Hostname: page-component-586b7cd67f-2plfb Total loading time: 0 Render date: 2024-11-28T02:01:40.187Z Has data issue: false hasContentIssue false

Determining Compositional Variation in Silicon–Metal Alloys by Parsing SEM/EDS Hyperspectral Images

Published online by Cambridge University Press:  07 May 2021

Jeremy M. Beebe*
Affiliation:
Analytical Sciences, The Dow Chemical Company, Midland, MI48611, USA
Matthew A. Gave
Affiliation:
Analytical Sciences, The Dow Chemical Company, Midland, MI48611, USA Dow Performance Silicones, Midland, MI48686, USA
Joseph R. Sootsman
Affiliation:
Dow Performance Silicones, Midland, MI48686, USA
Alitha A. Klele
Affiliation:
Dow Performance Silicones, Midland, MI48686, USA
James R. Young
Affiliation:
Dow Performance Silicones, Midland, MI48686, USA
Vasgen A. Shamamian
Affiliation:
Dow Performance Silicones, Midland, MI48686, USA
*
*Author for correspondence: Jeremy Beebe, E-mail: [email protected]
Get access

Abstract

High-temperature differential scanning calorimetry was used to understand the thermal properties of Si-rich metal–silicon alloys. Insoluble metals (A and B) were found to produce an alloy with discrete ASi2 and BSi2 dispersed phases. In contrast, metals that form a solid solution result in a dispersed phase that has a composition of AxB1−xSi2, where x varies continuously across each inclusion. This complex composition distribution is putatively caused by differences in the solidification temperatures of ASi2 versus BSi2. Though this behavior was observed for several different combinations of metals, we focus here specifically on the Cr/V/Si system. To better understand the range and most probable element concentrations in the dispersed silicide domains, a method was devised to generate histograms of their Cr and V concentrations from energy-dispersive X-ray spectroscopy hyperspectral images. Varying the Cr/V/Si ratio was found to change the shape of the element histograms, indicating that the distribution of silicide compositions that form is controlled by the input composition. Adding aluminum was found to result in dispersed phases that had a single composition rather than a range of Cr and V concentrations. This demonstrates that aluminum can be an effective additive for altering solidification kinetics in silicon alloys.

Type
Materials Science Applications
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of the Microscopy Society of America

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

Current address: SK Siltron, Auburn, MI 48611, USA

Current address: Hemlock Semiconductor Corporation, Hemlock, MI 48626, USA

References

Allbee, A, Bauer, Z, Beebe, J, Gave, M, Shamamian, V, Siegel, R, Sootsman, J & Young, J (2013). Containment of molten materials having silicon. US Application 20150050183 A1.Google Scholar
Bauer, Z, Beebe, J, Gave, M, Roehl, D, Shamamian, V, Siegel, R, Sootsman, J & Young, J (2014). Silicon eutectic alloy composition and method of making by rotational casting. US Application 20140290804 A1.Google Scholar
Buonassisi, T, Heuer, M, Istratov, AA, Pickett, MD, Marcus, MA, Lai, B, Cai, Z, Heald, SM & Weber, ER (2007). Transition metal co-precipitation mechanisms in silicon. Acta Mater 55(18), 61196126.CrossRefGoogle Scholar
Chaia, N, David, N, Fiorani, JM, Mathieu, S & Vilasi, M (2015). Thermodynamic modeling of the V-Cr-Si system. Calphad 48, 166174.CrossRefGoogle Scholar
Curtis, JM, Shamamian, VA, Toepke, MW, Nyutu, EK & Sootsman, J (2015). Ternary silicon-chromium eutectic alloys having molybdenum, copper or silver. WO Application 2015168500 A1.Google Scholar
Di Giovanni, MT, de Menezes, JTO, Cerri, E & Castrodeza, EM (2020). Influence of microstructure and porosity on the fracture toughness of Al-Si-Mg alloy. J Mater Res Tech 9, 12861295.CrossRefGoogle Scholar
Fischer, DS (2010). Development of in-situ toughened silicon-rich alloys: a new class of castable engineering ceramics. PhD thesis. MIT, Cambridge.Google Scholar
Fischer, DS & Schuh, CA (2011). Microstructure and fracture of anomalous eutectic silicon-disilicide composites. Intermetallics 19(11), 16611673.CrossRefGoogle Scholar
Forwald, KR & Arnberg, L (2001). Microstructural development in rapidly solidified silicon-rich alloys. Mat Sci Eng A 304–306, 125128.CrossRefGoogle Scholar
Gokhale, AB & Abbaschian, GJ (1987). The Cr-Si (chromium-silicon) system. JPE 8, 474484.CrossRefGoogle Scholar
Goto, T & Tu, R (2019). Eutectic ceramic composites by melt-solidification. J Korean Ceram Soc 56, 331339.CrossRefGoogle Scholar
Grosse, RL, Roehl, DW, Shamamian, VA, Young, JR, Sootsman, JR, Gave, M, Cramton, J & Tulloch, W (2015). Decorative shape-cast articles made from silicon eutectic alloys, and methods for producing the same. WO Application 2015195538 A1.Google Scholar
Hafiz, MF & Kobayashi, T (1996). Fracture toughness of eutectic Al-Si casting alloy of different microstructural features. J Mater Sci 31, 61956200.CrossRefGoogle Scholar
Hume-Rothery, W (1962). Atomic Theory for Students of Metallurgy. London: Institute of Metals.Google Scholar
Kong, B, Jia, L, Zhang, H, Sha, J, Shi, S & Kai, G (2016). Microstructure, mechanical properties and fracture behavior of Nb with minor Si addition. Int J Refract Met Hard Mater 58, 8491.CrossRefGoogle Scholar
Larsen, RT, Nyutu, EK, Shamamian, V, Sootsman, J & Young, J (2014). Industrial component comprising a silicon eutectic alloy and method of making the component. US Application 20140291567 A1.Google Scholar
Liu, W, Fu, Y & Sha, J (2013). Microstructure and mechanical properties of Nb-Si alloys fabricated by spark plasma sintering. Prog Nat Sci 23, 5563.CrossRefGoogle Scholar
Meyers, MA & Chawla, KK (2009). Mechanical Behavior of Materials, 2nd ed. New York, NY: Cambridge University Press.Google Scholar
Okamoto, H (2005). Ta-V (tantalum-vanadium). J Phase Equilib Diffus 26, 298299.CrossRefGoogle Scholar
Ravi, C, Panigrahi, BK, Valsakumar, MC & van de Walle, A (2012). First-principles calculation of phase equilibrium of V-Nb, V-Ta, and Nb-Ta alloys. Phys Rev B 85, 054202.CrossRefGoogle Scholar
Saha, RL, Nandy, TK, Misra, RDK & Jacob, KT (1991). Microstructural changes induced by ternary additions in a hypo-eutectic titanium-silicon alloy. J Mater Sci 26, 26372644.CrossRefGoogle Scholar
Schlesinger, ME (1994). The Si-Ta (silicon-tantalum) system. JPE 15, 9095.CrossRefGoogle Scholar
Schlesinger, ME, Okamoto, H, Gokhale, AB & Abbaschian, R (1993). The Nb-Si (niobium-silicon) system. JPE 14, 502509.CrossRefGoogle Scholar
Shao, G (2005). Thermodynamic modelling of the Cr-Nb-Si system. Intermetallics 13, 6978.CrossRefGoogle Scholar
Smith, JF (1981). The Si-V (silicon-vanadium) system. Bull Alloy Phase Diagrams 2, 4248.CrossRefGoogle Scholar
Smith, JF (1983). Nb-V phase diagram. Bull Alloy Phase Diagrams 4, 361362.CrossRefGoogle Scholar
Smith, JF, Bailey, DM & Carlson, ON (1982). The Cr-V (chromium-vanadium) system. JPE 2, 469473.CrossRefGoogle Scholar
Venkatraman, M & Neumann, JP (1986). The Cr-Nb (chromium-niobium) system. Bull Alloy Phase Diagrams 7, 462466.CrossRefGoogle Scholar
Venkatraman, M & Neumann, JP (1987). The Cr-Ta (chromium-tantalum) system. JPE 8, 112116.CrossRefGoogle Scholar
Wierzbińska, M & Sieniawski, J (2006). Effect of morphology of eutectic silicon crystals on mechanical properties and cleavage fracture toughness of AlSi5Cu1 alloy. J Achiev Mater Manuf Eng 14, 3136.Google Scholar
Zelenin, LP, Radovskii, IZ, Sidorenko, FA, Gel'd, PV & Rabinovich, BS (1966). Structural characteristics of solid solutions of chromium disilicide with vanadium and titanium disilicides. Sov Powder Metall Met Ceram 5, 896900.CrossRefGoogle Scholar
Zhou, Z, Li, Z, Wang, X, Liu, Y, Wu, Y, Zhao, M & Yin, F (2014). 700°C isothermal section of Al-Cr-Si ternary phase diagram. Thermochim Acta 577, 5965.CrossRefGoogle Scholar