Geochemical Characterization of Iron and Steel Slag and Its Potential to Remove Phosphate and Neutralize Acid

Piatak, Nadine M.; Seal, Robert R.; Hoppe, Darryl Andre; Green, Carlin J.; Buszka, Paul M.

doi:10.3390/min9080468

Cited by 16 publications

(8 citation statements)

References 36 publications

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“…The nonferrous slag includes copper slag, zinc slag, lead-zinc slag, and nickel slag. Several studies highlighted the importance of reprocessing waste piles for secondary metal recovery, thus, generating revenues [64,65]. Of course, one of the keys issues to be addressed is that the slag is generally characterized by an uneven distribution of the target components throughout the slag dump [66].…”

Section: Co-occurrence Keyword Networkmentioning

confidence: 99%

“…However, the laboratory tests performed by Kasikow et al demonstrated that a recovery process for large volumes of nickel-cobalt technogenic raw materials is valid to the total volume of slag [66]. On the other hand, bio-assisted extraction of metals from historical slag by use of Acidithiobacillus thiooxidans was demonstrated as being technical feasible and, at the same time, economically efficient [65]. Another already in practice example of metal recovery is the modern smelter of Zambian Copperbelt where the historical copper tailing was revisited for extraction of cobalt recovery [64].…”

Section: Co-occurrence Keyword Networkmentioning

confidence: 99%

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Global Research Progress and Trends on Critical Metals: A Bibliometric Analysis

2023

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In the perspective of observing the latest worldwide and European strategies toward green transition and delivering a secured access to local resources, the objective of this study was to analyze the research progress on critical materials and, more specific, critical metals and review the future research hot-topics for critical metals. Consequently, a bibliometric analysis for the assessment of the current state of the art research, future trends as well as evolution through time of the critical metals research was performed in the present work. The study included four phases of work: (i) search string selection, (ii) data collection, (iii) data processing, and (iv) data interpretation. A total of 433 publications on critical metals were collected from Scopus database between 1977 and 2023, with an increasing yearly trend and a burst in 2013. The data retrieved showed a significant increase in publications related to the topic in the last 10 years. The results show that research interest is concentrated around six critical areas: (i) bioleaching as an important process of critical metal recovery, (ii) circular economy concepts and recovery of critical metals by urban mining from e-waste, (iii) resource recovery from waste landfills as urban mines, (iv) targeted studies on various critical elements (copper, zinc, gallium, silver, lithium), (v) rare elements as industry vitamins and, (vi) coal deposits and coal ashes as an alternative source of critical metals. This analysis could provide important guidance for further directions on the development of research for recovery of critical metals.

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Section: Co-occurrence Keyword Networkmentioning

confidence: 99%

Section: Co-occurrence Keyword Networkmentioning

confidence: 99%

Global Research Progress and Trends on Critical Metals: A Bibliometric Analysis

2023

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“…The slag can be characterized using Xray diffraction (XRD), Fourier-transform infrared spectroscopy (FTIR), scanning electron microscopy with energy-dispersive spectrometry (SEM-EDS), and light optical microscopy (LOM) in transmitted and reflected light [45][46][47]. Previous studies have indicated that copper slag behaves differently when subjected to different temperatures, thus exhibiting different properties [42,48]. BCL slag was characterized to analyze its composition.…”

Section: Uses Of Metallurgical Slagmentioning

confidence: 99%

“…Direct reduction is one method used to recover iron from the slag by reducing Fe 3 O 3 and Fe 2 SiO 4 found in copper slag to metallic iron using coal. This involves using reduction temperatures of about 1300 • C over the course of 30 min, giving an output of 98.13% Fe [48]. Iron is a vital metal element that encourages the growth of humanity and national economies [62,63].…”

Section: Reuse and Recycling Of Copper Slagmentioning

confidence: 99%

Environmental and Socioeconomic Impact of Copper Slag—A Review

et al. 2021

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Copper slag is generated when copper and nickel ores are recovered from their parent ores using a pyrometallurgical process, and these ores usually contain other elements which include iron, cobalt, silica, and alumina. Slag is a major problem in the metallurgical industries as it is dumped into heaps which have accumulated into millions of tons over the years. Moreover, they pose a danger to the environment as they occupy vacant land (space problems). Over the past few years, studies have been conducted to investigate the copper slag-producing outlets to learn their behavior, as well as properties of slag, to have the knowledge of how to better reuse and recycle copper slag. This review article provides the environmental and socioeconomic impacts of slag, as well as a characterization of copper slag, with the aim of reusing and recycling the slag to benefit the environment and economy. Recycling methods are considered an attractive technological pathway for reducing waste and greenhouse gas emissions, as well as promoting the concept of circular economy through the utilization of waste. These metal elements have value depending on their characteristics; hence, copper slag is considered as a secondary source of valuable metals. Some of the pyrometallurgical and hydrometallurgical processes to consider are physical separation, magnetic separation, flotation, leaching, and direct reduction roasting of iron (DRI). Some of the possible metals that can be recovered from the copper slag include Cu, Fe, Ni, Co, and Ag (precious metals).

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“…Another example of how to reuse metallurgical slags is presented in the contribution of Piatak et al [7]. Through the study of ferrous slags from the Chicago-Gary area (Illinois and Indiana, USA), the effective removal of phosphates from solution was documented.…”

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confidence: 99%