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Article

Toxic Metal Adsorption from Aqueous Solution by Activated Biochars Produced from Macadamia Nutshell Waste

by
Minh Trung Dao
1,
T. T. Tram Nguyen
1,
X. Du Nguyen
2,
D. Duong La
3,4,*,
D. Duc Nguyen
5,6,*,
S. W. Chang
6,
W. J. Chung
6 and
Van Khanh Nguyen
7,*
1
Thu Dau Mot University, Thu Dau Mot City, Binh Duong Province, Vietnam
2
Saigon University, Ho Chi Minh City, Vietnam
3
Laboratory of Advanced Materials Chemistry, Advanced Institute of Materials Science, Ton Duc Thang University, Ho Chi Minh City, Vietnam
4
Faculty of Applied Sciences, Ton Duc Thang University, Ho Chi Minh City, Vietnam
5
Institute of Research and Development, Duy Tan University, Da Nang 550000, Vietnam
6
Department of Environmental Energy Engineering, Kyonggi University, Suwon 16227, Korea
7
Department of Microbiology, Pusan National University, Busan 46241, Korea
*
Authors to whom correspondence should be addressed.
Sustainability 2020, 12(19), 7909; https://doi.org/10.3390/su12197909
Submission received: 20 August 2020 / Revised: 9 September 2020 / Accepted: 22 September 2020 / Published: 24 September 2020
(This article belongs to the Special Issue Environmental Remediation)
Browse Figures
Versions Notes

Abstract

:
Abundantly available biomass wastes from agriculture can serve as effective environmental remediation materials. In this study, activated biochar was fabricated from macadamia nutshell (MCN) through carbonization and chemical modification. The resultant biochars were used as adsorbents to remove toxic metal ions such as Cu2+ and Zn2+ from aqueous solutions. The results showed that the activated MCN biochar has a high adsorption capacity for toxic metal ions. When MCN biochar was activated with K2CO3, the adsorption efficiencies for Cu2+ and Zn2+ were 84.02% and 53.42%, respectively. With H3PO4 activation, the Cu2+- and Zn2+-adsorption performances were 95.92% and 67.41%, respectively. H2O2-modified MCN biochar had reasonable Cu2+- and Zn2+-adsorption efficiencies of 79.33% and 64.52%, respectively. The effects of pH, adsorbent concentration and adsorption time on the removal performances of Cu2+ and Zn2+ in aqueous solution were evaluated. The results exhibited that the activated MCN biochar showed quick adsorption ability with an optimal pH of 4 and 4.5 for both Cu2+ and Zn2+, respectively.

1. Introduction

The rapid and continuous growth of industrialization and urbanization has caused serious environmental problems. Of these, contamination of water sources with toxic metals has attracted considerable interest from scientists and governments worldwide. Toxic metal ions—even at trace levels—can be extremely harmful to human health and ecosystems [1,2]. Therefore, the removal of toxic metal ions from aqueous solutions requires urgent attention. Many techniques have been effectively used for the removal of toxic metals ions from polluted wastewater, including, but not limited to, precipitation, use of filtration membranes, chemical treatment, reverse osmosis, electrochemical treatment and adsorption [3,4,5]. Among these methods, adsorption has been demonstrated as an effective pathway for the removal of toxic ions from contaminated water because of its low operation cost, high performance and simplicity.
Many materials and resources have been employed as adsorbents. For example, biomass waste, industrial waste, carbon-based nanomaterials, oxides, natural and synthetic polymers and surfactants have been used for remediation of toxic metal contamination [6,7,8]. Biochar, a common carbon-based group of nanomaterials derived from biomass, has a microporous structure with high surface area, many reactive sites on the surface and high adsorption capacity [9], and therefore, it is extensively used as an effective and affordable adsorbent of metal ions [10]. Biochar is obtained from the thermochemical decomposition of biomass [11,12]. The factors that decide the quality of biochar products are heat treatment time, temperature, type of natural resources and limited oxygen condition [13]. Abundant natural wastes such as cocoa husks, corn cob, rice husks, sludge, coconut shell, seeds, fruits, straws, leaves, orange peel, and other residuals are used to produce biochar for the effective removal of toxic metal ions [14,15,16].
The macadamia nut was first discovered in Southern Australia by botanists in 1857, and thereafter, it has been widely grown worldwide as a high-value agricultural product. Approximately 70–77% of a macadamia nut is the nutshell, which means that one ton of macadamia kernel produces an average of approximately three tons of nutshell [17]. With an annual estimated production of 44,000 tons of macadamia kernels, more than 120,000 tons of macadamia nutshell are discarded as solid waste per annum. This large amount of solid waste needs to be treated—or could be used for various applications [18]. One of the important recycling processes of macadamia nutshell is to produce biochar, which is used as activated carbon for adsorption or charcoal for heating purposes [19,20]. With high surface area and carbon content, the carbon material produced from the macadamia nutshell is of lower ash content than that of other biomass materials. Macadamia-derived biochar has been successfully employed in various applications such as when combined with other types of biochars to form denitrification agents in bioreactors [21], for soil amendment and nutrient control in agriculture [22,23] and for the production of steel [24]. In order to enhance the surface area of the biochar, which increases the adsorption capacity, the biochar has to activate either by physical or chemical methods. Among these, chemical activations. Among these, chemical activation is one of the most favorites techniques to obtain the desirable adsorption capability of biochar for the pollutant treatment in practical [25,26]. Rodrigues et al. also fabricated activated carbon from macadamia nutshell and used it as an adsorbent for the effective removal of organic solvents such as phenol [27]. The macadamia-based biochars were also successfully employed for the removal of toxic metal ions [28,29,30,31,32]. However, the application of macadamia nutshell-derived biochar solely for the removal of Zn2+ and Cu2+ seems to be scarce. Furthermore, the need for finding an effective activation and/or chemical modification protocol to produce activated carbon from the macadamia nutshell is crucial.
Thus, this work presents an effective protocol to fabricate chemically modified biochar from macadamia nutshells through carbonization and chemical activation. In these works, the common and widely available basic chemicals such as K2CO3, H3PO4 and H2O2 were used to activate the MCN biochar. The resultant biochar is employed as an adsorbent for the removal of Cu2+ and Zn2+ from an aqueous solution. The effects of several factors on the adsorption performance such as pH of the solution, concentration, and adsorption time were investigated in detail.

2. Materials and Methods

2.1. Materials

Stock solutions of Cu2+ and Zn2+ with concentrations of 30 ppm each, K2CO3, H3PO4 and H2O2 were purchased from Xilong Scientific Co., Ltd., Shantou, China. Macadamia nutshells (MCN) were obtained as biomass waste from the Lam Dong Province, Vietnam. All chemicals (except macadamia nutshells) were used as received without any purification.

2.2. Fabrication of Modified MCN Biochar from Macadamia Nutshells

Macadamia nutshells were collected as biomass waste and then washed thoroughly and dried before the carbonization process. Typically, MCN nutshells with uniform size were cleaned and thoroughly rinsed with distilled water, then dried at a temperature of 110 °C for 48 h. After primary treatment, the MCN nutshells were calcined at a temperature of 350 °C for 1 h with a heating rate of 23 °C per minute to form MCN charcoal.
K2CO3-modified MCN biochar: MCN charcoal was immersed and agitated in K2CO3 solution with a charcoal:K2CO3:water ratio of 1:1:10 for 24 h. The precipitate was filtered and dried at 110 °C for 24 h. The K2CO3-modified MCN charcoal was then carbonized in the furnace for 1 h at a temperature of 650 °C. The obtained samples were washed thoroughly with distilled water until the pH reached 7 and then dried at 110 °C. Samples were ground to fine particles and stored in a vacuum for further characterization.
H3PO4-modified MCN biochar: MCN charcoal was immersed and agitated in H3PO4 solution for 24 h with a charcoal:H3PO4:water ratio of 1:1:10. The precipitate was filtered and dried at 170 °C for 1 h. The K2CO3-modified MCN charcoal was then carbonized in the furnace for 1 h at a temperature of 500 °C. The obtained samples were washed thoroughly with distilled water until the pH reached 7, then they were dried at 110 °C. Samples were ground to fine particles and stored in a vacuum for further characterization.
H2O2-modified MCN biochar: MCN charcoal was immersed and agitated in H2O2 25% solution continuously for 48 h with charcoal:H2O2 25% ratio of 1:10. After modification, the samples were washed with distilled water until neutral pH and dried at a temperature of 110 °C. Samples were ground to fine particles and stored in a vacuum for further characterization.

2.3. Toxic Metal Adsorption Studies

Effect of pH of the solution: The toxic metal ions employed in this study were Cu2+ and Zn2+ with a concentration of 30 ppm each. In the typical experiment, the modified-MCN biochar with a concentration of 0.3 g/L was added to 50 mL of Cu2+ or Zn2+ 30 ppm with the pH of the solution adjusted from 2.5 to 5.5. The adsorption time was 1 h. The precipitates were separated, and the residual was used to measure the remaining ions in the solution. The experiments were repeated three times.
Effect of biochar content: The modified-MCN biochar with the concentration ranging from 0.2 g/L to 2 g/L was added to 50 mL of Cu2+ or Zn2+ 30 ppm with the pH of the solution of 5.5. The adsorption time was 1 h. The precipitates were separated, and the residual was used to measure the remaining ions in the solution. The experiments were repeated three times.
Effect of adsorption time (adsorption kinetics): The modified-MCN biochar with the concentration of 0.3 g/L was added to 50 mL of Cu2+ or Zn2+ 30 ppm with the pH of the solution of 5.5. The adsorption time was from 0 min to 120 min. The precipitates were separated, and the residual was used to measure the remaining ions in the solution. The experiments were repeated three times.

2.4. Characterization of Biochars

The infrared absorption spectrum determines the FT-IR molecular functional group using the Perkin Elmer spectrophotometer with a resolution of 2 cm−1 and 16 scans (PerkinElmer, Inc., Waltham, MA, USA). All the spectra were recorded in the transmittance mode [33]. SEM particle size measurement and surface observation were conducted using a scanning electron microscope (SEM; JEOL, Ltd., Tokyo, Japan) at 2.0 kV and 10 µA. The samples were coated with gold powder before the images were captured. pH was measured directly using a pH meter (Mettler Toledo—S220K, Mettler Toledo, Greifensee, Switzerland).

3. Results and Discussion

3.1. SEM Image and FTIR Spectrum of the Modified-MCN Biochar

The morphology of the prepared modified-MCN biochar was observed using SEM and the result is shown in Figure 1a. It is evident that the prepared modified-MCN biochar has a porous microstructure with an average pore size of 10 µm. The appearance of the pore structures is due to the etching caused by the activating agent such as H3PO4 as well as the activating condition at high temperatures. The chemical surface properties of the resultant biochar were investigated using an FTIR spectrum (Figure 1b). In the FTIR spectrum, the appearance of the vibration bands at 700 cm−1 and 400 cm−1 represents the stretching oscillation of the C=C functional group, which indicates that the C content increases in the biochar [34]. The vibration band at the wavelength of 3426.4 cm−1 is ascribed to the OH stretching in the functional hydroxyl group, which is favorable for the metal ion adsorption [35]. The functional carbonyl groups (C–O and C=O) on the surface of biochar are also observed in the wavelength range of 1000 cm−1 to 2000 cm−1 of the FTIR spectrum, which indicates that the surface of the MCN biochar was successfully modified with the functional groups thereby improving the adsorption capability of the MCN biochar. The surface area of the modified-MCN biochar was determined to be 339,262 m2/g, which is reasonable for adsorption application.

3.2. Adsorption of Cu2+ by Modified-MCN Biochar

It is well-known that the pH of the solution plays a significant role in the adsorption behavior of the Cu2+, which is related to the dissolution and precipitation of copper [36]. With a pH of less than 6, copper is mostly present in the aqueous solution as ions, however, when the pH of the solution >6, copper ions tend to precipitate [37]. Thus, to study adsorption behavior, the pH of the solution of <6 was selected. Figure 2 presents the Cu2+ adsorption performance by the modified-MCN biochars with various pH values of the solution for one hour with the adsorbent dose of 0.3 g/L. The figure clearly shows that the adsorption capabilities of Cu2+ by MCN biochars modified with K2CO3, H3PO4 and H2O2 increases along with an increase in the pH of the solution. The Cu2+ removal percentages significantly increased from the pH of the solution of 2.5 to 4. Further, an increase in pH from 4–5.5 witnesses a negligible increase in adsorption efficiencies. For the K2CO3-modified MCN biochar, the removal percentages of Cu2+ at pH values of 4, 4.5, 5 and 5.5 were 22.66%, 28.27%, 32.61% and 33.85%, respectively, indicating that the optimal pH for Cu2+ removal by the K2CO3-modified MCN biochar was 5–5.5. When Cu2+ was absorbed by H3PO4-modified MCN biochar, a similar trend in the effect of pH on the adsorption performance was also observed and the maximum adsorption of ions was 55% obtained at a pH of 5–5.5. Therefore, a pH of the solution of 5.5 was optimal for the maximum Cu2+ adsorption of 76%. These results are consistent with that of previous studies [38,39]. It is relevant to note that the MCN biochar modified by H2O2 showed the highest Cu2+ removal in comparison with that modified by K2CO3 and H3PO4.
The concentrations of the adsorbents had significant impacts on the Cu2+ and Zn2+ adsorption performances of the activated biochar. Figure 3 shows the Cu2+ adsorption efficiency of chemically modified MCN biochars with a pH of the solution of 5 and an adsorption time of 1 h. The adsorption capacities of MCN biochars activated with K2CO3, H2O2 and H3PO4 increased along with adsorbent concentrations. For the K2CO3-activated MCN biochar, the Cu2+ adsorption efficiency increased remarkably with dosed of 0.2–1.4 g/L. It gradually increased with dosage before reaching the maximum of 84.96% of Cu2+ removal at the adsorbent concentration of 2 g/L. Similar trends could also be observed with H2O2 and H3PO4-activated MCN biochars, where the Cu2+ adsorption efficiencies increase with an increase of adsorbent concentrations and reaching a maximum of 80.50% and 94.53% at a concentration of 2 g/L H2O2 and H3PO4-activated MCN biochars, respectively. With the dose of 2 g/L, the MCN biochars modified with H3PO4 exhibited the highest Cu2+ removal efficiency in comparison with that modified with H2O2 and K2CO3.
Figure 4 shows the effect of adsorption time on the Cu2+ removal efficiencies by the modified MCN biochars with an adsorbent content of 2 g/L, Cu2+ concentration of 30 ppm and solution pH of 5. It can be clearly seen that the optimal time to adsorb Cu2+ by the MCN biochars activated with K2CO3 was 30 min with an efficiency of 84.02%, which became saturated at 40 min of processing time at a removal efficiency of 86.35%, after which the treatment efficiency increased insignificantly at 50 min to 87.85% and slightly decreased at 1 h to 87.81%. Research results determined that pH = 5, a dosage of 2 g/L, and a processing time of 30 min was optimal for treating Cu2+. Thus, it shows that K2CO3-activated MCN biochar could be used effectively as an adsorbent for the treatment of toxic Cu2+ in textile wastewater. Badruddoza et al. (2011) [33] found that that after 30 min of treatment, the processing efficiency of Cu2+ using carboxymethyl-cyclodextrin conjugated magnetic nanoparticles had a similar treatment performance of 90% removal. Research results from Singha and Das (2013) [40] showed that after 5 h of treatment, the efficiency of Cu2+ treatment at pH 6 using activated carbon from coconut shell was approximately 90%.
For the MCN biochar modified with H3PO4 the Cu2+ removal efficiencies with reaction times of 0, 10, 20, 30, 40, 50 min and one hour were determined to be 0, 85.08%, 92.58%, 93.21%, 95.92%, 96.12%, 96.14% and 96.03%, respectively. This indicates that the H3PO4-activated MCN biochar has a quick absorbing capability for Cu2+ with the highest efficiency of 96.14% after 50 min of adsorption time. When activated with H2O2, the MCN biochar also reveals fast removal of Cu2+ as 51.58% is removed only after 10 min. The optimized adsorption time for Cu2+ treatment using H2O2-activated MCN biochar is one hour with the highest Cu2+ removal efficiency of 80.9%. It can be concluded that the MCN biochar activated with H3PO4 and K2CO3 show faster Cu2+ adsorption efficiencies than that activated with the H2O2 agent.

3.3. Adsorption of Zn2+ by Modified-MCN Biochar

The pH of the solution had a significant effect on Zn2+ adsorption performance of biochar. Thus, the effect of pH of the solution on the removal efficiency of Zn2+ by the modified-MCN biochar for one hour with the adsorbent dose of 0.3 g/L was investigated as shown in Figure 5. In general, the adsorption capabilities of Zn2+ by MCN biochars modified with K2CO3, H3PO4, and H2O2 decreased at a low pH of the solution of 2 to 3, reached a minimum value at a pH 2.5–3, then significantly increased in a pH of 3.5–5. The adsorption of Zn2+ by MCN biochars activated with K2CO3 decreased with the increase in the pH of the solution from 2 to 3 and reached a minimal removal concentration of 2.63 ppm at a pH of 3. Further increases in the pH of the solution demonstrated an increase in the adsorption capabilities of biochar; it reached a maximum at the pH of 4.5 with a removal concentration of 4.85 ppm. A similar trend was also observed with the adsorption behaviors of the H2O2-modified biochar with the change in the pH of the solution from 2 to 5. A Zn2+ removal concentration of 2.18 ppm was achieved at a pH of 3 and a maximum of 6.27 ppm at a pH of 4.5. Interestingly, for the H3PO4-activated macadamia biochar, the lowest Zn2+ removal concentration was observed to be 1.33 ppm at the pH of 2.5 and the highest removal efficiency was at the pH of 4.5 with a removal concentration of 6.05 ppm. These results indicate that the most suitable pH solution for the removal of Zn2+ from the aqueous solution by activated macadamia biochar was around 4.5 and the H2O2-activated biochar reveals the highest Zn2+ adsorption capability.
Figure 6 shows the effect adsorbent concentrations of the chemically modified MCN biochars on the removal performance of Zn2+ from the aqueous solution at a pH of 4.5 for one hour. The Zn2+ removal concentrations increased with the increase in adsorbent dosed. For the K2CO3-activated biochar as adsorbent, Zn2+ removal increased significantly in the adsorbent doses ranging from 0.2 g/L to 2 g/L and reaches a maximum at the adsorbent dose of 2 g/L with the highest removal percentage of 45.80%. However, compared to the removal efficiency of 1.8 g/L (45.29%), this value was not significant, and thus, the optimal K2CO3-activated biochar concentration for cost-effective adsorption of Zn2+ adsorption was determined to be 1.8 g/L. This trend was also observed with H2O2 and H3PO4-activated MCN biochars as the optimal adsorbent doses were determined to be 1.8 g/L for Zn2+ adsorption efficiencies of 57.3% and 65.56%, respectively.
Figure 7 shows the effect of adsorption time (0 min to 120 min) on the Zn2+ removal efficiencies of the chemically modified MCN biochars with the adsorbent content of 1.8 g/L, Zn2+ concentration of 30 ppm, and a pH of 4.5. Unlike the removal of Cu2+, for which the chemically activated macadamia biochars showed high adsorption speed reaching the equilibrium state only after 30 min, in this case, the adsorption ability of the biochars for Zn2+ oxides were relatively slow. The Zn2+ adsorption efficiencies of K2CO3, H2O2 and H3PO4-modified macadamia biochars only reached the equilibrium value after 80 min of adsorption time with the removal concentrations of 12.22 ppm, 15.48 ppm and 16.42 ppm, respectively.
The results discussed above lead to the conclusion that the macadamia biochars activated with H3PO4 show the highest and fastest Zn2+ and Cu2+ adsorption performances, and therefore, can be employed as effective adsorbents for the removal of metal ions from aqueous media.
It is clear from the above results that the MCN biochars activated with H3PO4 reveal the highest removal efficiency toward Cu2+ and Zn2+. The adsorption capacity can be roughly estimated with the following equation:
q e = ( C 0 C e ) × V m
where C0 (mg/L) is the initial concentration, Ce (mg/L) is the equilibrium concentration, V (L) is the solution volume and m (g) is the mass of the activated MCN biochars. Based on the investigation of adsorbent dosage on the removal efficiency toward Cu2+ and Zn2+ with the adsorption dosage of 0.2 g/L, Cu2+ and Zn2+ concentration of 30 mg/L, the adsorption capacity of activated MCN biochars for Cu2+ and Zn2+ are 2.825 and 2.1 mg/g, respectively. These results are slightly higher than the adsorption capacity of the biochar fabricated from the rice husk for the Cu2+ and Zn2+ removal [41].

4. Conclusions

To summarize, the macadamia biochar was successfully fabricated and modified with K2CO3, H2O2 and H3PO4. The modified-MCN biochars have porous microstructures with an average pore size of 10 µm. The resultant chemically modified biochars were used as adsorbent and they show high Cu2+ and Zn2+ adsorption performances. The effect of several factors such as the pH of the solution, adsorption time and adsorbent doses were investigated in detail. The results showed that the optimized pH of the solution, adsorbent doses and adsorption time for the removal for Cu2+ and Zn2+ are 5, 2 g/L and 30 min and 4.5, 1.8 g/L and 80 min, respectively. Of the three K2CO3, H2O2 and H3PO4 modifiers, the macadamia biochars activated with H3PO4 had the highest Cu2+ and Zn2+ adsorption performances. With high adsorption efficiencies and inexpensive fabrication from biomass waste, chemically activated macadamia biochar can be used as a promising adsorbent for the effective removal of toxic metal ions in practical applications.

Author Contributions

Conceptualization, M.T.D., D.D.L., D.D.N. and V.K.N.; methodology, M.T.D., T.T.T.N. and X.D.N.; software, M.T.D. and W.J.C.; investigation, M.T.D., D.D.L., D.D.N. and V.K.N.; data curation, M.T.D., T.T.T.N., and X.D.N.; writing—original draft, M.T.D. and D.D.L.; writing—reviewing scientific contents and editing, S.W.C. and W.J.C. All authors have read and agreed to the published version of the manuscript.

Funding

This research is funded by Thu Dau Mot University under grant number ĐT.20-014.

Acknowledgments

The authors are grateful to the research collaboration among universities, institutes and groups of authors.

Conflicts of Interest

The authors declare no conflict of interest exits in the submission of this manuscript.

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Figure 1. (a) SEM image and (b) FTIR spectrum of the modified-macadamia nutshell biochar.
Figure 1. (a) SEM image and (b) FTIR spectrum of the modified-macadamia nutshell biochar.
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Figure 2. Effect of pH of the solution on Cu2+ adsorption by chemically modified MCN biochars at the adsorbent dose of 0.3 g/L and adsorption time of one hour.
Figure 2. Effect of pH of the solution on Cu2+ adsorption by chemically modified MCN biochars at the adsorbent dose of 0.3 g/L and adsorption time of one hour.
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Figure 3. Effects of concentration of chemically modified MCN biochars on Cu2+ adsorption performance with an adsorption time of one hour and pH of the solution of 5.
Figure 3. Effects of concentration of chemically modified MCN biochars on Cu2+ adsorption performance with an adsorption time of one hour and pH of the solution of 5.
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Figure 4. Effect of adsorption time on Cu2+ removal efficiencies using activated MCN biochars with an adsorbent dose of 2 g/L at a solution pH of 5.
Figure 4. Effect of adsorption time on Cu2+ removal efficiencies using activated MCN biochars with an adsorbent dose of 2 g/L at a solution pH of 5.
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Figure 5. Effect of pH of the solution on Zn2+ adsorption by chemically modified MCN biochars with an adsorbent dose of 0.3 g/L and adsorption time of one hour.
Figure 5. Effect of pH of the solution on Zn2+ adsorption by chemically modified MCN biochars with an adsorbent dose of 0.3 g/L and adsorption time of one hour.
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Figure 6. Effects of concentrations of chemically modified MCN biochars on Zn2+ adsorption performance with an adsorption time of one hour and pH of the solution of 4.5.
Figure 6. Effects of concentrations of chemically modified MCN biochars on Zn2+ adsorption performance with an adsorption time of one hour and pH of the solution of 4.5.
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Figure 7. Effect of adsorption time on Zn2+ removal efficiencies by activated MCN biochars with an adsorbent dose of 1.8 g/L at a pH of 4.5.
Figure 7. Effect of adsorption time on Zn2+ removal efficiencies by activated MCN biochars with an adsorbent dose of 1.8 g/L at a pH of 4.5.
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Dao, M.T.; Nguyen, T.T.T.; Nguyen, X.D.; La, D.D.; Nguyen, D.D.; Chang, S.W.; Chung, W.J.; Nguyen, V.K. Toxic Metal Adsorption from Aqueous Solution by Activated Biochars Produced from Macadamia Nutshell Waste. Sustainability 2020, 12, 7909. https://doi.org/10.3390/su12197909

AMA Style

Dao MT, Nguyen TTT, Nguyen XD, La DD, Nguyen DD, Chang SW, Chung WJ, Nguyen VK. Toxic Metal Adsorption from Aqueous Solution by Activated Biochars Produced from Macadamia Nutshell Waste. Sustainability. 2020; 12(19):7909. https://doi.org/10.3390/su12197909

Chicago/Turabian Style

Dao, Minh Trung, T. T. Tram Nguyen, X. Du Nguyen, D. Duong La, D. Duc Nguyen, S. W. Chang, W. J. Chung, and Van Khanh Nguyen. 2020. "Toxic Metal Adsorption from Aqueous Solution by Activated Biochars Produced from Macadamia Nutshell Waste" Sustainability 12, no. 19: 7909. https://doi.org/10.3390/su12197909

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