Distribution of heavy metals in wheat, mustard, and weed grown in field irrigated with industrial effluents.
about
Risk assessment of heavy metals contamination in paddy soil, plants, and grains (Oryza sativa L.) at the East Coast of India.Heavy metals in soil and crops of an intensively farmed area: a case study in Yucheng City, Shandong Province, China.Influence of groundwater and wastewater irrigation on lead accumulation in soil and vegetables: Implications for health risk assessment and phytoremediation.Accumulation of arsenic, lead, copper, and zinc, and synthesis of phytochelatins by indigenous plants of a mining impacted area.Assessment of the root system of Brassica juncea (L.) czern. and Bidens pilosa L. exposed to lead polluted soils using rhizobox systems.Irrigational impact of distillery effluent on Abelmoschus esculentus L. Okra with special reference to heavy metals.Phytoextraction of metals by Erigeron canadensis L. from fly ash landfill of power plant "Kolubara".Effects of wastewater irrigation on chemical and physical properties of Petroselinum crispum.Effects of irrigation with wastewater on the physiological properties and heavy metal content in Lepidium sativum L. and Eruca sativa (Mill.).Phytofiltration of arsenic and cadmium from the water environment using Micranthemum umbrosum (J.F. Gmel) S.F Blake as a hyperaccumulator.Accumulation of heavy metals in Spinacia oleracea irrigated with paper mill effluent and sewage.Metal translocation patterns in Solanum melongena grown in close proximity to traffic.Effect of mercury and arsenic from industrial effluents on the drinking water and comparison of the water quality of polluted and non-polluted areas: a case study of Peshawar and Lower Dir.Oxidative Stress and Heavy Metals in Plants.Heavy metals bioconcentration from soil to vegetables and appraisal of health risk in Koka and Wonji farms, Ethiopia.Heavy-metal-contaminated industrial soil: Uptake assessment in native plant species from Brazilian Cerrado.Arsenic Uptake and Accumulation in Okra (Abelmoschus esculentus) as Affected by Different Arsenical Speciation.Copper Uptake Efficiency and Its Distribution Within Bioenergy Grass Giant Reed.Phytoremedial Potential of Typha latifolia, Eichornia crassipes and Monochoria hastata found in Contaminated Water Bodies Across Ranchi City (India).Cadmium, copper, and lead accumulation and bioconcentration in the vegetative and reproductive organs of Raphanus sativus: implications for plant performance and pollination.Effect of two biodegradable chelates on metals uptake, translocation and biochemical changes of Lantana Camara growing in fly ash amended soil.Proteome characterization of copper stress responses in the roots of sorghum.Phytoextraction potential of Prosopis juliflora (Sw.) DC. with specific reference to lead and cadmium.Cadmium uptake by radishes from soil contaminated with nickel-cadmium batteries: toxicity and safety considerations.Forage and rangeland plants from uranium mine soils: long-term hazard to herbivores and livestock?Plants as models for chromium and nickel risk assessment.Phytoextraction of heavy metals by potential native plants and their microscopic observation of root growing on stabilised distillery sludge as a prospective tool for in situ phytoremediation of industrial waste.
P2860
Q33786633-5BFD7662-09F9-4136-BDFE-6DAE5324931DQ33858678-F9CF8AB6-3068-47A7-BB8F-1A93216BDA2EQ38809150-B07107AD-5A41-4281-84DB-B6A8B7D60294Q40109558-ADF9FA40-C217-4C96-B9CF-ED85A06928E8Q40623246-9848BEA1-2977-4EDA-8C61-71B9511B177FQ43314434-2D7D78B4-4EFD-4628-8F23-44EC87459487Q43330051-2056B984-CBF6-4FA0-8C81-155C2F55425FQ43337466-DAE467FA-ED9B-4112-802F-35126B8C68AEQ43353208-41FC29E6-67F1-41E0-BDFA-B31384AC0881Q43360618-A105E6D8-6522-40C6-8146-8360FDFAB207Q44202114-BB332DEA-A55F-4F40-82C6-9ECB6DBBD29AQ45054449-DFB2ED13-C4C3-4F01-83F6-A8CA906EC7CBQ45158658-3EAF7325-B93F-4A69-954F-6810D012F623Q46285393-15966E71-C576-4A5F-94DD-2EEB435EEF38Q46456291-D3627341-A97A-41E3-B366-5CA09417A8A5Q46599395-D4035553-B70A-4B6A-9B2A-4436D770308EQ46622503-3A45D001-1688-4810-967D-4A704BE1235CQ46694385-07161B41-CD9E-4E00-8CED-15FE201734DCQ46713744-E7BB84A1-0A44-4D2D-88BA-689858910509Q46748218-08674AF8-4BF6-44C6-AC03-681863CCC819Q47426308-32E782CB-FE47-40D1-A006-6DA084F1930EQ47763272-5321D362-8481-4100-AB60-2943E99C0935Q50521038-5CEBD19F-6A86-4485-9A79-FDD98FF29490Q51139812-674D3482-6DBD-4FF9-9119-3F87D5EBA3EFQ51226749-30CC94F9-CF8E-421D-9B70-D13D46D513E0Q51564970-E1357AE0-18F0-4135-8641-DD669E9A9A96Q52819391-4EBA4F66-72D4-4118-B796-056128158B8D
P2860
Distribution of heavy metals in wheat, mustard, and weed grown in field irrigated with industrial effluents.
description
2000 nî lūn-bûn
@nan
2000年の論文
@ja
2000年学术文章
@wuu
2000年学术文章
@zh-cn
2000年学术文章
@zh-hans
2000年学术文章
@zh-my
2000年学术文章
@zh-sg
2000年學術文章
@yue
2000年學術文章
@zh
2000年學術文章
@zh-hant
name
Distribution of heavy metals i ...... ted with industrial effluents.
@en
Distribution of heavy metals i ...... ted with industrial effluents.
@nl
type
label
Distribution of heavy metals i ...... ted with industrial effluents.
@en
Distribution of heavy metals i ...... ted with industrial effluents.
@nl
prefLabel
Distribution of heavy metals i ...... ted with industrial effluents.
@en
Distribution of heavy metals i ...... ted with industrial effluents.
@nl
P2093
P356
P1476
Distribution of heavy metals i ...... ted with industrial effluents.
@en
P2093
P2888
P304
P356
10.1007/S001280000030
P577
2000-04-01T00:00:00Z