TY - JOUR
T1 - Hybrid biochar supported transition metal doped MnO2 composites
T2 - Efficient contenders for lithium adsorption and recovery from aqueous solutions
AU - Kamran, Urooj
AU - Park, Soo Jin
N1 - Publisher Copyright:
© 2021 Elsevier B.V.
PY - 2022/1/15
Y1 - 2022/1/15
N2 - Herein, novel nanocomposites (Nix-MnO2/BC) were synthesized by hybrid biochars (h-BC) that derived from coconut shell and rice husk, and subsequently decorating the surfaces of these h-BC with nickel-doped MnO2 nanorods at various ratios of nickel doping. The as-fabricated Nix-MnO2/BC nanocomposites exhibited efficient Li+ adsorption and desorption performances. Conventional batch adsorption tests were done to optimize parameters: pH, dose, contact time, Li+ initial concentration, and temperature that maximized Li+ uptakes adsorbents efficiency. The Ni0.01-MnO2/BC nanocomposite showed the greatest Li+ uptakes (89 mg g−1) under optimized parameters at ambient temperature. The high capacity of Ni0.01-MnO2/BC nanocomposite for Li+ uptakes arises from the specific extent of Ni-doping, large specific surface area (400 m2 g−1), and high number of accessible active functionalities. Sorption kinetics and isothermal analysis illustrate that, Li+ adsorption mechanism follows pseudo 1st order kinetic and Langmuir model. Based on identified thermodynamic parameters, the adsorption of Li+ on adsorbents was exothermic and spontaneous in nature, signifying the physical adsorption process. Subsequent desorption experiments demonstrate that 98% of the Li+ can be recovered in the desorbing agent. Furthermore, the selective Li+ adsorption and intermediate stable nature of nanocomposites make them suitable contenders for Li+ adsorption and recovery applications at a broad scale.
AB - Herein, novel nanocomposites (Nix-MnO2/BC) were synthesized by hybrid biochars (h-BC) that derived from coconut shell and rice husk, and subsequently decorating the surfaces of these h-BC with nickel-doped MnO2 nanorods at various ratios of nickel doping. The as-fabricated Nix-MnO2/BC nanocomposites exhibited efficient Li+ adsorption and desorption performances. Conventional batch adsorption tests were done to optimize parameters: pH, dose, contact time, Li+ initial concentration, and temperature that maximized Li+ uptakes adsorbents efficiency. The Ni0.01-MnO2/BC nanocomposite showed the greatest Li+ uptakes (89 mg g−1) under optimized parameters at ambient temperature. The high capacity of Ni0.01-MnO2/BC nanocomposite for Li+ uptakes arises from the specific extent of Ni-doping, large specific surface area (400 m2 g−1), and high number of accessible active functionalities. Sorption kinetics and isothermal analysis illustrate that, Li+ adsorption mechanism follows pseudo 1st order kinetic and Langmuir model. Based on identified thermodynamic parameters, the adsorption of Li+ on adsorbents was exothermic and spontaneous in nature, signifying the physical adsorption process. Subsequent desorption experiments demonstrate that 98% of the Li+ can be recovered in the desorbing agent. Furthermore, the selective Li+ adsorption and intermediate stable nature of nanocomposites make them suitable contenders for Li+ adsorption and recovery applications at a broad scale.
KW - Hybrid biochar
KW - Nanocomposites
KW - Nickel doping
KW - Recovery
KW - lithium uptakes
UR - http://www.scopus.com/inward/record.url?scp=85118826582&partnerID=8YFLogxK
U2 - 10.1016/j.desal.2021.115387
DO - 10.1016/j.desal.2021.115387
M3 - Article
AN - SCOPUS:85118826582
SN - 0011-9164
VL - 522
JO - Desalination
JF - Desalination
M1 - 115387
ER -