Arsenic (V) removal from water using hydrotalcites as adsorbents: A critical review (original) (raw)

2020, Applied Clay Science

Arsenic (As) is one of the most hazardous substance to human health because it is a toxic and carcinogenic chemical element. Hydrotalcites, the main class of layered double hydroxides (LDH), has emerged in the literature as promising adsorbents for remediation of waters contaminated with As. This fact is due to its high maximum adsorption capacity of As. However, determinations of residual concentration of As(V) in equilibrium solution after adsorption process, using hydrotalcites as adsorbent, are of fundamental importance and deserve special attention. In this review the term 'hydrotalcite' is used to describe LDH composed of Mg, Al, and CO 3 (Mg-Al LDH). The World Health Organization (WHO) establishes a limit of 0.01 mg L −1 of As in drinking water. Even though hydrotalcites have high maximum adsorption capacity of As, residual concentration of As in equilibrium solution could be toxic. Therefore, adsorbents for contaminated water remediation should be chosen based not only on maximum adsorption capacity. Moreover, for As(V) adsorption researches using hydrotalcites as adsorbent, only a few studies have evaluated the chemical dissolution of structural components in hydrotalcites such as aluminum (Al) and magnesium (Mg). Currently, the presence of Al in human organisms has been correlated to potential risk of Alzheimer's disease. This subject is of extreme importance but little discussed in the literature. In this review, no comparison was made regarding the efficiency of hydrotalcites in removing As from contaminated waters, but rather an approach to its use as adsorptive material in studies on water decontamination for potability. 1. Introduction The presence of arsenic (As) in waters for human consumption has increasingly concerned global public health (Bhattacharya et al., 2007). Water As-contamination due to natural and anthropogenic activities is a relevant problem for public health and threatens well-being and livelihoods of over 100 million people worldwide (Bhattacharya et al., 2007). Chronic exposure to As-contaminated water can result in skin lesions, metabolic and cardiovascular diseases, diabetes, adverse effects at birth, and some cancers (