Modeling the mass transfer in biosorption of Cr (VI) y Ni (II) by natural sugarcane bagasse

Rico, Iván L. Rodríguez; Carrazana, Rafael Jiménez; Karna, Nabin Kumar; Iáñez-Rodríguez, I.; Calero, M.

doi:10.1007/s13201-018-0692-z

Cited by 9 publications

(10 citation statements)

References 31 publications

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“…On the other hand, the desire to use a material that is readily available may be associated with its low effectiveness. It should also be taken into account that natural materials, after the sorption process, may cause the release of soluble organic compounds contained in plant materials (Rico et al 2018;Tapia et al 2018), and thus increase the values of some of the outflowing wastewater's parameters. Candelaria et al (2019) used agroindustrial byproducts to remove nickel and chromium ions.…”

Section: Discussionmentioning

confidence: 99%

“…Lemna gibba (Morales-Barrera et al 2020), Azolla filiculoides (Naghipour et al 2018), Pistia stratiotes or Nymphaea lotus (Ugya et al 2019)) and various plant fragments in their studies. For nickel sorption, both plant parts such as bark (Cancelo-Gonza ´lez et al 2017;Akar et al 2019) or cones (Oguz 2020), and more fragmented parts such as fibers (Boudaoud et al 2017), bagasse (Rico et al 2018;Candelaria et al 2019) and sawdust (Richard et al 2020) were used. Researchers have also used algae (Vetrivel et al 2017;Kipigroch 2018; El-Naggar and Rabei 2020) and fruits (Pertile et al 2020) including their seeds (Aravind et al 2017), shells (Cruz-Lopes et al 2021 or peels (Priyantha and Kotabewatta 2019) to remove metals from aqueous solutions.…”

Section: Trends In Biosorbent Researchmentioning

confidence: 99%

“…Conversely, if it occurs after a chemical interaction between the metal and the cell surface, the process may be independent of cell metabolism. Different functional groups are involved in the biosorption of metals (Rico et al 2018), therefore the pH affecting their charge, and thus the amount of biosorbed metal, is very important. Given that cationic forms are usually among the predominant forms of metals in an aqueous solution, the more negative the charge of the biosorbent, the greater the amount of biosorbed metal.…”

Section: Biosorption Mechanismsmentioning

confidence: 99%

“…The development of biodegradable adsorbents that are low-cost, abundant in nature, and available in large quantities is currently an area of extensive research due to their potential applications in biosorption processes for the removal of nickel (II) ions from water and wastewater. Among them, natural materials like bacteria (Mardiyono et al 2019), fungi biomass (Silah and Gu ¨l 2017), macroalgae (Eka Putri 2019), peat (Charazin ´ska et al 2021), old newspaper fibers (Ossman et al 2016), lemon peel waste (Villen-Guzman et al 2021), peanut hulls (Tapia et al 2018), sugarcane (Rico et al 2018) and palm bagasse (Candelaria et al 2019), surface-engineered yeast (Li et al 2019) have been developed and tested for the removal of nickel metal ions.…”

Section: Introductionmentioning

confidence: 99%

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Recent trends in Ni(II) sorption from aqueous solutions using natural materials

Charazińska

Burszta‐Adamiak

Lochyński

2021

Rev Environ Sci Biotechnol

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The use of materials of natural origin for the adsorption of heavy metal ions from aqueous solutions has gained attention in recent years among the scientific community. This is explained by the fact that nickel compounds, due to severe health consequences, are considered to be among the most dangerous to the environment. This article reviews the results of studies on the use of biosorbents for purification of aqueous solutions from nickel ions, and then attempts to classify them according to their origin. The characteristics of materials and their sorption capacity have been compared, and the removal mechanisms identified of which chemisorption and ion exchange are considered to be the most common. From the analyses, a major trend is the use of biomass; however, biosorbents from other groups also continue to attract the interest of researchers. Conducting laboratory studies can help select materials with high efficiency. The highest sorption capacity values for the materials in each group were: for waste products 56 mg Ni·g−1 (olive stone), for peat 61 mg Ni·g−1, for miscellaneous 225 mg Ni·g−1 (microbial flocculant GA1), for biomass 286 mg Ni·g−1 (Plantanus orientalis bark) and for composites/modified materials calcinated eggshells 769 mg Ni·g−1 (calcinated eggshells). However, for some materials the sorption phenomenon may be accompanied by precipitation in the presence of hydroxides, which significantly affects the sorption capacity achieved. There is a need to transfer these experiments to an industrial scale so as to verify their applicability. In such industrial scale applications, attention should be paid not only to the effectiveness of the material, but also to its availability, price, and ease of use, as well as the effect of the biosorbent in terms of changing the quality parameters of the aquatic environment.

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Section: Discussionmentioning

confidence: 99%

Section: Trends In Biosorbent Researchmentioning

confidence: 99%

Section: Biosorption Mechanismsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Recent trends in Ni(II) sorption from aqueous solutions using natural materials

Charazińska

Burszta‐Adamiak

Lochyński

2021

Rev Environ Sci Biotechnol

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“…Traditional methods of contaminated effluent treatment with Cr(VI) consist of chemical precipitation, filtration, oxidation and chemical reduction, electrocoagulation, reverse osmosis, ultrafiltration, ion exchange, adsorption, evaporation, among others (Razi et al, 2018;Rico et al, 2018;Akram et al, 2016). However, these processes have some limitations due to high energy consumption and large amounts of input chemicals (Wassie and Srivastava, 2016), whereas bio-adsorption is a versatile and effective method to remove heavy metals because it involves the use of low cost and high-efficiency adsorbents.…”

Section: Introductionmentioning

confidence: 99%

Adsorption Thermodynamics of Cr(VI) Removal by using Agro-Industrial Waste of Oil Palm Bagasse and Plantain Peels

2020

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The effect of temperature on the adsorption of Cr (VI) was determined with waste materials from the agroindustry, such as palm bagasse and plantain peels, by determining the thermodynamic parameters which allow to establish the mechanisms that control the process. The methodology included an initial preparation of the biomass, its characterization, and subsequent adsorption tests by setting the initial concentration of the metal to 100 ppm, a particle size of 0,5 mm, a biomass amount of 0,325 g, pH 2, and a volume of 100 mL. The process temperature varied between 303,15, and 352,15 K. The concentration of the remaining metal in the solution was performed using the diphenyl carbazide colorimetric method through a UVVis spectroscopy at a wavelength of 540 nm. The results show that the effect of temperature does not present a defined trend for palm bagasse, whereas it is linear for adsorption using plantain peels. Furthermore, the process of adsorption of Cr (VI) with palm bagasse is more favorable at higher temperatures, since it is a spontaneous process with a physical adsorption mechanism. On the other hand, the adsorption process with plantain peels is thermodynamically feasible at temperatures from 40 to 55 °C and not spontaneous at higher temperatures. Also, a physicochemical adsorption mechanism was evinced. It is concluded that the use of the studied materials is possible in the removal of the Cr (VI) ion in aqueous solutions.

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