Characterizing Primary Dendritic Microstructures to Quantify the Processing-structure-property Relationship in Single Crystal Nickel Based Superalloys
Tschopp, M. A., Oppedal, A. L., Miller, J. D., Groeber, M. A., Rosenberger, A. H., & Solanki, K.N. (2013). Characterizing Primary Dendritic Microstructures to Quantify the Processing-structure-property Relationship in Single Crystal Nickel Based Superalloys. In Jian-Yang Hwang, Chengguang Bai, John Carpenter, Shadia J. Ikhmayies, Bowen Li, Sergio Neves Montiero, Zhiwei Peng, and Mingming Zhang (Eds.), Characterization of Minerals, Metals, and Materials 2013. San Antonio, TX: TMS (The Minerals, Metals & Materials Society). 299-310.
Characterizing the spacing of primary dendrite arms in directionally-solidified microstructures is an important step for developing process-structure-property relationships by enabling the quantification of (i) the influence of processing on microstructure and (ii) the influence of microstructure on properties. The research objective herein is to evaluate the capability of various conventional approaches, as well as new or modified approaches, for spatial point pattern analysis with application to characterizing experimental dendritic microstructures. Both computer-generated and experimental dendritic microstructures are used for this analysis along with numerous techniques based on the nearest neighbor spacing, Voronoi tessellation, Delaunay triangulation, or graph theory. Comparison of new metrics with traditional primary dendrite arm spacing metrics will also be discussed for both local and global measures. The current methods investigated will supply information of local spacing and coordination number while addressing edge effects, parameter sensitivity, and correlation with interdendritic features, thus providing insight into how processing affects properties.