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- Title
Hydraulic conductivity of the polymer-modified bentonite -sand-phosphogypsum (PMB-S-PG) mixture under drying–wetting and freezing–thawing cycles.
- Authors
Yang, Wei; Song, Muyuan; Yuan, Ping; Liu, Xueying; Chen, Wei; Plé, Olivier
- Abstract
To improve the multi-path and multi-field exploitation of phosphogypsum (PG), a polymer-modified bentonite-sand-phosphogypsum mixture is developed for application in anti-seepage of PG slag fields and roadbeds. In this research, the SEM tests, FSI tests, and hydraulic conductivity tests under different conditions are carried out. The PMB has a superior swell index (72 ml/2 g) in water, but the PMB-S-PG0.5 mixture's swell index is low (5.8 ml/2 g) in water because the acidic PG. The SEM and EDS tests reveal that the particles in the PMB-S-PG0.5 mixture form tight bond. The mixture has elasticity and strength due to the PMB carried many polymers, and these polymers can complicate the seepage channels and maintain the low hydraulic conductivity. Thus, the swell index is not an accurate indicator to hydraulic conductivity. During the DW cycles, the PMB-S-PG0.5 mixture has lower degree of crack development, superior crack self-healing properties and more tortuous seepage channels, resulting in lower hydraulic conductivity (2.14 × 10–10 m/s) compared to the RB-S-PG0.5 mixture (6.90 × 10–9 m/s) after 9 DW cycles. Due to the finer particles, the lower number of ice lenses, and the more seepage channels in PMB-S-PG0.5 mixture, the degree of ice nucleation in the PMB-S-PG0.5 mixture is lower than in the RB-S-PG0.5 mixture during the FT cycles. The PMB-S-PG0.5 mixture's hydraulic conductivity was lower (9.72 × 10–11 m/s) compared to the RB-S-PG0.5 mixture (3.26 × 10–9 m/s) after 9 FT cycles. That is, the PMB-S-PG0.5 mixture is expected to be widely used to enable the resource reuse of PG.
- Subjects
HYDRAULIC conductivity; BENTONITE; PARTICULATE matter; MIXTURES; PHOSPHOGYPSUM; INORGANIC polymers
- Publication
Journal of Material Cycles & Waste Management, 2024, Vol 26, Issue 2, p1012
- ISSN
1438-4957
- Publication type
Article
- DOI
10.1007/s10163-023-01877-4