This is an Accepted Manuscript for the Microscopy and Microanalysis 2020 Proceedings. This version may be subject to change during the production process.
Recently, high entropy alloys (HEA's) have been of great interest to researchers, since they represent a very broad area of study, these alloys are consolidated by different techniques like an arc casting, conventional sintering, plasma sintering and conventional casting [1, 2]. A new alternative consolidation route based in high frequency induction has been proposes in this work, such route will provide the option to consolidate HEA's at low temperature and short time, contributing to avoid the growth of grain in nanocrystalline materials, and allowing control porosity and oxidation. Thus, the aim of this work is evaluate the crystalline structure, microstructure, mechanical properties, porosity and density in samples obtained by new fast low temperature consolidation route in the AlCoCrFeMnNi HEA.The equiatomic AlCoCrFeMnNi powders were obtained by MA. Pure elements (each of them at least 99.9% purity) were used as the raw material. The millings were performed by using a high energy mill Spex 8000. Milling media and container are done by hardened steel. Milling conditions were set to 10 h of milling time, powder mass 8.5 g and a ball-to-powder ratio of 5:1. N-heptane was used as process control agent. To prevent contamination, the balls and vial were coated with nominal composition elemental powders and milling was performed under Ar atmosphere. 2 different routes were used in consolidation process of the powders. The first one was conventional consolidated with the following conditions: the compaction pressure was 1.56 GPa for 10 min, followed by the sintered at 1200ºC for 3 h. The second one was the fast-low temperature consolidation with the following conditions: compacted and pre-sinterized were performed simultaneously under compaction pressure of 0.9 Gpa at 600ºC for 3 min using a high frequency induction furnace, posteriorly a sintered was carried out at 1200ºC for 3 h. the microstructural characterization was carried out by means of a transmission electron microscope JEOL JEM 2200FS+CS and scanning electron microscope HITACHI SU3500. The Vickers microhardness was evaluated in LM300 AT tester. Figure 1 shows Vickers microhardness values and SEM micrographs obtained in the 2 consolidation routes. A reduction of pores-oxides, a best diffusion process of elements and higher microhardness values using the new route proposed in comparison to conventionally sintering are observed. Figure 2 shows the microstructure for samples consolidated by new route, which is composed of 2 phases: the AlNi-rich phase (dark) with FCC structure, and the FeCo-rich phase (clear) with a BCC structure. In addition, aluminum oxide with nanometic size, darkness tonality and homogeneously distributed in matrix is observed. It is concluded that fast low-temperature consolidation route presents a greater homogeneity of phases in the matrix, which contribute to increase microhardness values and decrease of porosity and oxidation.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.