S.S., A.S.R. and M.T.V.; writing—original draft prepara-
tion M.S.J.; writing—review and editing, S.S. and A.S.R.; funding acquisition, S.S. All authors have
read and agreed to the published version of the manuscript.
14. Nanomaterials 2022, 12, 706 14 of 15
Funding: This work was financially supported by: Project PTDC/CTM-CTM/31579/2017—POCI-01-
0145-FEDER-031579- funded by FEDER funds through COMPETE2020—Programa Operacional Com-
petitividade e Internacionalização (POCI) and by national funds (PIDDAC) through FCT/MCTES.
This research was also supported by national funds through FCT–Fundação para a Ciência e a
Tecnologia, under the project UIDB/EMS/00285/2020.
Data Availability Statement: Not applicable.
Acknowledgments: The authors are grateful to CEMUP-Centre of Materials of the University of
Porto for expert assistance with SEM.
Conflicts of Interest: The authors declare no conflict of interest.
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