تعداد نشریات | 31 |
تعداد شمارهها | 748 |
تعداد مقالات | 7,108 |
تعداد مشاهده مقاله | 10,240,730 |
تعداد دریافت فایل اصل مقاله | 6,898,264 |
Interaction of Ni and Cu in accumulation in leaves of the Ni-hyper accumulator, Alyssum murale | ||
Caspian Journal of Environmental Sciences | ||
دوره 20، شماره 3، مهر 2022، صفحه 459-466 اصل مقاله (979.74 K) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22124/cjes.2022.5637 | ||
نویسندگان | ||
Mohammad Reza Dalalian* 1؛ Shahram Shahmohammadi-Kalalagh2 | ||
1Department of Soil Science, Tabriz Branch, Islamic Azad University, Tabriz, Iran | ||
2Department of Water Sciences and Engineering, Tabriz Branch, Islamic Azad University, Tabriz | ||
چکیده | ||
Plants that can accumulate metals to exceptionally high concentrations in their shoots are so-called hyper-accumulators. To further quantify potential interactions between Ni and Cu, the Alyssuem murale grown in soils with factorial additions of NiSO4·6 H2O (0, 50, 250, 500 and 750 mg kg-1 Ni = Ni-T0, 50, 250 and 750) and/or CuSO4·H2O (0, 50, 250 and 500 mg kg-1 Cu = Cu-T0, 50, 250 and 500) salts were investigated. The experiments were carried out in pots in a greenhouse under controlled temperature, light conditions and ambient humidity. The test plants for biomass production were harvested three times; 30, 60 and 100 days after germination. Ni and Cu concentrations in the digests were determined by flame atomic absorption. The results showed that by each different levels of Ni, the maximum amount of absorbed Ni was achieved at 50 mg kg-1 Cu concentration. Also, with elevation of Cu concentration, Ni uptake decreased. These results indicated that the Ni-T750 and Cu-T50 at the third time period had the maximum average of 1585 µg kg-1 and was significantly different from the other treatments. The statistical analysis indicated that by the increased Ni levels from zero to 50 mg kg-1 in soil, the performance of the plant dry matter was significantly declined at the all Cu levels. In addition, by the Cu-T50 in the soil, the dry matter amount at the all Ni levels were higher than that of Cu-T0, although the differences were not significant (p < 0.05). | ||
کلیدواژهها | ||
Alyssuem murale؛ Cu؛ Ni؛ Phytoextraction؛ Soil pollution | ||
مراجع | ||
Asemaneh, T, Ghaderian, SM, Crawford, SA, Marshall, AT & Baker, AJM 2006, Cellular and subcellular compartmentation of Ni in the Eurasian Serpentine plants Alyssum bracteatum, Alyssum murale (Brassicaceae) and Cleome heratensis (Capparaceae). Planta, 225: 193-202.
Bani, A, Pavlova, D, Benizri, E, Shallari, S, Miho, L, Meco, M, Shahu, E, Reeves, R & Echevarria, G 2018, Relationship between the Ni hyperaccumulator Alyssum murale and the parasitic plant Orobanche nowackiana from serpentines in Albania. Ecological Research, 33: 549-559.
Broadhurst, CL & Chaney, RL 2016, Growth and Metal Accumulation of an Alyssum Murale Nickel Hyperaccumulator Ecotype Co-cropped With Alyssum Montanum and Perennial Ryegrass in Serpentine Soil. Frontiers in Plant Science, 7: 451.
Broadhurst, CL, Tappero, RV, Maugel, TK, Erbe, EF, Sparks, DL & Chaney, RL 2009, Interaction of Ni and manganese in accumulation and localization in leaves of the Ni hyperaccumulators Alyssum murale and Alyssum corsicum. Plant and Soil, 314: 35-48.
Cassina, L, Tassi, E, Morelli, E, Giorgetti, L, Remorini, D, Chaney, RL & Barbafieri, M 2011, Exogenous Cytokinin Treatments of an Ni Hyper-Accumulator, Alyssum Murale, Grown in a Serpentine Soil: Implications for Phytoextraction. International Journal of Phytoremediation, 13: 90-101.
Chaney RL, Angle JS, Baker AJM & Li YM 2004, Method for phytomining of Ni, cobalt, and other metals from soil. US patent 5,944,872.
Clark, CE, Burnham, AJ, Harto, CB & Horner, RM 2012, Hydraulic fracturing: technology, impacts, and policy (No. ANL/EVS/R-12/5). Argonne National Lab. (ANL), Argonne, IL (United States).
dos Santos, EV, Sáez, C, Martínez-Huitle, CA, Cañizares, P & Rodrigo, MA 2015, The role of particle size on the conductive diamond electrochemical oxidation of soil-washing effluent polluted with atrazine. Electrochemistry Communications, 55: 26-29.
Fuentes, D, Disante, KB, Valdecantos, A, Cortina, J & Vallejo, VR 2007, Response of Pinus halepensis Mill. Seedlings to biosolids enriched with Cu, Ni and Zn in three Mediterranean forest soils. Environmental Pollution, 145: 316-323.
Ghaderian, SM, Mohtadi, A, Rahiminejad, MR & Baker, AJM 2007, Nickel and other metal uptake and accumulation by Alyssum (Brassicaceae) from the ultramafics of Iran. Journal of Environmental Pollution, 145: 293-298.
Gee, GW & Bauder, JW 1986, Particle-size analysis. In A.Klute (ed.). Methods of soil analysis, Part1. ASA and SSSA. Madison. WI, 383-411.
Gupta, PK 2007, Soil, plant, water and fertilizer analysis, 2nd ed., Agrobios. New Delhi, India, 146 p.
Hashim, MA, Mukhopadhyay, S, Sahu, JN & Sengupta, B 2011, Remediation technologies for heavy metal contaminated groundwater. Journal of Environmental Management, 92: 2355-2388.
Hossner, LR, Loeppert, RH, Newton, RJ & Szaniszlo, PJ 1998, Literature review: phytoaccumulation of chromium, uranium, and plutonium in plant systems (No. ANRCP-1998-3). Amarillo National Resource Center for Plutonium, TX (United States), 55 p.
Hunce, SY, Akgul, D, Demir, G & Mertoglu, B 2012, Solidification/stabilization of landfill leachate concentrate using different aggregate materials. Waste Management, 32: 1394-1400.
Huang, D, Xu, Q, Cheng, J, Lu, X & Zhang, H 2012, Electrokinetic remediation and its combined technologies for removal of organic pollutants from contaminated soils. International Journal of Electrochemical Science, 7: 4528-4544.
Kim, B & McBride, MB 2009, Phytotoxic effects of Cu and Zn on soybeans grown in field‐aged soils: Their additive and interactive actions. Journal of Environmental Quality, 38: 2253-2259.
Li, YM, Chaney, R, Brewer, E, Roseberg, R, Angle, JS, Baker, A, Reeves, R & Nelkin, J 2003, Development of a technology for commercial phytoextraction of Ni: economic and technical considerations. Plant and Soil, 249: 107-115.
López-Vizcaíno, R, Sáez, C, Cañizares, P & Rodrigo, MA 2012, The use of a combined process of surfactant-aided soil washing and coagulation for PAH-contaminated soils treatment. Separation and Purification Technology, 88: 46-51.
Mena, E, Ruiz, C, Villaseñor, J, Rodrigo, MA & Cañizares, P 2015, Biological permeable reactive barriers coupled with electrokinetic soil flushing for the treatment of diesel-polluted clay soil. Journal of Hazardous Materials, 283: 131-139.
Motesharezadeh, B & Savaghebi-Firoozabadi, GR 2011, Study of the increase in phytoremediation efficiency in a Ni polluted soil by the usage of native bacteria: Bacillus safensis FO. 036b and Micrococcus roseus M2. Caspian Journal of Environmental Sciences, 9: 133-143.
Nelson, DW & Sommers, LE 1996, Total carbon, organic carbon, and organic matter. In: Methods of soil analysis, Part 2, 2nd ed., AL Page et al., Agronomy, 9: 961-1010. American Society of Agronomy, Inc. Madison, WI, pp: 539-579.
Papazoglou, EG, Karantounias, GA, Vemmos, SN & Bouranis, DL 2005, Photosynthesis and growth responses of giant reed (Arundo donax L.) to the heavy metals Cd and Ni. Environment International, 31: 243-249.
Paria, S & Yuet, PK 2006, Solidification–stabilization of organic and inorganic contaminants using portland cement: a literature review. Environmental Reviews, 14: 217-255.
Parida, BK, Chhibba, IM & Nayyar, VK 2003, Influence of Ni-contaminated soils on fenugreek (Trigonella corniculata L.) growth and mineral composition. Scientia Horticulturae, 98: 113-119.
Raicevic, S, Kaludjerovic-Radoicic, T & Zouboulis, AI 2005, In situ stabilization of toxic metals in polluted soils using phosphates: Theoretical prediction and experimental verification. Journal of Hazardous Materials, 117: 41-53.
Rascio, N & Navari-Izzo, F 2011, Heavy metal hyperaccumulating plants: how and why do they do it? And what makes them so interesting? Plant Science, 180: 169-181.
Rhoades, JD 1982, Soluble Salts. In: A.L. Page (ed.) Methods of soil analysis, Part 2 Chemical and microbiological properties, 2nd edition. Agronomy, 9: 149-157.
Rozas, F & Castellote, M 2012, Electrokinetic remediation of dredged sediments polluted with heavy metals with different enhancing electrolytes. Electrochimica Acta, 86: 102-109.
Sarma, H 2011, Metal hyperaccumulation in plants: a review focusing on phytoremediation technology. Journal of Environmental Science and Technology, 4: 118-138.
Sellami, R, Gharbi, F, Rejeb, S, Rejeb, MN, Henchi, B, Echevarria, G & Morel, JL 2012, Effects of Ni hyperaccumulation on physiological characteristics of Alyssum murale grown on metal contaminated waste amended soil. International Journal of Phytoremediation, 14: 609-620.
Svab, M, Kubal, M, Müllerova, M & Raschman, R 2009, Soil flushing by surfactant solution: Pilot-scale demonstration of complete technology. Journal of Hazardous Materials, 163: 410-417.
Tang, X, & McBride, M B 2018, Phytotoxicity and microbial respiration of Ni‐spiked soils after field aging for 12 yr. Environmental Toxicology and Chemistry, 37: 1933-1939.
Tappero, R, Peltier, E, Gräfe, M, Heidel, K, Ginder‐Vogel, M, Livi, KJT, Rivers, ML, Marcus, MA, Chaney, RL & Sparks, DL 2007, Hyperaccumulator Alyssum murale relies on a different metal storage mechanism for cobalt than for Ni. New Phytologist, 175: 641-654.
U.S. Salinity Laboratory Staff 1954, Diagnosis and improvement of saline and alkali soils. USDA Agriculture Handbook. No 60. US. Goverment Publishing Office. Washington DC, 166 p.
Wishart, DN, Slater, LD, Schnell, DL & Herman, GC 2009, Hydraulic anisotropy characterization of pneumatic-fractured sediments using azimuthal self potential gradient. Journal of Contaminant Hydrology, 103: 134-144.
Wuana, RA & Okieimen, FE 2011, Heavy metals in contaminated soils: A review of sources, chemistry, risks and best available strategies for remediation. ISRN Ecology, 2011.
| ||
آمار تعداد مشاهده مقاله: 537 تعداد دریافت فایل اصل مقاله: 447 |