Green Zero-Waste Metal Extraction and Recycling from Printed Circuit Boards "2279

The development of a truly circular economy necessitates the recovery and recycling of resources from secondary streams. In this work, we studied the extraction of metals from printed circuit boards (PCBs) using choline chloride: ethylene glycol deep eutectic solvents: Cu, Ni, Zn, and Sn were selectively extracted from the PCBs, with >75% extraction after 72 h for Cu, Ni, and Sn, and circa. 45% extraction for Zn. This solvometallurgical approach promises to minimize the use of water and acid/base reagents in processing. The results show a considerable ability to compete with current methods of metal extraction and therefore generate a strong potential to attain the goal of a sustainable circular economy via zero-waste green urban mining.


Introduction
The vast amount of electronic waste generated from our tech-heavy societies is a significant challenge currently facing the world. In fact, waste electrical and electronic equipment (WEEE) is one of the fastest growing waste streams, with more than 5% annual growth, and represents a valuable secondary resource for strategic, critical, and precious metals [1]. In fact, many WEEE streams contain higher concentrations of valuable metals than primary resources. Although metal separation and recovery from these complex matrices is a challenge, green urban mining has become significantly important worldwide [2].
Recently, a new zero-waste solvometallurgical processing route has been proposed for metal extraction and recovery. It relies on the use of green anhydrous solvents, namely, deep eutectic solvents (DESs), and promises to minimize the use of water and acid/base consumption in process circuits [3]. DESs are eco-friendly, biodegradable, low cost, and easy to prepare solvents with tunable properties [4]. Specifically, they are mixtures of salts which, due to hydrogen bonding, result in a lower melting point than their respective discrete components [4]. Thus far, DESs have been successfully used in several studies, including selective metal dissolution and electrowinning from ores and wastes [5][6][7][8][9].
In this work, we studied the solvometallurgical extraction of metals from printed circuits boards (PCBs). Due to the high association of metals with plastics, metal liberation processes often lead to fine particles, which may, in turn, result in inefficient metal recovery [10]. To reduce such metal losses, we used large pieces of PCBs instead of pulverized PCB powder [11,12]. Ethaline, a DES mixture of choline chloride (ChCl) and ethylene glycol (EG) at a 1:2 molar ratio, was used as the solvent in this study. Ethaline is a promising green solvent, as it is chemically stable in both air and moisture [13] and has low viscosity (36 cP) [14]. In addition, the use of iodine was evaluated as the oxidant in this work. Iodine is an environmentally benign strong oxidant that can be used in solvometallurgical processing since it is both highly soluble in ethaline and able to oxidize most elements [15].
Printed circuit boards (PCBs) were collected from a local scrap market. The electronic elements attached to the PCBs were manually removed prior to exposing the PCBs in a 10 M NaOH solution for 24 h to remove any chemical coating, which could prevent contact between the metals and the solvent. The PCBs were then washed with DI water, dried, and cut into 1 × 1 cm 2 pieces. All leaching experiments were carried out in 250 mL beakers at 85°C, 150 rpm, for 72 h, with and without the presence of 0.1 mol L −1 I 2 .
The experiments were duplicated. Liquid samples were collected at pre-determined time intervals, filtered, diluted with 5% HNO 3 , and analyzed using microwave plasma atomic emission spectroscopy (MP-AES, Agilent Technologies 4100 + ). Sodium peroxide fusion was used to completely digest the remaining PCB pieces post-leaching; metal concentrations were determined by MP-AES.

Results
The average metal content of the PCBs is shown in Table 1. Metal extraction (%) during leaching from the 1 × 1 cm 2 PCB pieces was calculated using Equation (1).
where M 1 is the metal weight (mg) in the pregnant leach solution (PLS), and M 2 is the metal weight (mg) in the residue. M 1 and M 2 were calculated based on Equations (2) and (3), respectively.
where C 1 (ppm) is the metal concentration in the PLS, V 1 (L) is the volume of the leaching solution, C 2 (ppm) is the metal concentration in the solid residue after leaching, and V 2 (L) is the volume of the fusion digestion solution. Figures 1 and 2 show the metal extraction (%) from the PCBs in ethaline with and without I 2 after 72 h. The presence of I 2 significantly enhanced metal extraction, except for Al, which in both cases resulted in less than 1% extraction. The lower effectiveness of ethaline compared to ethaline:I 2 may be attributed to the metallic state of the metals present on the PCBs [6,16]. As can be seen in Figure 2, in the presence of I 2 , the extraction of Cu, Sn, and Ni was higher than 75%, while that of Zn was circa. 45%. However, without the presence of I 2 in ethaline, metal extraction was below 15%, except for Sn (circa. 100%). ethaline compared to ethaline:I2 may be attributed to the metallic state of the metals present on the PCBs [6,16]. As can be seen in Figure 2, in the presence of I2, the extraction of Cu, Sn, and Ni was higher than 75%, while that of Zn was circa. 45%. However, without the presence of I2 in ethaline, metal extraction was below 15%, except for Sn (circa. 100%).

Discussion
Solvometallurgical processing shows a strong potential in the field of sustainable urban mining, especially in the recovery of metals from waste electrical and electronic equipment. This work investigated the extraction of metals from large pieces of printed circuit boards (PCBs) by leaching in a green non-aqueous choline chloride: ethylene glycol deep ethaline compared to ethaline:I2 may be attributed to the metallic state of the metals present on the PCBs [6,16]. As can be seen in Figure 2, in the presence of I2, the extraction of Cu, Sn, and Ni was higher than 75%, while that of Zn was circa. 45%. However, without the presence of I2 in ethaline, metal extraction was below 15%, except for Sn (circa. 100%).

Discussion
Solvometallurgical processing shows a strong potential in the field of sustainable urban mining, especially in the recovery of metals from waste electrical and electronic equipment. This work investigated the extraction of metals from large pieces of printed circuit boards (PCBs) by leaching in a green non-aqueous choline chloride: ethylene glycol deep

Discussion
Solvometallurgical processing shows a strong potential in the field of sustainable urban mining, especially in the recovery of metals from waste electrical and electronic equipment. This work investigated the extraction of metals from large pieces of printed circuit boards (PCBs) by leaching in a green non-aqueous choline chloride: ethylene glycol deep eutectic solvent. The results indicate that the use of an oxidant, namely, iodine, is necessary to achieve acceptable metal extraction levels from non-oxidized metal resources. Specifically, without using water or acid/base reagents in the leaching process, Cu, Ni, Zn, and Sn metals were selectively extracted from 1 × 1 cm 2 PCB pieces (>75% extraction after 72 h for Cu, Ni, and Sn, and circa. 45% for Zn); Al, Mg, and Pb extraction was below 10%, and that of Fe was below 40%. These results are a strong indicator of the potential success of the solvometallurgical approach as a green zero-waste metal extraction and recycling processing route.