Sun Wenhao H, Lo Joey B, Robert Françoise M, Ray Chittaranjan, Tang Chung-Shih
Department of Molecular Biosciences and Bioengineering, University of Hawaii, 1955 East-West Road, Agricultural Science 218, Honolulu, Hawaii 96822, USA.
Environ Sci Pollut Res Int. 2004;11(4):260-6. doi: 10.1007/BF02979634.
GOAL, SCOPE AND BACKGROUND: This glasshouse study is aimed at evaluating tropical plants for phytoremediation of petroleum hydrocarbon-contaminated saline sandy subsurface soils. Tropical plants were selected for their ability to tolerate high salinity and remove No. 2 diesel fuel in coastal topsoil prior to further investigation of the phytoremediation feasibility in deep contaminated soils. The residual petroleum-hydrocarbon contaminant at the John Rogers Tank Farm site, a former petroleum storage facility, at Hickam Air Force Base, Honolulu, Hawaii, is located in a coastal area. It lies below a layer of silt in the subsurface, in loamy sand characterized by moderate salinity and high pH. Little is known regarding the ability of tropical plants to remediate petroleum hydrocarbon-contaminated subsurface soil in Hawaiian and other Pacific Island ecosystems although suitable plants have been identified and utilized for bioremediation in surface soil or marine sediments.
The experiments were conducted in long narrow pots under glasshouse conditions in two phases. A preliminary experiment was done with nine tropical plants: kiawe (Prosopis pallida), milo (Thespesia populnea), common ironwood (Casuarina equisetifolia), kou (Cordia subcordata), tropical coral tree (Erythrina variegata), false sandalwood (Myoporum sandwicense), beach naupaka (Scaevola sericea), oleander (Nerium oleander), and buffelgrass (Cenchrus ciliaris). These plants were screened for resistance to high salinity treatment (2% NaCl) and two diesel fuel levels (5 and 10 g No. 2 diesel fuel/kg soil) in separate treatments. Plants that showed good tolerance of both factors were further evaluated in a second phase for their efficacy in the phytoremediation of diesel-fuel petroleum hydrocarbons under moderate salinity treatment (1% NaCl).
Tropical coral tree and buffelgrass were susceptible to either 2% NaCl or diesel fuel at 10 g/kg soil, but tolerant of diesel fuel at 5 g/kg soil. Kiawe, milo, kou, common ironwood, N. oleander, beach naupaka and false sandalwood were tolerant of high salinity (2% NaCl) or high diesel fuel level (10 g/kg soil). These seven plants were also tolerant of the combined adverse effects of a moderate salinity (1% NaCl) and 10 g diesel fuel/kg soil. Three trees, kiawe, milo and kou significantly accelerated the degradation of petroleum hydrocarbons in the soil spiked with 10 g diesel fuel/kg soil under a moderate salinity treatment (1% NaCl).
Thus the tropical woody plants, kiawe, milo and kou showed potential for use in phytoremediation of petroleum hydrocarbons in coastal tropical soils.
Two fast growing trees, milo and kou, appeared promising for further phytoremediation evaluation in experiments that simulate the soil profile at the field site.
目标、范围和背景:本温室研究旨在评估热带植物对受石油烃污染的盐渍砂质地下土壤的植物修复能力。选择热带植物是因为它们能够耐受高盐度,并能在进一步研究深层污染土壤的植物修复可行性之前,去除沿海表土中的2号柴油。位于夏威夷檀香山希卡姆空军基地的约翰·罗杰斯油罐农场旧址,是一个 former petroleum storage facility,其残留的石油烃污染物位于沿海地区。它位于地下一层淤泥之下,处于盐度适中、pH值较高的壤质砂土中。尽管已经确定了适合的植物用于表层土壤或海洋沉积物的生物修复,但对于热带植物在夏威夷和其他太平洋岛屿生态系统中修复受石油烃污染的地下土壤的能力,人们了解甚少。
实验在温室条件下的狭长花盆中分两个阶段进行。初步实验使用了九种热带植物:牧豆树(Prosopis pallida)、木槿(Thespesia populnea)、木麻黄(Casuarina equisetifolia)、寇阿相思树(Cordia subcordata)、热带珊瑚树(Erythrina variegata)、假檀香(Myoporum sandwicense)、海滨纽扣菊(Scaevola sericea)、夹竹桃(Nerium oleander)和水牛草(Cenchrus ciliaris)。这些植物在单独的处理中被筛选对高盐度处理(2%氯化钠)和两种柴油燃料水平(5和10克2号柴油/千克土壤)的抗性。对两个因素都表现出良好耐受性的植物在第二阶段进一步评估其在中度盐度处理(1%氯化钠)下对柴油燃料石油烃的植物修复效果。
热带珊瑚树和水牛草对2%氯化钠或10克/千克土壤的柴油燃料敏感,但对5克/千克土壤的柴油燃料耐受。牧豆树、木槿、寇阿相思树、木麻黄、夹竹桃、海滨纽扣菊和假檀香耐受高盐度(2%氯化钠)或高柴油燃料水平(10克/千克土壤)。这七种植物也耐受中度盐度(1%氯化钠)和10克柴油燃料/千克土壤的联合不利影响。三种树,牧豆树、木槿和寇阿相思树在中度盐度处理(1%氯化钠)下显著加速了添加10克柴油燃料/千克土壤的土壤中石油烃的降解。
因此,热带木本植物牧豆树、木槿和寇阿相思树显示出用于沿海热带土壤中石油烃植物修复的潜力。
两种速生树,木槿和寇阿相思树,在模拟田间土壤剖面的实验中进行进一步的植物修复评估似乎很有前景。
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