Abstract
Heavy metals (HMs) exist in nature in different forms, and the more unstable the form of an HM, the higher its toxicity and bioavailability. The content of HMs in stable fractions can increase significantly through the stabilization/solidification (S/S) technology. Still, external environments such as freeze–thaw (F–T) cycles will affect the stability of HMs directly. Therefore, a long-term F–T study of S/S Pb–Zn–Cd composite HM-contaminated soil was conducted under six conditions (0, 3, 7, 14, 30, and 90 cycles) with each F–T cycle process up to 24 h. The improved Tessier method was employed, and the results show that the S/S technology makes HMs transform to a more stable fraction. Still, the transformation efficiency is different for each HM. More than 98% of lead and zinc were converted to stable forms, while for cadmium, there are only 75.1%. Meanwhile, the S/S HMs were rapidly transformed into unstable forms at 0–14 cycles, but after 14 cycles, the transformation speed was significantly reduced. Among stable forms, it is mainly that the carbonate-bound fraction of HMs changes to unstable forms, and the characteristic peaks of carbonate stretching vibration were found at 874 cm−1, and 1420 cm−1 by Fourier infrared spectroscopy proves the presence of carbonate-bound substances. As a result of this study, the change trend of contaminated soil with S/S HMs under the effect of long-term F–T cycle was revealed, and the crisis point of pollution prevention and control was found, which provides some theoretical basis for the safety of soil remediation project.
Highlights
Because of considerable migration depth, complex migration mechanism, sizeable spatial variability, strong concealment, and resistance to degradation of heavy metals (HMs), its high-concentration and high-risk pollutants in the soil are extremely difficult to repair and manage and are called “chemical time bombs” [1–3]
HMs whose bioavailability is greater than this form can be considered to have undergone a transition to the stable forms, and are referred to as the stable form, while the ion-exchange fraction and the water-soluble fraction are set as the unstable form
The improved Tessier method and Fourier transform infrared spectrum (FTIR) analysis test were used to study the effects of long-term F–T on the S/S of Pb–Zn–Cd composite HMcontaminated soil in this study
Summary
Because of considerable migration depth, complex migration mechanism, sizeable spatial variability, strong concealment, and resistance to degradation of heavy metals (HMs), its high-concentration and high-risk pollutants in the soil are extremely difficult to repair and manage and are called “chemical time bombs” [1–3]. The non-degradability of HMs leads to their accumulation in plants, animals, and humans along the biological chain [7–11]. Both pose a threat to human safety and health; it is imperative to control soil. That means fixing them in place and reducing their biotoxicity by special treatments [13,14]. Solidification/stabilization (S/S) technology is the most widely used because of its cost-effective and simple operation [14,15]
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