This application claims priority to U.S. patent application Ser. No. 13/164,495 filed on Jun. 20, 2011, which is incorporated by reference herein.
Magnets may be broadly categorized as temporary or permanent. Temporary (soft) magnets become magnetized or demagnetized as a direct result of the presence or absence of an externally applied magnetic field. Temporary magnets are used, for example, to generate electricity and convert electrical energy into mechanical energy in motors and actuators. Permanent (hard) magnets remain magnetized when they are removed from an external field. Permanent magnets are used in a wide variety of devices including motors, magnetically levitated trains, MRI instruments, and data storage media for computerized devices.
High-performance permanent magnets, such as Sm—Co (HC=10-20 kOe) and Nd—Fe—B (HC=9-17.5 kOe), are generally intermetallic alloys made from rare earth elements and transition metals, such as cobalt. Demand for high-performance permanent magnets for motors is increasing rapidly for applications such as wind turbine generators and motors in electric and hybrid cars. Rare-earth magnets are generally used for such challenging applications with, for example, each Toyota Prius using 1 kg of Nd and a typical wind turbine generator using 250 Kg of Nd. These rare earth magnets have highest energy product (BH)max of any material, where B is magnetic flux density and H is magnetic field strength.
By way of example, Nd2Fe14B has the highest (BH)max at 45 MGOe. However, this material is not without problems. Sintered Nd2Fe14B is vulnerable to grain boundary corrosion, requiring nickel or copper/nickel plating or lacquer coating. Although polymer-bonded Nd2Fe14B magnets do not suffer from this grain boundary corrosion problem, they have a significantly lower energy product due to the polymer matrix.
In another example, Sm—Co magnets have a (BH)max of 28-30 MGOe, which is lower than that of Nd2Fe14B. Although Sm—Co magnets do not suffer from corrosion and can be used at higher temperatures (up to ˜350° C.), they are quite brittle, prone to chipping and can fracture from thermal shock. Further issues with these materials are that over 95% of rare earths are produced in one country and there are no US-owned manufacturers of rare earth magnets. The high cost of rare earth elements and cobalt makes the widespread use of high-performance magnets commercially impractical.
Less expensive magnets are more commonly used, but these magnets generally have lower coercivity HC i.e., their internal magnetization is more susceptible to alteration by nearby fields. For example, ferrites, which are predominantly iron oxides, are the cheapest and most popular magnets, but they have both low HC (1.6-3.4 kOe) and low values of MS. Similarly, Alnico alloys, which contain large amounts of nickel, cobalt and iron and small amounts of aluminum, copper and titanium, have HC in the range of 0.6-2 kOe, which makes exposure to significant demagnetizing fields undesirable.
The ferromagnetic τ phase in a MnAl magnet was first reported by H. Kono, On the Ferromagnetic Phase in Manganese-Aluminum Systems”, Journal of the Physics Society of Japan, 13 (1958) 1444 and Koch et al. “New Material for Permanent Magnets on a Base of Mn and Al”, Journal of Applied Physics, 31 (1960) 75S. This material is not used commercially in bulk form, but continues to attract attention since it has an attractive combination of magnetic properties for technological applications. MnAl magnet has a theoretical energy product, (BH)max, of 12 MGOe together with a relatively low density of 5200 kg/m3, and thus a high density-compensated (BH)max. In contrast, Sm—Co magnets have a relatively high (BH)max, but also a relatively high density of ˜8300 kg/m3. Therefore, the MnAl magnet has a comparable ratio of (BH)max,/density as compared to the Sm—Co magnet. Table 1 lists a comparison of the estimated maximum energy product, density and density-compensated maximum energy product for several classes of permanent magnets.
While the magnetic properties of MnAl magnets are superior to conventional hard ferrites, Alnicos, and Fe—Cr—Co alloys, MnAl is not as good as the rare-earth magnets. τ-MnAl does not suffer from the issues associated with the rare-earth magnets outlined above. Advantages of MnAl magnets include low costs and excellent availability of the Mn and Al materials, good machinability, high specific strength, high modulus of elasticity, and excellent corrosion resistance.
More recently, Mn—Al—(C) alloys have been produced by mechanical alloying processes. D. C. Crew, P. G. McCormick and R. Street, Scripta Metall. Mater., 32(3), p. 315, (1995) and T. Saito, J. Appl. Phys., 93(10), p. 8686, (2003) have shown that adding small amounts of carbon (e.g., about 2 atomic % or less) to certain Mn—Al alloys stabilizes the metastable τ phase and improves magnetic properties and ductility. Crew et al. (1995) produced Mn70Al30 weight % and Mn70.7Al28.2C1.1 weight % alloys by consolidating ball milled powders, annealing at 1050° C. and then quenching, after which the materials were no longer nanocrystalline. The resulting alloys had grain sizes of about 300-500 nm and exhibited coercivities, HC, of 1.4 kOe and 3.4 kOe, respectively. Saito (2003), produced mechanically alloyed Mn70Al30 weight % and Mn70Al29.5C0.5 weight % alloys that had grain sizes of about 40-60 nm and coercivities of 250 Oe and 3.3 kOe, respectively. In this study, the low coercivities reflected the limited formation of the magnetic τ phase, which was determined to be 10% in Mn70Al30 and 40% in Mn70Al29.5C0.5. K. Kim, K. Sumiyama and K. Suzuki, J. Alloys Comp., 217, p. 48, (1995), produced MnAl alloys that were ball milled, but never annealed. The alloys displayed no hard magnetic properties with HC of 130 Oe.
Mechanical milling (MM) has been used to synthesize a number of rare earth permanent magnet alloys, including Nd2Fe14B, Nd(Fe,Mo)12Nx and SmCo5. This processing technique may be used to produce a nanocrystalline microstructure having beneficial effects on the magnetic properties. So far, only a few studies have dealt with the magnetic behavior of MM Mn—Al. In one study by Satio, “Magnetic Properties of Mn—Al System Alloys Produced by Mechanical Alloying”, Journal of Applied Physics, 93 (2003) 8686, a relatively high HC of 3.3 kOe was obtained, but the maximum MS was only 20 emu/g. The same author Satio studied MM MnAl—C and obtained Br=60 emu/g and HC=1.95 kOe, see “Magnetic Properties of Mn—Al—C Alloy Powders Produced by Mechanical Grinding”, Journal of Applied Physics, 97 (2005) 1. Commercial products with magnetic properties of Br=5.75 kG, HC=3.0 kOe and (BH)max=7 MGOe are made by hot extrusion of annealed gas-atomized Mn—Al—C powders by Sanyo Special Steel Co. Ltd., which has been working on MnAl—C alloys for many years. These Mn—Al alloys are made from relatively inexpensive materials, but the low coercivities remain a problem.
The subject matter of the present disclosure advances the art and overcomes the problems outlined above by providing nanostructured Mn—Al alloys and a method for their manufacture. Constituents of these alloys may be mechanically milled and heat-treated to form permanent room temperature magnets with high coercivities and relatively high saturation magnetization values.
In an embodiment, a bulky consolidated nanostructured manganese aluminum alloy includes at least about 80% of a magnetic τ phase and having a macroscopic composition of MnXAlYDoZ, where Do is a dopant, X ranges from 52-58 atomic %, Y ranges from 42-48 atomic %, and Z ranges from 0 to 3 atomic %. In a particular embodiment, the manganese aluminum alloy includes carbon having a macroscopic composition of 51 atomic % manganese, 46 atomic % aluminum and 3 atomic % carbon and has coercive forces of about 5.2 kOe. In another particular embodiment, the manganese aluminum alloy has a macroscopic composition of 54 atomic % manganese, 46 atomic % aluminum and coercive forces of about 4.8 kOe. In an embodiment, a method for producing a bulky nanocrystalline solid is provided. The method includes melting a mixture of metals comprising between 52-58 atomic % manganese and between 42-48 atomic % aluminum to form a substantially homogenous solution. The method also includes casting the solution to form ingots, measuring compositions of the ingots, crushing the ingots to form crushed powders, and milling the crushed powders to form nanocrystalline powders. The method also includes verifying the presence of τ phase and determining the amount of the τ phase. The method further includes simultaneously consolidating the nanocrystalline powders into a bulky nanocrystalline solid and undergoing phase transformation from ε phase to at least 80% τ phase, β and γ2 phases.
In a particular embodiment, the method further includes characterizing microstructure of the bulky nanocrystalline solid and measuring magnetic properties of the bulky nanocrystalline solid. The method further includes annealing the nanocrystalline powders to determine conditions for consolidating the nanocrystalline powders. The method further includes annealing at temperatures between 200° C. and 600° C. to maximize the amount of the magnetic metastable τ phase transformed from a milled nanocrystalline unstable high-temperature ε phase, thereby minimizing the presence of non-magnetic equilibrium β and γ2 phases. The annealing time is shorter for higher annealing temperature to avoid decomposition of the τ-phase into the γ2 and β phases. The step of consolidating the milled powders includes backpressure assisted Equal channel angular extrusion (ECAE). The method further includes increasing backpressure to consolidate the nanocrystalline powders. The method further includes controlling a temperature of the nanocrystalline powders within 200° C. to 600° C. during the ECAE. The method also includes decreasing rate of extrusion with increasing temperature to shorten annealing time at higher temperature to avoid decomposition of the τ-phase into the γ2 and β phases.
In a particular embodiment, the bulky nanocrystalline solid is in a form of rod shapes. The bulky nanocrystalline solid has a cross-section in one of square, rectangular, and circular shape. The method further includes repeating the step of consolidating the nanocrystalline powders until the bulky nanocrystalline solid having minimum defects. The bulky nanocrystalline solid is machinable. The mixture of metals includes a dopant comprising at least one of carbon and boron. The mixture of metals has 54 atomic % manganese, and 46 atomic % aluminum. The mixture of metals includes 51 atomic % manganese, 46 atomic % aluminum and 3 atomic % carbon.
The benefits of the nanostructured Mn—Al and Mn—Al—C permanent magnets include high coercivities (˜4.8 kOe and 5.2 kOe, respectively) and high saturation magnetization values. The benefits of the magnets also include relatively low cost and readily available raw material supplies compared to rare earth magnets.
Methods for producing mechanically milled, nanostructured Mn—Al and Mn—Al—C alloys will now be shown and described. High room temperature coercivities and saturation magnetization values have been achieved for Mn—Al alloys that are produced by the presently described methods, and it has been shown that the addition of small amounts of carbon dopant (e.g., about 3 atomic % or less) to Mn—Al alloys stabilizes the metastable τ phase and improves magnetic properties.
Mechanically milled Mn—Al alloys possessing a nanostructured ferromagnetic τ phase, with HC=4.8 kOe and MS=87 emu/g at room temperature, were obtained by annealing Mn54Al46 powders at 400° C. for 10 minutes. The coercivity value of this alloy is the highest ever reported for Mn—Al materials. The amount of magnetic phase present in the annealed product is estimated from the saturation magnetization to be about 80% on the basis that MS of the pure τ phase is about 110 emu/g. In another embodiment, a Mn—Al—C alloy, Mn51Al46C3, prepared by the same method displayed a coercivity that is the highest ever reported for Mn—Al—C materials, HC=5.2 kOe.
The macroscopic formulas presented herein, e.g., Mn54Al46, pertain to the overall composition, but the materials have nanostructure or microstructure of localized phase variation (e.g., γ, β, and/or τ phases). As used herein, a “nanostructured” material is a bulk solid characterized by localized variation in composition and/or structure such that the localized variation contributes to the overall properties of the bulk material.
The large coercive forces observed are believed to result from small grains of the magnetic τ phase (˜30 nm) being magnetically isolated from one another. This lack of magnetic exchange coupling may result from non-magnetic phases (e.g., β, γ) inhibiting changes in the alloy's internal magnetization when an external magnetic field is applied (i.e., the non-magnetic phase(s) act as magnetic domain wall pinning sites).
The alloys disclosed herein are resistant to corrosion and may, for example, be used in applications currently utilizing known permanent magnets. In one embodiment, small particles or powders of the alloys may be produced in a resin or plastic bonded form according to known methods. The small grain size of the alloys may provide improved ductility relative to materials with larger grains.
Mn54Al46 alloy ingots were prepared by arc-melting stoichiometrically balanced quantities of Mn and Al in a water-cooled copper mold (Tm≈1250-1350° C.). The melted metallic solution was then heated until melted. Quenching was performed by allowing the alloy to rapidly cool in the copper mold to a temperature of ˜30° C. in approximately 10 minutes. Ingots were flipped and melted a minimum of three times under argon to ensure mixing. Ingots were subsequently heated to and held at 1150° C. for 20 hours followed by water quenching to retain the ε phase. The ingots were then crushed and milled for eight hours in a hardened steel vial using a SPEX 8000 mill containing hardened steels balls with a ball-to-charge weight ratio of 10:1. The vials were sealed under argon to limit oxidation. Both the as-milled powders and the quenched bulk samples were annealed at temperatures from 350-600° C. for 10-30 minutes to produce the ferromagnetic τ phase.
The magnetic properties were measured at a room temperature of about 20° C. using a LakeShore 7300 vibrating sample magnetometer (VSM) under an external magnetic induction field of 15 kOe. Some samples were also measured with an Oxford superconducting quantum interference device (SQUID) magnetometer under a field of 50 kOe. Accuracy of the magnetic measurements is within ±2%. Therefore, magnetic data may be reported as “about” a particular value to account for ubiquitous sources of error (e.g., magnetic fields within or near the magnetometer and errors associated with weighing samples). Microstructural characterization was performed using a Siemens D5000 diffractometer with a Cu X-ray tube and a KeVex solid state detector set to record only Cu Kα X-rays.
These results show that the improved magnetic performance may be related to small grain sizes, where the nanostructured ε phase material is transformed to the ferromagnetic τ phase at anneal conditions characterized by the 400° C. anneal which produced the results of
δM=Md(H)−[Mr(Hsat)−2Mr(H)] Equation(1)
where Md (H) is the demagnetic remanent magnetization, Mr is remanent magnetization, and Hsat is magnetic field strength that saturates the magnet.
A plot of δM versus H therefore gives a curve characteristic of the interactions present. The overall negative and small δM for the mechanically milled sample indicates that most of the τ phase nanograins are isolated with only small dipolar interactions between them. No exchange coupling exists in this nanostructured material, which explains why the remanence ratio is close to 0.5.
The manufacturing process of Example 1 was repeated by varying the content of the Mn and Al metals, and doping with carbon.
MnXAlYDoZ,
The disclosure presents methods for producing nanocrystalline τ-phase MnAl with a coercivity, HC, of 4.8 kOe, and a saturation magnetization, MS, of 87 emu/g by mechanically-milling powders of the unstable, high-temperature s-phase until they were nanocrystalline and then annealing the milled powders. These values are the highest reported for Mn—Al based powders (bulk magnets have MS of 110 emu/g). Good magnetic properties resulted from producing the nanocrystalline ε-phase first and then transforming the s-phase into the i-phase rather than producing the τ-phase and then milling i-phase to produce nanocrystalline material as conventionally undertaken. The origin of the high HC may be the nanostructure and/or the presence of small amounts of the equilibrium γ2 and β phases, which could pin the magnetic domain walls.
While this improvement in magnetic properties is exciting, the powders should be consolidated while retaining their good magnetic properties in order for the material to be of practical value. The heat treatment to which the milled ε-phase powders have to subject in order to produce the superior magnetic behavior provides a processing window to allow the warm consolidation of the powders. This disclosure presents methods for consolidating nanocrystalline MnAl powders into a fully dense solid while producing the superior magnetic properties that can be obtained in the powders.
The present disclosure further includes methods of producing anisotropic magnets by warm extrusion, determination of the origin of the high HC so that the heat treatment and composition of the powders can be optimized to develop even better magnetic properties. The milled nanocrystalline ε-phase powders, with this heating, simultaneously consolidate to form a bulky solid and undergo the necessary phase transformations to form the required microstructure.
Equal channel angular extrusion (ECAE) is a powder consolidation technique to consolidate microcrystalline powders by Kim et al, “Equal Channel Pressing of Metallic Powders”, Materials Science Forum, 437-438 (2003) 89 and Xiang et al, “Microstructure and mechanical properties of PM 2024Al-3Fe-5Ni alloy consolidated by a new process, equal channel angular pressing”, Journal of Materials Science Letters, 16 (1997) 1725. Further, the use of backpressure has been reported to be effective in aiding the compaction of Mg alloy powders and shavings to full density by Lapovok, “The positive role of back-pressure in equal channel angular extrusion”, Materials Science Forum, 503-504 (2006) 37.
ECAE was used to consolidate commercial Al powders, eutectic Al—Si powders, unalloyed Mg powders and nanocrystalline Al powders. The powders were cold-compacted into annealed copper cans, onto which lids were pressed. Then, the cans were extruded at about 200° C. through a well-lubricated hardened-steel ECAE jig. A key to successful consolidation was to have a brass plug in front of the copper can to provide backpressure during extrusion. Extrusion without the plug led to poor powder consolidation, particularly for the milled Al.
An important feature of the consolidation of the mechanically-milled Al powder is that the nanocrystalline grain size of 55 nm produced by mechanical milling only marginally increased during the ECAE extrusion to a grain size of 63 nm (see
ECAE was also used to consolidate Mg-alloys without using a can, i.e. the powder is loaded directly into the jig, reported by Baker et al, “Containerless Consolidation of Mg Powders using ECAE”, Materials and Manufacturing Processes, 25(12) (2010) 1381-1384, which is incorporated by reference herein. Commercial Mg can be consolidated to full density after two passes through the ECAE jig at 200° C.
ECAE can also be used to consolidate MnAl powders to form a bulky MnAl solid in a way similar to consolidation of Mg powders or Al powders. Extrusion may be performed at relatively lower temperatures than is the case with conventional hot extrusion, in order to avoid allowing the ε phase to fully transform to the equilibrium β and γ2 phases during consolidation. The temperature is a compromise between being as low as possible to prevent significant grain growth and high enough to allow powder consolidation. Variation in ECAE for consolidating MnAl powders may include temperatures at which extrusion occur, the powders are consolidated with and without a can, with a plug to provide backpressure etc.
It should be noted that the nanocrystalline powders are simultaneously consolidated and undergo the necessary phase transformations from ε phase to magnetic phase and non-magnetic β and γ2 phases to form the required microstructure. The magnetic ti phase is at least 80%. The coercivity HC of the bulky nanocrystalline solid remains substantially unchanged from the nanocrystalline powders. Specifically, MnAl bulky nanocrystalline solid can have a HC of 5.2 kOe for 51 atomic % manganese, 46 atomic % aluminum and 3 atomic % carbon, and a HC of 4.8 kOe for 54 atomic % manganese, 46 atomic % aluminum.
The relevant MnAl phase transformations simultaneously consolidate nanocrystalline ε-MnAl phase powders and transform them to the magnetic τ-MnAl phase. Understanding the origin of the high HC in nanocrystalline τ-MnAl phase assists processing and composition of the powders to optimize magnetic properties. A working hypothesis is that it is the nanoscale distribution of the non-magnetic β and γ2 phases that produces the high HC, via domain-wall pinning, in nanostructured τ-MnAl magnets.
At step 1802, casted ingots are produced from as-received mixtures in the form of powders, flakes, pellets, ribbons or the like (˜100 g) of several compositions of Mn—Al near the Mn54Al46 composition with or without carbon. The as-received mixtures are arc melted and cast into a chilled copper mold to form an ingot. Melting and casting each ingot three times and flipping the ingot over in between may improve the homogeneity. Since Mn has a low vapor pressure and can easily be lost during melting, the compositions of the alloys is measured at step 1804, including the oxygen and carbon content, after melting using a wet chemistry approach. Typically, excess Mn is added to the starting materials to compensate for any losses of Mn. The ingot contains ε-MnAl.
At step 1806, the ingot is crushed into powders to prepare for mechanical mill. The crushed powders have relatively large grain sizes in the range of microns. Mechanical mill reduces the grain sizes of the crushed powders to nanometer ranges, while the s-phase of the MnAl alloy remains unchanged during crushing and mechanical milling.
At step 1808, nanocrystalline powders are produced by mechanically milling the crushed powders using a water-cooled Union Process Szegvari attritor. Typically a rotation speed of approximately 700 rpm is used with hardened steel balls for 30-40 hrs under an argon atmosphere. 50-100 g of powders are milled, with a ball-to-powder ratio of 10:1. A SPEX mill may be used to more rapidly (˜8 h) produce nanocrystalline material than the attritor, but only around 5 g of material are produced and more contamination of the powder tends to occur with the SPEX. The milled powders are now nanocrystalline ε-MnAl powders.
An understanding of the kinetics of the transformation may inform about the conditions to use for the consolidation of the nanocrystalline powders. It is much easier to run many different anneals on the powders and to determine the phases present and the magnetic properties than to have many consolidation runs and determine microstructure and magnetic properties.
Nanocrystalline ε-MnAl powders may be optionally annealed at different temperatures and times to determine the optimum processing conditions for the best magnetic properties at step 1810. The step 1810 is bounded in dashed lines to indicate that this is an optional step. The starting point for the heat treatments is a 30 min anneal at 400° C. in a particular embodiment. However, powders may be annealed for very short time at higher temperature and for longer time at lower temperature. Powders may also go through two-step anneals of different times at different temperatures. Annealing temperature may be from 200° C. to 600° C. These anneals intend to maximize the amount of the magnetic metastable τ phase transformed from the as-milled, nanocrystalline unstable high-temperature ε phase, thereby minimizing the amounts of the non-magnetic equilibrium β and γ2 phases present. If it is the nanoscale distribution of the non-magnetic β and γ2 phases that produces the high HC in MnAl, via domain-wall pinning, a small amount of finely distributed β and γ2 has also to be present.
At step 1812, the nanocrystalline ε-MnAl powders are consolidated into a bulky nanocrystalline solid, which includes at least 80̂% of τ phase and presence of β and γ2 phases. The solid may be in a shape of rod. The rod may have a cross-section in any shape including square, rectangular, circular, etc. It will be appreciated by those skilled in the art that the shape and dimension may vary for the nanocrystalline solid.
For consolidation of nanocrystalline powders, the ECAE system includes the ECAE jig, cartridge heaters with thermocouple feedback to control the temperature, and forward and backpressure pistons. A variety of temperatures are used, based on the powder annealing results outlined above, in order to consolidate the powder. Higher backpressure is generally better for powder consolidation. The powders may be consolidated in one pass or two or more passes if a previous pass is unsuccessful. The consolidated bulky nanocrystalline solid should have minimum defects or substantially free of defects.
It is noted that the ECAE jig produced billets that are about 15 mm diameter and 40 mm long. In principle, ECAE processing can simply be scaled up using a larger jig and a larger extrusion piston system, similar to a traditional direct extrusion set up. In reality, the scale up probably requires lower pressures that simply scale with the size of the billet. The reason for this is that in small specimens the surface frictional forces in the billet have a larger effect in small diameter specimens than large diameter specimens due to the larger surface-to-volume ratio.
At step 1816, the annealed powders may be optionally characterized for their microstructure and magnetic properties. The step 1816 is bounded in dash lines to indicate that this is an optional step. The size and morphology of the unmilled, milled and annealed powders are determined using secondary electron imaging in a field emission gun (FEG) XL30™ scanning electron microscope by FEI company. The phases present in each of these annealed powders are determined using a computer-controlled Riagku DMax rotating anode X-ray diffractometer with a Cu target. The average grain size (and lattice strain) are calculated from the corrected full width at half maximum of each diffracted peak, βsample, for the powders using a Hall-Williamson method:
Where k is Scherrer constant, δ is the grain size, λ is the wavelength, ε is the internal strain introduce by milling, and θ is the Bragg angle. βsample is obtained from βsample2=βmeasured2−βinstrument2, where βinstrument and βmeasured are the Full Width Half Maximums (FWHM) of a well-annealed and a milled specimen, respectively.
At step 1814, the bulky MnAl solid is characterized for its microstructure and magnetic properties. For microstructural characterization of extruded bulky MnAl solid, a FEI Tecnai F2 FEG 200 keV transmission electron microscope (TEM) is used. Energy dispersive X-ray microanalysis (EDS) and convergent beam electron diffraction (CBED) are performed using this instrument. Several microstructural features are analyzed to determine the crystal structures of the phases present using CBED, including whether any ε-MnAl is left over after the processing. The chemistry of the phases are measured using EDS. The grain size of the τ-MnAl phase is determined using bright field imaging. The sizes of the β and γ2 particles are determined using dark field imaging. The distribution of the β and γ2 particles, i.e. whether they are homogeneously distributed, lie on the τ-MnAl grain boundaries or lie in lines along the extrusion direction, are determined using dark field imaging. The orientation relationships between the τ-MnAl matrix and the β and γ2 particles are determined. The coherency of the β and γ2 particles with the τ-MnAl matrix are determined. The dislocation density in the τ-MnAl matrix are determined using a standard point line-intersection counting method coupled with measurements of the foil thickness using the standard two-beam CBED technique. The Burgers vectors of the dislocations are determined using tilting experiments and the standard g·b=0 (where g is the diffraction vector and b is the dislocation Burgers vector) invisibility criterion.
When the phases present are small, such as within a few nanometers, EDS may not be very useful for determining their chemistry. In this case, a Cameca Local electrode atom probe (LEAP) located at Oak Ridge National Laboratory (ORNL) is used. In the LEAP, a high electric field is applied to a sharp needle-shaped specimen, held in a high vacuum, to strip individual atoms from the specimen atom layer by atom layer over thousands of layers and identify them—including their location—by time-of-flight mass spectrometry. The LEAP is somewhat complementary to the TEM since it does not provide diffraction data.
Fine precipitates can be identified by using atom probe tomography (API). The compositions of fine particles can be determined using the APT. The extruded MnAl alloy may have a texture. Thus, the grain orientations and grain misorientations are determined using electron backscatter patterns (EBSPs) using the FEI FEG XL30 SEM.
For magnetic measurements, the quasi-static magnetic behavior of the powders and consolidated MnAl may be measured using a Lakeshore Instruments 7300 VSM that can apply fields up to 15 kOe. This field strength cannot saturate the alloys, thus the MS will be determined by extrapolation of H2→0, from a plot of the saturation law M=MS (1−a/H2). The warm extrusion via ECAE may produce anisotropic magnets which have improved magnetic properties compared to isotropic magnets.
To interpret the measurements, a key question is whether the τ-phase has to be nanocrystalline to get the superior magnetic properties as seen in annealed powders, or whether it is sufficient to have the equilibrium β and γ2 phases distributed on the nanoscale if these β and γ2 phases are the cause of domain wall pinning and, hence, the high HC. Extruding the nanocrystalline powders at different temperatures may lead to a wide variety of microstructures, i.e. different τ grain structures and different distributions of the non-magnetic equilibrium β and γ2 phases. From analyzing these microstructures and correlating them with the measured magnetic properties, processing of the material can be improved and better compositions can be determined.
It is known that Mn metal is ordinarily antiferromagnetic. By increasing the atomic distance between Mn atoms to 2.96 Å or more, the element becomes ferromagnetic. The ferromagnetism of the τ-phase in MnAl occurs because the magnetic moments of Mn atoms in 0, 0, 0 sites are parallel to one another (see
Although various mechanisms have been proposed for τ-phase formation, the generally accepted one is that the high-temperature non-magnetic ε-phase (h.c.p.) transforms into a non-magnetic ε′-phase (orthorhombic) by an ordering reaction, and then transforms into a ferromagnetic τ-phase by a martensitic phase transition, i.e. ε→ε′→τ. However, the transformation from ε to τ may also involve diffusion, and a nucleation and growth process or a massive transformation, as suggested by recent electron microscopy observations and kinetic analysis. The high density of lattice defects within the τ-phase that develops during the phase transformation is attributed to growth faults produced during atomic attachment at the migrating interface. Practically, the tetragonal τ phase, which is metastable, is usually produced either by a rapid quenching of the high temperature ε phase followed by isothermal annealing between 400° C. and 700° C., or by cooling the ε phase at a rate of ˜10° C./min. Prolonged annealing and elevated temperatures result in decomposition of the τ phase into the equilibrium cubic γ2 and β phases (see
In order to stabilize the τ-phase, carbon has been introduced into Mn—Al. Carbon reduces the Curie temperature TC, and the magnetic anisotropy field, but increases MS with a larger resultant Mn moment. It should be pointed out that Mn—Al—C magnets have a very low Curie temperature TC of ˜290-300° C., compared with ˜700-800° C. for Alnico and ˜450° C. for ferrite. The workability is also improved due to the small C atoms that relieve internal lattice stresses. In Mn53.6Al44.6 alloys, the best magnetic properties were obtained for a carbon content just above the solubility limit of carbon atoms (1.7 atomic %) because of the formation of non-magnetic Mn3AlC precipitates. The magnetic hysteresis behavior of Mn—Al—C is extremely sensitive to the microstructure and defects introduced during the formation of the τ phase within the high temperature ε phase. So far, useful permanent magnets have been obtained only by doping the alloy with carbon and extruding them. Anisotropic Mn—Al—C magnets have been produced by subjecting the ternary alloys to warm extrusion. The properties of the extruded material are a result of the high anisotropy, grain size reduction and carbide precipitations.
It is desirable that the resulting bulk material is able to be machined for engineering applications. In order to determine the utility of the material for this purpose and determine its structural integrity, tensile tests may be performed at 1×10−4 s−1 in air on specimens from the ECAE-processed rods after different extrusions to determine their yield strengths and elongation at room temperature. The fracture surfaces may be examined in the SEM. Their behavior will be compared to that of the non-nanocrystalline MnAl. Additionally, correlating the magnetic properties and phase transformations with the microstructure via modeling help understand the magnetic behavior and further refine the processing and alloy compositions. Modeling that relates the observed phases to the temperature and time at temperature as well as the extrusion pressures may be used to guide the processing to obtain the optimum conditions. Software Thermo-Calc and DICTRA may be used to model the phase transformations.
The above description of the specific embodiments may be modified and/or adapted for various applications or uses that do not depart from the general scope hereof. Therefore, such adaptations and modifications should and are intended to be comprehended within the meaning and range of equivalents of the disclosed embodiments. It is to be understood that the phraseology or terminology employed herein is for the purpose of description and not limitation.
This specification contains numerous citations to references such as patents, patent applications, and publications. Each is hereby incorporated by reference.
Number | Date | Country | Kind |
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10251200.1 | Jul 2010 | EP | regional |
This invention was made with government support under contract number 60NANB2D0120 awarded by the National Institute of Standards and Technology (NIST). The government has certain rights in the invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2012/029812 | 3/20/2012 | WO | 00 | 4/15/2016 |
Number | Date | Country | |
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Parent | 13165595 | Jun 2011 | US |
Child | 14128163 | US |