Metal ion remediation by polyamidoamine dendrimers: a comparison of metal ion, oxidation state, and titania immobilization

Castillo, Vanessa A.; Barakat, M.A.; Ramadan, Mohamed H.; Woodcock, H. Lee; Kuhn, John N.

doi:10.1007/s13762-013-0346-5

Cited by 15 publications

(3 citation statements)

References 41 publications

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“…In this context, there are few reports that have studied the effect of oxidation number of heavy metals in the adsorption process and particularly, the works related with the adsorption by complexation mechanism have considered this property. For example, in the removal of Ni 2+ , Fe 2+ and Fe 3+ (with external hydroxyl functional groups) was demonstrated that high-valence species complex more quickly than the lowvalence due to the ability to accept more of the ligand's electron donation, where the adsorption followed the trend Ni 2+ > Fe 3+ > Fe 2+ [70].…”

Section: Adsorbate Properties and Adsorption Conditionsmentioning

confidence: 99%

Removal of Heavy Metals Using Adsorption Processes Subject to an External Magnetic Field

Virgen¹,

Vázquez²,

Montoya³

et al. 2018

Heavy Metals

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Adsorption is a broadly used process for the removal of heavy metals and the world trend is directed to the application of new technologies to intensify existing processes. The properties of the magnetic field (intensity and arrangement) and the intrinsic magnetic properties of the adsorbent and the adsorbate are decisive for satisfactory results. The intensity of the magnetic field is important, because this implies that the greater number of spins present will align with the magnetic field according to the magnetic nature present, allowing the mobility of the adsorbate and generating heterogeneity on the surface of the adsorbent. Similarly, the arrangement of the magnetic field will determine the direction of the magnetic field lines. The application of a magnetic field as an alternative for the intensification of the adsorption process based on the consideration that the magnetic field is safe, environmentally friendly and economic.

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Section: Adsorbate Properties and Adsorption Conditionsmentioning

confidence: 99%

Removal of Heavy Metals Using Adsorption Processes Subject to an External Magnetic Field

Virgen¹,

Vázquez²,

Montoya³

et al. 2018

Heavy Metals

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show abstract

“…Figure 2 suggests the removal mechanism of positive metal ions through dendrimers-Ti composite. Castillo et al [14] studied the removal capacity of Ni and Fe oxidation states utilizin 4th generation PAMAM with the G4-OH group. They also investigated the influence o G4-OH immobilization on Ti enhanced materials and their chelating potential on Ni(I removal.…”

Section: Titanium Supported Dendrimersmentioning

confidence: 99%

A Comprehensive Review of Polymeric Wastewater Purification Membranes

Singh

Kumari

et al. 2021

J. Compos. Sci.

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Synthetic membranes are currently employed for multiple separation applications in various industries. They may have been prepared from organic or inorganic materials. Present research majorly focuses on polymeric (i.e., organic) membranes because they show better flexibility, pore formation mechanism, and thermal and chemical stability, and demand less area for installation. Dendritic, carbon nanotube, graphene and graphene oxide, metal and metal oxide, zwitter-ionic, and zeolite-based membranes are among the most promised water treatment membranes. This paper critically reviews the ongoing developments to utilize nanocomposite membranes to purify water. Various membranes have been reported to study their resistance and fouling properties. A special focus is given towards multiple ways in which these nanocomposite membranes can be employed. Therefore, this review provides a platform to develop the awareness of current research and motivate its readers to make further progress for utilizing nanocomposite membranes in water purification.

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“…Metals can become mobilized, leading to soil and groundwater contamination that increase the possibility of entering into the food chain and finally into the human body (Taghipour et al 2013;Shaheen et al 2014a, b, c). Thus, remediation of PTMs in contaminated soils has received increasing attention and is an important issue for adequate environmental management (Ok et al 2011a;Castillo et al 2014;Shaheen et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Impact of various amendments on immobilization and phytoavailability of nickel and zinc in a contaminated floodplain soil

Shaheen

Rinklebe

Selim

2014

Int. J. Environ. Sci. Technol.

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The immobilization of toxic metals in soils using amendments is a cost-effective remediation technique for contaminated soils. Therefore, this study aimed to assess the efficiency of various amendments to immobilize nickel (Ni) and zinc (Zn) in soil and reduce their phytoavailability. A greenhouse pot experiment was established with a contaminated agricultural floodplain soil. The soil was treated with activated carbon (AC), bentonite (BE), biochar (BI), cement bypass kiln dust (CBD), chitosan (CH), coal fly ash (FA), limestone (LS), nano-hydroxyapatite (HA), organo-clay (OC), sugar beet factory lime (SBFL), and zeolite (Z) with an application rate of 1 % (0.2 % for HA) and cultivated by rapeseed (Brassica napus). After plant harvesting, the soil was analyzed for water-soluble and geochemical fractions of Ni and Zn. Additionally, both metals were analyzed in the aboveground biomass. Application of the amendments increased significantly the biomass production of rapeseed compared to the control (except for OC, HA, and FA). Water-soluble Ni and Zn decreased significantly after adding the amendments (except OC, Z, and CH). The SBFL, CBD, LS, BE, AC, and BI were most effective, resulting in a 58-99 and 56-96 % decrease in water-soluble Ni and Zn, respectively. The addition of SBFL, CBD, and LS leads to the highest decreasing rate of concentrations of Ni in plants (56-68 %) and Zn (40-49 %). The results demonstrate the high potential of CBD, SBFL, LS, BE, AC, and BI for the immobilization of Ni and Zn in contaminated floodplain soils.

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Metal ion remediation by polyamidoamine dendrimers: a comparison of metal ion, oxidation state, and titania immobilization

Cited by 15 publications

References 41 publications

Removal of Heavy Metals Using Adsorption Processes Subject to an External Magnetic Field

Removal of Heavy Metals Using Adsorption Processes Subject to an External Magnetic Field

A Comprehensive Review of Polymeric Wastewater Purification Membranes

Impact of various amendments on immobilization and phytoavailability of nickel and zinc in a contaminated floodplain soil

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