Metal materials can be reinforced with filler particles to increase their strength, providing metal-filler composites. Such composites are manufactured by a variety of methods but typically require chemical and/or mechanical pre-treatment of the filler material. In addition, the filler material often agglomerates together within the metal matrix, limiting its effectiveness.
Embodiments of the subject invention provide novel and advantageous metal (e.g., aluminum (Al))-nanoparticle composites and methods of manufacturing the same. Ultrasonic techniques can be used to achieve superior dispersion of nanoparticles, including SiC nanoparticles and/or one-dimensional (1D) fibrous boron nitride nanotubes (BNNTs) in the metal matrix of the aluminum (e.g., by incorporating into the Al melt). This can result in fine-grained, dense, and high strength nanocomposites.
In an embodiment, a method of fabricating a metal-nanoparticle composite can comprise: preparing a cavity inside a block of a metal; disposing nanoparticles in the cavity to provide a nanoparticle-metal block; melting the nanoparticle-metal block to provide a molten material; stirring the molten material to provide a stirred melt; ultrasonically treating the stirred melt to provide an ultrasonically-treated melt; and cooling the ultrasonically-treated melt (e.g., in an ambient environment) to provide the metal-nanoparticle composite. The nanoparticles can be, for example, BNNTs. The metal can be, for example, Al, an Al alloy, magnesium (Mg), or an Mg alloy. The ultrasonically treating of the stirred melt can comprise inserting a probe in the stirred melt to ultrasonically treat the stirred melt at a controlled amplitude and a controlled frequency for a predetermined period of time. The controlled amplitude can be in a range of from 10 micrometers (μm) to 30 μm, the period of time being in a range of from 10 seconds (s) to 120 s, and the controlled frequency can be in a range of from 18 kilohertz (kHz) to 20 kHz. A tip of the probe configured to be inserted in the stirred melt can have a length in a range of from 4 millimeters (mm) to 8 mm. The melting of the nanoparticle-metal block comprising melting the nanoparticle-metal block in a crucible placed in a furnace at a predetermined temperature (e.g., 660° C. to 750° C.). The nanoparticles can be pure nanoparticles that have not undergone any chemical pre-treatment or mechanical pre-treatment prior to being disposed in the cavity. The cavity can have a diameter in a range of from 20 mm to 30 mm and/or a height in a range of from 15 mm to 20 mm. The nanoparticles can be disposed in the cavity such that a volume percentage of the nanoparticles in the nanoparticle-metal block is in a range of from 0.5% to 5% (e.g., 0.5% to 2%). The nanoparticles can be BNNTs, the BNNTs in the metal-nanoparticle composite having an aspect ratio in a range of from 10,000 to 30,000, and/or the BNNTs can be uniformly dispersed within the metal in the metal-nanoparticle nanocomposite.
In another embodiment, a metal-BNNT composite can comprise pure BNNTs (i.e., from BNNTs that were not chemically and/or mechanically pre-treated prior to be added to the metal) uniformly dispersed within a matrix of the metal. The BNNTs within the metal matrix can have an aspect ratio in a range of from 10,000 to 30,000. The metal-BNNT composite can be formed by in situ ultrasonic casting as disclosed herein. The metal can be, for example, Al, an Al alloy, magnesium (Mg), or an Mg alloy.
Embodiments of the subject invention provide novel and advantageous aluminum (Al)-nanoparticle composites and methods of manufacturing the same. Ultrasonic techniques can be used to achieve superior dispersion of nanoparticles, including SiC nanoparticles and/or one-dimensional (1D) fibrous boron nitride nanotubes (BNNTs) in the metal matrix of the aluminum (e.g., by incorporating into the Al melt). This can result in fine-grained, dense, and high strength nanocomposites.
No related art methods exist to manufacture an Al matrix composite reinforced with a homogeneous distribution of high surface area BNNTs by casting. Embodiments of the subject invention fill this gap by providing methods to rapidly manufacture Al matrix composites reinforced with a uniform distribution of pure, high surface area BNNTs by ultrasonic casting. Such methods enhance the integration of the BNNTs by in situ, one-step anchoring with Al, while also preserving the pristine structural morphology of the BNNTs, enabling excellent flexibility for manufacturing a wide range of metal and alloy matrix composites, and saving time and money. These advantages provide the ability to manufacture a component that can bear the same load (as a pure Al component) using a lower volume of material. Embodiments thus provide alternative, green technology for fabrication of lightweight, high strength components with lower fuel consumption and carbon footprint, to be used in a variety of applications including but not limited to aerospace and automotive components.
In many embodiments, BNNTs can be incorporated into a metal matrix (e.g., an Al matrix) by ultrasonic cavitation. BNNT is a one-dimensional (1D) nanomaterial comprising hexagonal boron nitride (h-BN) sheets wrapped in a tubular form, analogous to carbon nanotubes (CNTs). BNNTs display extraordinary mechanical properties (elastic modulus >1 teraPascal (TPa) and tensile strength up to about 61 gigaPascal (GPa)). BNNTs also exhibit high flexibility, with double the fracture strain of CNTs. A major advantage of BNNTs over CNTs is the thermal stability up to 1000° C., compared to the fact that CNTs start oxidizing at 450° C. High-temperature stability of BNNTs can enable processing of low melting point metals such as Al and Mg by the solidification route because BNNTs are stable at temperatures exceeding their melting points. Also, BNNTs display extraordinary thermal conductivity, piezoelectric behavior, chemical stability against acids and bases, and ability to suppress neutron radiation. Therefore, BNNTs are a promising material to develop multifunctional nanocomposites for advanced military and civil applications. Long nanotubes can be used for effective stress transfer from the metal matrix to the filler (shear-lag mode). BNNT can be used as a reinforcing filler phase for Al-based metal matrix composites. A very limited interfacial reaction takes place to form ultra-thin AlN layer, which promotes interfacial wetting of nanotubes (see also
Embodiments of the subject invention allow rapid production of Al matrix composites reinforced with a uniform distribution of nanoparticles (e.g., SiC nanoparticles or BNNTs) by ultrasonic casting. Superior in situ, one-step anchoring of individual nanoparticles with the Al matrix is achieved by harnessing controlled interfacial reactions between the two. Preservation of the purity of high surface area BNNTs can enable full utilization of the strength and thermal stability of the reinforcement. The resulting composites have good material flexibility for manufacturing lightweight, high strength Al-nanoparticle composites.
Referring still to
Effective dispersion is a key challenge in nanocomposite processing. Adhesion, capillary, and van der Waals forces hold together the nanoparticles as agglomerates. The strength of the agglomerates is given as:
where P is the total force of binding, Ar is the cross-section area of the agglomerate, fv is the volume fraction of the particle in the agglomerate, F is the interparticle binding force and d is the average diameter of the particle. In nanocomposites, the size of the particles (d) is extremely small (1-100 nanometers (nm)). As a result, binding forces are very high, and dispersion is not as easy as in the case of micron-size particles. Ultrasonic cavitation produces high-intensity acoustic waves with alternating compression-expansion cycles, resulting in the formation and collapse of microbubbles in the melt (see also
In aerospace and automotive components, Al is the most widely used among commercial light metals. In order to lower fuel consumption in these applications, the weight of the components needs to be reduced without compromising their load-bearing capability. This requires a material with higher strength per unit weight or higher specific strength. BNNTs, exhibiting high strength (about 61 gigaPascals (GPa)) and low density (0.3-2.0 grams per cubic centimeter (g/cc)), are a promising candidate to reinforce the Al matrix for the fabrication of high specific strength composites. Embodiments of the subject invention can manufacture an advanced BNNT reinforced Al matrix composite within minutes (e.g., 45 minutes or less, 40 minutes or less, 35 minutes or less, 30 minutes or less, 25 minutes or less, 20 minutes or less, 15 minutes or less, or even 10 minutes or less).
Embodiments of the subject invention provide several advantages over the related art. Homogenous dispersion of high surface area BNNTs in the Al matrix can be achieved using ultrasonic casting. Ultra-long BNNTs would be expected to entangle and agglomerate in molten Al due to the strong mutual attraction between their surfaces known as van der Waals forces. In embodiments of the subject invention, the BNNTs are disentangled into individual BNNTs by administering high-intensity ultrasound waves that overcome the attractive forces. The waves subsequently propagate throughout the melt, thereby distributing the BNNTs. Embodiments can therefore result in dispersing BNNTs with an extremely high aspect ratio (e.g., 10,000-30,000) by ultrasonic casting, where the aspect ratio is the length divided by the width (e.g., width when viewed from side) or the length divided by the diameter. The aspect ratio of reinforcements dispersed by related art technologies range from 400-1,000 for Carbon Nanotubes (CNTs) to 200-5,000 for BNNTs. Embodiments of the subject invention surpass these by a factor of 20-150.
Enhanced integration between the BNNTs and the Al matrix is achieved by ultrasonic casting. A large area of interface can be created between the BNNTs and Al, and a large number of locations are thus generated, which drives in situ reactions between BNNTs and Al. The resulting enhancement of interfacial bonding enables the transfer of load from the metal matrix to the stronger reinforcement. Therefore, the maximum interphase strengthening potential of the BNNTs is utilized.
In related art methods, nanotube reinforcements such as CNTs and BNNTs are always subjected to a highly specialized chemical and/or mechanical pre-treatment. CNTs are surface coated with chemicals, metal-plated, structurally altered by heat treatment, protected by a layer of oxide, and/or disintegrated by ball milling. BNNTs are compressed into pellets or coated by sputtering. Pre-treatment of reinforcements imposes a major limitation by causing loss or diminishment of the intrinsic properties of the reinforcements. Embodiments of the subject invention overcome these issues by maintaining the pristine structural morphology of the nanoparticle reinforcements (e.g., BNNTs) by ultrasonic casting. That is, the nanoparticle reinforcements (e.g., BNNTs) can be cast with no chemical pre-treatment and no mechanical pre-treatment (i.e., in their pure form).
Embodiments of the subject invention enable superior flexibility in materials for manufacturing lightweight, high strength metal matrix composites. Although Al and Al alloy matrix composites are discussed herein in detail, embodiments are not limited thereto. In addition to Al and Al alloys, the methods of embodiments of the subject invention can be employed to fabricate magnesium (Mg) and Mg alloy matrix composites reinforced with a uniform distribution of pure nanoparticles (e.g., BNNTs). Indeed, the thermal stability of BNNTs up to 1000° C. can be utilized to integrate it with any metal or alloy matrix with a melting point below this temperature. Embodiments can thus be used to fabricate a wide range of BNNT reinforced metal matrix composites.
Embodiments of the subject invention save time and monetary expenditure compared to related art methods and composites. No chemical and/or mechanical pre-treatment of the nanoparticle reinforcement (e.g., BNNTs) is necessary, and such treatments typically require an additional 14-48 hours due to their inherently time-consuming nature. Embodiments of the subject invention provide one-step ultrasonic casting methods that can cut manufacturing time to about 10-30 minutes. The simplicity eliminates the need for specialized instruments and skill, thereby lowering the cost of manufacturing.
Embodiments of subject invention advantageously provide at least the following: disentanglement and uniform distribution of individual, high aspect ratio BNNTs in a molten Al matrix by ultrasonic waves in minutes; harnessing of integral anchoring between BNNTs and Al by in situ interfacial reactions; and preservation of the pristine structure and morphology of BNNTs in an Al-BNNT composite (which can also be referred to as a BNNT-reinforced Al matrix composite).
In an embodiment, a method of manufacturing a BNNT-reinforced Al matrix composite can include: preparing a cavity inside an Al block (e.g., a cylindrical Al block) and disposing BNNTs inside the cavity; melting the Al and BNNTs and stirring the molten Al; ultrasonically treating the molten Al (e.g., by inserting a probe inside the molten Al); and cooling the ultrasonically treated melt (e.g., in an ambient environment) to provide the BNNT-reinforced Al matrix composite. The cavity can have a diameter of, for example, 20-30 millimeters (mm) and a height of, for example, 15-20 mm. The BNNTs can be, for example, 0.5-2% by volume. The melting of the Al and BNNTs can be done at temperature of, for example, 660-750° C., and this can be done by, for example, melting the Al and BNNTs in a crucible placed inside a furnace operated at the desired temperature. The ultrasonic treatment can include ultrasonically treating the molten Al at a controlled amplitude (e.g., in a range of from 10-30 micrometers (μm)) and/or a controlled frequency (e.g., in a range of from 18-20 kilohertz (kHz)). The ultrasonic treatment can be for a short period of time (e.g., in a range of from 10-120 seconds (s)), and the portion of the probe inserted into the molten Al can have a length of, for example, 4-8 mm.
Embodiments of the subject invention are advantageous in many applications, including but not limited to applications where lightweight and high strength are the main criteria, such as in aerospace and automotive components. The lightweight nature reduces the consumption of fuel, thereby achieving a significant saving of cost. This is an alternative green and cheaper technology for fabricating fuselage and wings of aircraft and chassis of automobiles. The mainframe and body of aerospace vehicles and automobiles constitute a significant part of their total weight. This weight can be reduced by the methods and composites of embodiments of the subject invention. In addition to lower fuel consumption, the lowered weight will also reduce emissions thereby leading to a smaller carbon footprint of these vehicles. Further, composites of embodiments of the subject invention can be sued used in the development of lightweight and robust unmanned air vehicles (UAVs) and ground vehicles for traversing uneven terrains. BNNTs have excellent thermal conductivity, and therefore, BNNT-based composites can be employed in combat tanks for thermal management by effective dissipation of heat in critical components. BNNTs are also known to exhibit radiation absorption properties, so BNNT based-composites, can be used in radiation shields.
No related art technology exists to manufacture an Al matrix composite reinforced with a homogenous distribution of high surface area BNNTs by casting. Thus, embodiments of the subject invention create a new paradigm for metal matrix composite manufacturing. The in situ anchoring achieved by embodiments of the subject invention eliminates the need for material development and decreases cost and time required.
The microstructure evolution in ultrasonic cavitation depends on three critical processing parameters: (i) temperature of the melt; (ii) amplitude of the vibration; and (iii) the time of ultrasonic treatment. The addition of nano-species in the melt introduces major challenges to metal/alloy processing, such as chemical reactivity, physical stability, and agglomeration. Higher ultrasonic treatment time leads to grain refinement, and higher sonication time will also result in superior dispersion and limited agglomeration of nanoparticles. However, longer processing time may also lead to accelerated interfacial reactions between metal (e.g., Al) and nanoparticles. The acoustic waves can also damage/alter the nanoparticle morphology, which will compromise their ability to enhance mechanical properties.
The propagation of ultrasound in the melt results in loss of oscillation energy. The amplitude of the acoustic wave drops exponentially with distance x:
A=Aoe−αx (2)
where α is the attenuation factor and A is the amplitude. Therefore, non-homogeneity in the microstructure is expected, with finer grains in the vicinity of the sonotrode and progressive coarsening of grains away from the sonotrode. Higher amplitude acoustic waves are expected to travel farther before dying.
Higher amplitude of vibration can promote deagglomeration of nanoparticle clusters and reduce the required time duration for sonication, which is desirable for minimizing interfacial reactions. However, high amplitude waves pose the risk of damaging the nanoparticles in the melt.
The sound pressure introduced by the sonotrode must exceed a certain threshold value to initiate cavitation in the melt. The critical radius (Rcr) of the cavitation bubble before its rupture is given as:
where μ is the viscosity of the melt, κ is a polytropic constant, Po is the initial gas pressure, and ρ is the melt density. The critical radius is directly proportional to the melt viscosity. It is well known that the viscosity of molten Al drops as the temperature of the melt increases. Therefore, the higher temperature would result in lower critical radius and hence favorable cavitation in the melt. However, higher temperature poses the challenge of increased interface reactions between Al and nanoparticles.
Table 1 shows example ultrasonic cavitation parameters that can be used in some embodiments of the subject invention.
The method of introducing nanoparticles can influence the microstructure, particularly the quality of dispersion. The injection technique can, in turn, be influenced by the nature of nanoparticle (size, morphology, density) and chemical interactions that take place in the melt (reactivity between the metal and nanoparticles). Two example injection methods that can be used include capsulate feeding and pre-melting introduction. Capsulate feeding includes the nanoparticles being wrapped in foil of the metal used (e.g., Al foil for an Al composite). These metal capsules containing nanoparticles can be injected into to the melt through a tube, and sonication treatment can be employed to disperse the nanoparticles. In pre-melting introduction, the nanoparticles can be mixed with the solid metal pieces/chunks in the crucible. This mixture can then be heated to melt the metal, and sonication treatment can be used to disperse the nanoparticles present in the crucible.
Varying the volume fraction of nanoparticles can have an effect on composite microstructure. Adding excessive nanoparticles can lead to agglomeration in the microstructure, which is difficult to overcome, resulting in deteriorated mechanical properties The nanoparticles can be added at a volume percentage of any of the following values, about any of the following values, at least any of the following values, or at most any of the following values (all values are volume percentage of the composite): 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2, 2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7, 2.8, 2.9, 3, 3.1, 3.2, 3.2, 3.3, 3.4, 3.5, 3.6, 3.7, 3.8, 3.9, 4, 4.1, 4.2, 4.3, 4.4, 4.5, 4.6, 4.7, 4.8, 4.9, 5, 5.5, 6, 6.5, 7, 7.5, 8, 9, or 10.
Ultrasonic cavitation promotes interfacial wetting by stripping off the gaseous species adsorbed on the nanoparticle surface and by forcing the melt into the surface asperities. As a result, these sites filled with molten metal act as active solidification sites. The accelerated wetting of nanoparticles by molten metal can reduce the overall casting time, which can result in arrested interfacial product formation. Cavitation bubbles in the melt act as nucleation sites during solidification. Grain size due to ultrasonic treatment is given by the relation:
where D is the diffusion coefficient of the solute in the melt, zΔTn is the incremental amount of undercooling required to activate the nucleation event ahead of the solidification front, v is the growth rate of the solid-liquid interface, Q is the growth restriction factor, Nv is the number density of the substrate, and A is the ultrasonic amplitude. From Equation (4), it is evident that higher amplitude leads to smaller grain size. The higher volume fraction of nanoparticles (higher Nv) would also result in finer grains, due to more heterogeneous nucleation sites. Therefore, cavitation bubbles and nanoparticles in the melt have a synergistic effect on grain refinement. The mechanism of grain refinement during ultrasonic processing of metal matrix composites is schematically shown in
Cavitation causes the growth of H2 gas bubbles dissolved in the metal melt due to rapid diffusion. These microbubbles then coalesce to form larger bubbles, which can float to the top surface of the melt. The ejection of dissolved gas from the melt results in reduced porosity or denser microstructure. Controlling porosity in the microstructure is important for achieving superior mechanical properties. In turn, porosity in the composite can be a function of ultrasonic processing parameters. The porosity of the composites can be quantified using the Helium Pycnometer and Archimedes Principle.
The quality of nanoparticle (e.g., SiC nanoparticles or BNNTs) dispersion by ultrasonic cavitation technique can be assessed by image analysis and Delaunay triangulation methods. These techniques can also be used for CNT reinforced Al composites. In addition, a standard ASTM index for characterizing the dispersion quality on a relative scale can be computed. In image analysis, a micrograph of the fracture surface with nanoparticles distributed in the Al matrix can be used for evaluating the dispersion quality. This technique involves creating cells in the image and then evaluating the number of particles in each cell (see
where L is the volume fraction of the nanoparticles. This index varies from 0 to 100, where 100 signifies excellent dispersion.
The mechanical properties of nanocomposites are highly sensitive to the microstructure variables, such as dispersion, grain size, and porosity. Therefore, connecting ultrasonic processing variables with mechanical properties is important for engineering nanocomposites with desired performance. Grain refinement due to cavitation as well as the addition of nanoparticle reinforcement can improve the mechanical properties of the composites significantly. Usually, the addition of a ceramic nano-filler to a metal matrix leads to arrested ductility, but ultrasonic casting produces a “non-dendritic” microstructure due to accelerated solidification, contrary to a dendritic microstructure in related art metal casting. The oscillating cavitation bubbles cause fragmentation of growing dendrites. The resultant globular microstructure results in enhanced ductility. Therefore, metal matrix composites processed by ultrasonic cavitation may result in simultaneous enhancement of strength and ductility, which is advantageous and in general would not be expected.
Fiber reinforcement (e.g., nanotubes) within metal composites strengthens the metal by bearing the applied loads. There is stress transfer at the interface due to shear-lag effect. The nanotubes can bear the stress until they fail. BNNTs in particular have extremely high tensile strength (about 61-64 GPa).
A greater understanding of the embodiments of the subject invention and of their many advantages may be had from the following examples, given by way of illustration. The following examples are illustrative of some of the methods, applications, embodiments, and variants of the present invention. They are, of course, not to be considered as limiting the invention. Numerous changes and modifications can be made with respect to the invention.
Materials and Methods
An ultrasonic casting setup was prepared and used to fabricate metal-nanoparticle composites as described herein. A furnace capable of reaching up to 1100° C. was also used. The setup included graphite crucibles and an ultrasonic tool (750 Watts) with a niobium (Nb) probe designed for cavitation. The probe, which is shown in
Al6061 alloy was used for ultrasonic casting to assess the effect of cavitation on the microstructure, density, and hardness. Ultrasonic treatment resulted in grain refinement (32%) as compared to as-cast microstructure (without sonication), as shown in
An Al6061-BNNT composite was synthesized by ultrasonic cavitation. BNNTs were introduced in the melt, wrapped in Al foil. Two such pellets were prepared: one without sonication treatment and one with ultrasonic treatment for 15 seconds at 700° C. at an applied power and amplitude of 700 W and 20 μm, respectively. The solidified pellets were then sectioned from the middle using a low-speed diamond saw. The pellet without sonication treatment revealed a large cluster of BNNTs (
SiC nanoparticles were used as the reinforcement phase in an Al6061 alloy composite. The composite was prepared as in Examples 1 and 2 and showed good dispersion of the SiC nanoparticles.
It should be understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application.
All patents, patent applications, provisional applications, and publications referred to or cited herein are incorporated by reference in their entirety, including all figures and tables, to the extent they are not inconsistent with the explicit teachings of this specification.
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