Halophyte-Mediated Metal Immobilization and Divergent Enrichment in Arid Degraded Soils: Mechanisms and Remediation Framework for the Tarim Basin, China

Liu, Jingyu; Wang, Lang; Guo, Shuai; Hu, Hongli

Halophyte-Mediated Metal Immobilization and Divergent Enrichment in Arid Degraded Soils: Mechanisms and Remediation Framework for the Tarim Basin, China

Jingyu Liu (), Lang Wang (), Shuai Guo and Hongli Hu
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Jingyu Liu: Urumqi Natural Resources Comprehensive Survey Center of China Geological Survey, Urumqi 830057, China
Lang Wang: Urumqi Natural Resources Comprehensive Survey Center of China Geological Survey, Urumqi 830057, China
Shuai Guo: Urumqi Natural Resources Comprehensive Survey Center of China Geological Survey, Urumqi 830057, China
Hongli Hu: Urumqi Natural Resources Comprehensive Survey Center of China Geological Survey, Urumqi 830057, China

Sustainability, 2025, vol. 17, issue 19, 1-19

Abstract: Understanding heavy metal behavior in arid saline soils is critical for phytoremediation in degraded lands. This study investigated metal distribution and plant enrichment in the Tarim Basin using 323 soil and 55 plant samples ( Populus euphratica , Tamarix ramosissima , cotton, jujube). Analyses included redundancy analysis (RDA) and bioconcentration factor (BCF) assessments. Key findings reveal that elevated salinity (total salts, TS > 200 g/kg) and alkalinity (pH > 8.5) immobilized As, Cd, Cu, and Zn. Precipitation and competitive leaching reduced metal mobility by 42–68%. Plant enrichment strategies diverged significantly: P. euphratica hyperaccumulated Cd (BCF = 1.59) and Zn (BCF = 2.41), while T. ramosissima accumulated As and Pb (BCF > 0.05). Conversely, cotton posed Hg transfer risks (BCF = 2.15), and jujube approached Cd safety thresholds in phosphorus-rich soils. RDA indicated that pH and total salinity (TS) jointly suppressed metal bioavailability, explaining 57.6% of variance. Total phosphorus (TP) and soil organic carbon (SOC) enhanced metal availability (36.8% variance), with notable TP-Cd synergy (Pearson’s r = 0.42). We propose a dual-threshold management framework: (1) leveraging salinity–alkalinity suppression (TS > 200 g/kg + pH > 8.5) for natural immobilization; and (2) implementing TP control (TP > 0.8 g/kg) to mitigate crop Cd risks. P. euphratica demonstrates targeted phytoremediation potential for degraded saline agricultural systems. This framework guides practical management by spatially delineating zones for natural immobilization versus targeted remediation (e.g., P. euphratica planting in Cd/Zn hotspots) and implementing phosphorus control in high-risk croplands.

Keywords: heavy metal behavior; saline–alkaline soil; arid ecosystems; Tarim Basin; phytoremediation potential (search for similar items in EconPapers)
JEL-codes: O13 Q Q0 Q2 Q3 Q5 Q56 (search for similar items in EconPapers)
Date: 2025
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