Metal and metallic alloy casting is widely used for manufacturing components in high-performance industries, including automotive and aerospace. However, cast metallic alloys often exhibit limitations such as low fracture toughness and reduced tensile strength.
Image Credit: Mr.1/Shutterstock.com aluminium section profiles
Incorporating nanotechnology into the casting process has shown potential for improving the mechanical properties of these alloys. The use of nanoparticles and nanostructures during casting can enhance the strength and other mechanical characteristics of the final product.
The demand for lightweight, high-strength, and precisely engineered components that can withstand extreme conditions, such as elevated temperatures and pressures, has grown significantly.
While the casting process is widely employed for materials like aluminum, steel, and titanium, it faces challenges such as susceptibility to hot cracking, reduced yield compared to other high-cost preparation methods, and limited fluidity in certain components. These limitations highlight the need for innovative solutions to improve the efficiency and quality of cast parts.
The addition of nanoparticles and nano-powders has shown potential for improving material properties, making it a focus of research for material scientists and nanotechnology specialists.1
Aluminum alloys are commonly produced using casting methods; however, efforts to optimize their design for improved compatibility and performance have had limited success. Incorporating nanoparticles through stir casting or squeeze casting has proven effective in enhancing the wear and corrosion resistance of these alloys, which are widely used in high-strength aerospace applications.
Nano-treatment has been applied to enhance the properties of 7075 aluminum alloys. Recent research has investigated its effects on surface roughness, resistance to hot cracking, and microstructural characteristics in AA7075 fabricated through investment casting.
The addition of varying volumes of nanoparticles has been studied, showing measurable improvements in fluidity length in nano-treated alloys. A 1 % nanoparticle volume resulted in the greatest increase in fluidity length, while a 0.5 % volumetric addition exhibited the most consistent fluidity performance across different operating pressures.
The integration of titanium nanoparticles effectively addressed the issue of hot cracking in AA7075 alloys. In pristine samples, hot cracking was observed at a vacuum pressure of 45 kPa, whereas the addition of nanoparticles significantly reduced crack dimensions. Only one sample containing 0.5 vol% of nanoparticles exhibited hot cracking. Samples with higher nanoparticle concentrations demonstrated improved strength and were free from cracks.
The samples with higher nanoparticle content showed a reduction in surface roughness by approximately 59 %, resulting in smoother and glossier surfaces. These improvements suggest that nanoparticle-enhanced casting can be utilized to produce thin-walled structures with high strength, broadening the application potential of cast metals and their alloys.
High-strength cast alloys of aluminum, zinc, and copper are susceptible to corrosion damage. Researchers investigated the nano-treatment of 7075 aluminum alloys by incorporating TiB2 nanoparticles. In untreated cast alloys, the oxide layer resistance was measured at 23.58 Ω.cm2, while the polarization resistance was 434.1 Ω.cm2.
The incorporation of nanoparticles significantly enhanced the corrosion resistance. With the addition of 1.5 vol% TiC nanoparticles, the oxide layer resistance increased to 59.60 Ω.cm2, and the polarization resistance rose to 3915 Ω.cm2.3 These findings demonstrate that nanoparticle integration effectively improves the corrosion resistance of aluminum alloys.
The ceramic particulate-reinforced metal-matrix composites (MMCs) field has advanced significantly over the past decade. However, large-scale production of metal matrix nanocomposites (MMnCs) remains challenging, primarily due to the poor wettability of ceramic nanoparticles, which complicates their incorporation using conventional casting methods. Uniform dispersion of nanoparticles within the steel matrix is essential for improving the material's mechanical properties and performance.4
Nanoparticles influence the solid-liquid phase transformation in steel-cast alloys by affecting heterogeneous nucleation. This process depends on the interfacial energy between the second-phase particle substrate and the nucleating phase.
During solidification, dispersed second-phase particles in molten steel act as nucleation sites for the crystalline primary phase, increasing the nucleation rate. Research indicates that adding ZrC nanoparticles to low-carbon steel at a volume fraction exceeding 0.5% saturates the nucleation sites, reducing the grain refinement effect. These particles not only facilitate nucleation but also regulate grain growth during the liquid-solid transformation process.5
The addition of specially developed nanopowders to steel-cast alloys has been shown to enhance their mechanical properties. In a study involving the modification of carbon steel alloys with TiN and Y2O3 nanopowder particles, concentrations ranged from 0.03 % to 0.25 % by weight.
Experimental results indicated a reduction in alloy porosity by 25–36 % and improvements in fracture toughness and yield values by 35–50 %. The ultimate tensile strength increased by 19 %, demonstrating that the controlled integration of nanopowders in carbon steel alloys can effectively enhance tensile characteristics.6
Magnesium alloys are commonly used to produce lightweight, high-strength components; however, they have inherently poor wear resistance in comparison to traditional alloys. To address this issue, researchers have incorporated SiC nanoparticles into stir-cast Mg alloys to investigate their effects on tensile properties.
The study involved controlled nanoparticle additions at concentrations of 0.2 %, 0.5 %, and 1 % by weight. Results showed that increasing nanoparticle concentration improved alloy hardness, with a 25 % increase in hardness compared to untreated samples. The presence of SiC nanoparticles in the matrix was found to restrict localized deformation, contributing to the observed improvement in mechanical properties.
Similar improvements were observed for the ultimate tensile and yield strength of the alloy, with the addition of 1 wt% nano-fillers resulting in a 30 % increase in strength. Enhanced wear resistance was also demonstrated during penetration testing, as indicated by a measurable reduction in penetration depth.7
Experimental studies on various cast alloys, including magnesium, aluminum, steel, and titanium, consistently show that the incorporation of nanoparticles, nanopowders, or nanotubes improves their functional properties. With increasing demand for high-strength alloys, ongoing research emphasizes the importance of cost-effective and environmentally sustainable methods for developing nano-enhanced cast alloys.
Optimized Steel Analysis with Accurate XRF Spectrometry
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Ibtisam graduated from the Institute of Space Technology, Islamabad with a B.S. in Aerospace Engineering. During his academic career, he has worked on several research projects and has successfully managed several co-curricular events such as the International World Space Week and the International Conference on Aerospace Engineering. Having won an English prose competition during his undergraduate degree, Ibtisam has always been keenly interested in research, writing, and editing. Soon after his graduation, he joined AzoNetwork as a freelancer to sharpen his skills. Ibtisam loves to travel, especially visiting the countryside. He has always been a sports fan and loves to watch tennis, soccer, and cricket. Born in Pakistan, Ibtisam one day hopes to travel all over the world.
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