Abstract
The need for rare earths elements (REEs) in high tech electrical and electronic based materials are vital. In the global economy, deposits of natural REEs are limited except for countries such as China, which has prompted current attempts to seek alternative resources of REEs. This increased the dependence on major secondary rare earth-bearing sources such as scrap alloy, battery waste, spent catalysts, fly ash, spent magnets, waste light-emitting diodes (LEDs), and phosphogypsum (PG) for a substantial recovery of REEs for use. Recycling of REEs from these alternative waste sources through hydrometallurgical processes is becoming a sustainable and viable approach due to the low energy consumption, low waste generation, few emissions, environmentally friendliness, and economically feasibility. Industrial wastes such as the PG generated from the production of phosphoric acid is a potential secondary resource of REEs that contains a total REE concentration of over 2000 mg/kg depending upon the phosphate ore from which it is generated. Due to trace concentration of REEs in the PG (normally < 0.1% wt.) and their tiny and complex occurrence as mineral phases the recovery process of REE from PG would be highly challenging in both technology and economy. Various physicochemical pre-treatments approaches have been used up to date to up-concentrate REEs from PG prior to their extraction. Methods such as carbonation, roasting, microwave heating, grinding or recrystallization have been widely used for this purpose. This present paper reviews recent literature on various techniques that are currently employed to up-concentrate REs from PG to provide preliminary insight into further critical raw materials recovery. In addition, the advantages and disadvantages of the different strategies are discussed as avenues for realization of REE recovery from PG at a larger scale. In all the different approaches, recrystallization of PG appears to show promising advantages due to both high REE recovery as well as the pure PG phase that can be obtained.
Highlights
The need for rare earths elements (REEs) in high tech electrical and electronic based materials are vital
This review provided information about the leaching of PG to provide an overview for the recovery of REEs contained in secondary wastes as critical raw materials
The first stage in REE recovery from waste materials is the leaching of elements from the solids
Summary
Rare earths elements (REEs) are metals of the lanthanoids series on the periodic table commonly referred to as lanthanides, with atomic numbers ranging from 57 to 71. REE metal used in current advanced technologies This advancement has led to a strong growth in the use of rare earth oxides (REOs) in the past few decades, from. The. Chinese control over the annual amounts of REO had led to significant price fluctuations, in particular for elements such as neodymium, dysprosium, europium, yttrium and terbium that are mostly used in sustainable applications. Chinese control over the annual amounts of REO had led to significant price fluctuations, in particular for elements such as neodymium, dysprosium, europium, yttrium and terbium that are mostly used in sustainable applications This control has prompted an urgent search for new deposits of REEs as well as the reopening of formerly exploited deposits such as the Mountain Pass mine in Nevada, United States of America, which was reopened in 2012 [7].
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