Figure 7a displays the metal uptake capacity of ZnO nanosheets for Cd(II) obtained from the experiment of adsorption isotherm. Adsorption capacity of ZnO nanosheets for Cd(II) was determined https://www.selleckchem.com/products/lxh254.html to be 97.36 mg g−1. Reported adsorption capacity in this study was found to be comparable with those previously reported for Cd(II) (4.92 [23], 9.39 [24], 84.30 [25], 57.90 [26], 95.20 [27], 123.65 mg g−1[28]) in other studies. In comparison
with the adsorption capacity of ZnO nanosheets toward Cd(II), uptake capacities of other nanostructures for Cd(II) were also previously reported. For example, the adsorption capacity of Cd(II) on MnO2 functionalized multi-walled carbon nanotubes was determined to be 41.60 mg g−1 by Luo et al. [29]. In addition, adsorption selleck capacities of nano B2O3/TiO2 composite material and nanocrystallite hydroxyapatite for Cd(II) were previously evaluated and reported to be 49.00 [30] and 142.86 mg g−1[31]. As discussed above, the adsorption capacity
of nanostructures for Cd(II) may vary. However, ZnO nanosheets possess the most SB273005 concentration important property in its high efficiency and selectivity for Cd(II). Thus, the high selectivity of ZnO nanosheets enables the method for accurate and precise determination of Cd(II) in complex matrices. Figure 6 Schematic view of Cd(II) adsorption process on ZnO nanosheets. Figure 7 Adsorption Urease profile of Cd(II) (a) and Langmuir adsorption isotherm model of Cd(II) adsorption (b). On 25 mg of ZnO nanosheets at pH 5.0 and 25°C. Adsorption experiments were obtained at different concentrations (0 to 150 mg L−1) under static conditions. Adsorption isotherm models Experimental equilibrium adsorption data were analyzed using different models in order to develop an equation that accurately represents
the results. Langmuir equation is based on an assumption of a monolayer adsorption onto a completely homogeneous surface with a finite number of identical sites and a negligible interaction between the adsorbed molecules. The Langmuir adsorption isotherm model is governed by the following relation [7]: (3) where C e corresponds to the equilibrium concentrations of Cd(II) ion in solution (mg mL−1) and q e is the adsorbed metal ion by the adsorbate (mg g−1). The symbols Q o and b refer to Langmuir constants related to adsorption capacity (mg g−1) and energy of adsorption (L mg−1), respectively. These constants can be determined from a linear plot of C e/q e against C e with a slope and intercept equal to 1/Q o and 1/Q o b, respectively.