LEDs are essential components in the vast majority of technologies. Over the years, to maintain the comfort of modern life, an increase in the generation of LED waste has been observed. It is known that LED wastes are potential sources for recovering critical, valuable, and rare earth metals. Therefore, this study aims to provide a complete characterization of LED models: cold white (CW), warm white (WW), and RED, mapping potential elements to be recovered and hazardous elements to the environment and public health. The LED models were analyzed by ICP-OES, SEM-EDS, and FTIR-ATR. It was observed in WW a higher concentration of Ce, Ga, and Y than in CW and RED due to its greater density of phosphor particles in the encapsulant material. In, Ga, Ag, and Au were seen in LED dies of WITHES, while As, and Ga were identified in RED LED dies. Pb was observed in the solder of CW and RED. LEDs' encapsulant and polymeric structures are polydimethylsiloxane (PDMS) and polyamide 11, respectively. The study findings showed a wide variation in metal contents and distribution regarding different LED models. Those variations were pointed out, providing opportunities for developing future works aimed at recycling and treating LED waste.
Keywords: Characterization; Critical raw materials; LED; Recycling; Urban mining; WEEE.
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