Removal of Phosphate from Aqueous Solutions Using Chemically Synthesized Vaterite Polymorph of Porous Calcium Carbonate Nanoparticles under Optimized Conditions

Abeysooriya, KHD Namal; Abeysooriya, K. H. Dushmantha Namal; Dunuweera, S. P.; Ekanayake, Bhanuka P.K.; Wijenayake, W.M.H.K.; Rajapakse, R.M.G.

doi:10.1155/2020/3931910

Cited by 11 publications

(3 citation statements)

References 52 publications

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“…These tiny particles are likely to be calcium phosphate or hydroxyapatite formed on the surface of the CaO particles by continuously reacting with phosphate ions. This was discussed by Darshana Senarathna et al, 2020 [22] when they applied a vaterite polymorph of porous calcium carbonate nanoparticles to remove phosphate from solutions. The results obtained from the SEM/EDS analysis confirmed the modification of the Ag/CaO-AC and the adsorption of phosphate on the surface of the Ag/CaO-AC nano-composite.…”

Section: Morphology and Elemental Composition Of Nanocompositesmentioning

confidence: 99%

Adsorption of Phosphate by Synthesized Silver/Calcium Oxide-Activated Carbon Nanocomposite

Nyakairu¹,

Ntale²,

Usman³

2023

Adv Environ Eng Res

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Developing adsorbents with appreciable morphology will create new approaches for better phosphate adsorption performance. This study aims to investigate the design of an adsorbent by impregnating silver nanoparticles (AgNPs) onto calcium oxide-activated carbon (CaO-AC). The Ag/CaO-AC nanocomposite was used as an adsorbent to remove phosphate. Batch adsorption studies were performed to evaluate the effects of adsorbent dose, initial phosphate concentration, contact time, and pH on removing phosphate from an aqueous solution. The optimized conditions were applied to a real wastewater sample. The optimum condition for phosphate adsorption on Ag/CaO-AC nanocomposite was at an adsorbent dose of 0.02 g, an initial phosphate concentration of 40 mg∙L<sup>-1</sup>, an equilibrium contact time of 45 minutes, and pH 7. Pseudo-second-order proved to be more accurate in representing the data of phosphate adsorption onto Ag/CaO-AC nanocomposite. The adsorption isotherm fitted well on the Langmuir model with a maximum adsorption capacity of 77.4 mg∙g<sup>-1</sup>. From the kinetics and isotherm studies, chemisorption was the primary adsorption mechanism through ion exchange and ligand exchange mechanisms. The results of this study show that Ag/CaO-AC nanocomposite is a promising adsorbent for removing phosphate from wastewater.

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Section: Morphology and Elemental Composition Of Nanocompositesmentioning

confidence: 99%

Adsorption of Phosphate by Synthesized Silver/Calcium Oxide-Activated Carbon Nanocomposite

Nyakairu¹,

Ntale²,

Usman³

2023

Adv Environ Eng Res

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“…NanoCaCO 3 demonstrated remarkable phosphorus removal of 100% in treating water collected from Beira Lake, Sri Lanka. [ 11 ] Galan et al [ 12 ] impregnated CuO nanoparticles on activated carbon, which removed 60% of the nitrate via the adsorption process. Besides, research also showed that nanoFe 0 reduced Cr(VI) via adsorption, and it was fitted to the pseudo‐first‐order kinetic model.…”

Section: Introductionmentioning

confidence: 99%

Embedded nanoFeCu for sewage treatment: Laboratory‐scale and pilot studies

et al. 2022

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Bimetallic nanoparticles have been widely studied for wastewater treatment, but the study of nanoFeCu for sewage treatment is minimal. In the previous work, ammonia was removed by nanoFeCu via an oxidation reaction, and nitrogen gas was released. However, the performance and reusability of nanoFeCu in treating industrial wastewater have not been reported elsewhere. This study revealed the performance of nanoFeCu for sewage treatment on both laboratory‐scale and pilot‐scale for the first time. A varied mass of embedded nanoFeCu (eFeCu4) was exposed to sewage water, and the quality of the effluent was measured in terms of ammonia, biological oxygen demand (BOD), and chemical oxygen demand (COD) removal. Fe2+ and Cu2+ concentrations were measured to determine the stability of eFeCu4 in nine reuse cycles. Results showed that the laboratory‐scale experiment removed 20%–30% ammonia from sewage. A similar removal rate was reported in all nine cycles of reuse, which confirmed the usability and reliability of eFeCu4. In the pilot‐scale study, ammonia was removed from ~22.3 to ~4.8 mg/L, while BOD and COD were reduced from ~204 to ~56 mg/L and ~71 to ~39.7 mg/L, respectively. The treated effluent quality complies with the effluent discharge standard of Malaysia, and it is also comparable with the effluent quality at sewage treatment plants in Malaysia and overseas. In conclusion, nanoFeCu could be an alternative method for sewage treatment due to its stability and pollutant removal performance. A sustainability and cost‐effectiveness study should be conducted to determine the feasibility of a full‐scale application.

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“…and improved the effluent quality (Stefanakis et al 2009, Bruch et al 2011Stefanakis and Tsihrintzis 2012). Furthermore, porous vaterite calcium carbonate nanoparticles (PVCCNPs) and vaterite polymorph of porous calcium carbonate nanoparticles (VPCCNPs) can be used to remove fluoride from drinking water and phosphate in natural water, respectively (Abeykoon et al 2020;Darshana-Senarathna et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Experiments on Fluometuron Removal from Simulated Agricultural Wastewater in Porous Media Filters

2021

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Six gravity filters were constructed and evaluated for the treatment of water contaminated with herbicide fluometuron. Two filter types in terms of feeding strategy (i.e., batch and continuous feeding strategies), three porous media (i.e., coarse gravel (CG), coarse zeolite (CZ) and fine zeolite (FZ)), and three hydraulic residence times (i.e., 1 day, 2 days and 4 days) were evaluated to find the best design and operation parameter in fluometuron removal by adsorption on the porous media. Batch experiments were also conducted and the experimental data were fitted to adsorption kinetic and isotherm models. Results showed that the experimental data fitted better to the pseudo-first-order model for the three porous media tested and the ranking order of the fluometuron adsorption capacities was FZ>CZ>CG. The results also showed that fluometuron adsorption capacities were better fitted to the Freundlich model for both CZ and FZ porous media, and in all cases, the 1/n value was less than 1 indicating that fluometuron adsorption on both media is a favorable physical process. According to the Freundlich model, the highest fluometuron adsorption was recorded for fine zeolite (2.29 mg/kg). The results of filter operation indicated that the FZ unit with continuous feeding strategy at HRT of 2 days and 4 days achieved the highest fluometuron removal (34.2%) and that the most important parameter affecting fluometuron removal is the hydraulic residence time. KeywordsPesticides • Hydraulic residence time • Gravity filters • Adsorption kinetic models • Freundlich and Langmuir isotherms Highlights • Batch and continuous gravity filters are used to remove fluometuron • Kinetic and isotherm models on fluometuron adsorption are presented • Adsorption on the porous media was the main process of herbicide removal • The hydraulic residence time (HRT) of 4 days was adequate for fluometuron removal • The FZ-C unit at HRT of 2 and 4 days showed the highest removal capacity * Zisis Vryzas

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Removal of Phosphate from Aqueous Solutions Using Chemically Synthesized Vaterite Polymorph of Porous Calcium Carbonate Nanoparticles under Optimized Conditions

Cited by 11 publications

References 52 publications

Adsorption of Phosphate by Synthesized Silver/Calcium Oxide-Activated Carbon Nanocomposite

Adsorption of Phosphate by Synthesized Silver/Calcium Oxide-Activated Carbon Nanocomposite

Embedded nanoFeCu for sewage treatment: Laboratory‐scale and pilot studies

Experiments on Fluometuron Removal from Simulated Agricultural Wastewater in Porous Media Filters

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