Thermo-History-Dependent Copper Enrichment During High-Temperature Oxidation of Recycled Steels.
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| Title: | Thermo-History-Dependent Copper Enrichment During High-Temperature Oxidation of Recycled Steels. |
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| Authors: | Huang, Yuhe1,2 (AUTHOR), Yang, Fangbo1,2 (AUTHOR), Lu, Jun1,2 (AUTHOR), Wang, Shuize1,2 (AUTHOR), Mao, Xinping1,2 (AUTHOR) |
| Source: | Materials (1996-1944). Feb2026, Vol. 19 Issue 3, p595. 15p. |
| Subjects: | Copper, Hot rolling, Steel wastes, Heat treatment, Steel manufacture, Copper surfaces, Oxidation |
| Abstract: | The utilization of recycled steel is essential for achieving carbon neutrality and sustainable engineering, yet repeated recycling inevitably leads to the accumulation of residual elements that are difficult to remove during conventional refining. Among them, copper (Cu) readily enriches in scrap-based steels and is a primary cause of surface hot shortness during high-temperature processing due to its segregation at the oxide/steel interface. While the compositional effects of Cu have been extensively studied, the influence of thermo-history associated with different industrial processing routes remains poorly understood. In this work, Cu enrichment during high-temperature oxidation was systematically investigated under thermo-histories representative of conventional hot rolling, thin slab continuous casting and rolling (TSCR), and strip casting. Plain carbon steels containing 0.05–0.30 wt.% Cu were oxidized at 1000–1200 °C, and interfacial microstructures were characterized using SEM–EDS. The results show that Cu enrichment is highly sensitive to both temperature and thermal exposure time, with a critical temperature range of 1100–1150 °C promoting the formation of continuous Cu-rich liquid films. Prolonged thermo-history in conventional hot rolling markedly enhances Cu enrichment, TSCR partially suppresses interfacial segregation, whereas strip casting effectively inhibits Cu enrichment even at elevated Cu contents. These findings highlight thermo-history as a dominant factor controlling Cu-induced surface hot shortness and provide guidance for process optimization in recycled steels. [ABSTRACT FROM AUTHOR] |
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| Database: | Engineering Source |
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