This paper reported the recovery of desert plant communities after
twenty years of oil-derived hydrocarbon contamination in desert habitats
of Kuwait, caused by the First Gulf War (1990 – 1991). The hypothesis
that certain native desert plant species can tolerate weathered
oil-polluted soils with oil breakdown products (i.e., polycyclic
aromatic hydrocarbons ( PAHs)) and have the potential to function as
bioindicators and phytoremediator species for oil-polluted soil was
tested. A field survey of 200 quadrat sampling plots at seven
hydrocarbon-contaminated and unpolluted desert areas in Kuwait was
performed that recorded 42 plant species, with Haloxylon salicornicum,
Cyperus conglomeratus and Rhanterium epapposum as the most dominant
species. Analysis of plant tissues indicated plant uptake and
accumulation of some PAHs. H. salicornicum was used as a representative
species in a controlled field study that included growth of plants in
hydrocarbon-polluted and unpolluted soils in two separate desert areas
under similar growth conditions. Results showed a significant decrease
in plant biomass in oil-contaminated soil compared to those from the
uncontaminated site. However, the plants appeared green and healthy in
both sites, and showed no overt stress. The results suggest that some
desert plant communities exhibit signs of recovery after severe oil
pollution, and that H. salicornicum may serve as a phytoremediator of
oil-contaminated desert soils. Our results also demonstrated that some
desert plant communities could be cultivated in oil fields to reduce
hydrocarbon contamination and provide guide to other ecosystem services
through improving soil quality and biodiversity.
This paper reports on the recovery of desert plant communities after 20 years of oil‐derived hydrocarbon contamination in desert habitats of Kuwait, caused by the First Gulf War (1990–1991). The hypothesis that certain native desert plant species can tolerate weathered oil‐polluted soils and can potentially function as bioindicators and phytoremediator species for oil‐polluted soil was tested. A field survey of 200 quadrat sampling plots at seven hydrocarbon‐contaminated and unpolluted desert areas in Kuwait was performed and recorded 42 plant species, with Haloxylon salicornicum (Moq.) Bunge ex Boiss., Cyperus conglomeratus Rottb., and Rhanterium epapposum Oliv. as the dominant species. Analysis of plant tissues indicated plant uptake and accumulation of some polycyclic aromatic hydrocarbons (PAHs), depending on plant species and specific PAH compounds. Total PAHs in plant tissues in the most contaminated sites were over 200 μg kg−1. H. salicornicum could develop in both oil‐contaminated soil and uncontaminated soil although their biomass was about 16.7% smaller than usual. However, the plants appeared green and healthy in both sites, and showed no overt stress. The results suggest that some desert plant communities can recover after severe oil pollution and that H. salicornicum may serve as a phytoremediator of oil‐contaminated desert soils. Our results also demonstrated that some desert plant communities could be cultivated in oil fields to reduce hydrocarbon contamination and provide support to other ecosystem services through improving soil quality and biodiversity.
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