Journal of Mechanical Engineering Science and Technology ISSN 2580-0817 

Vol. 4, No.2, November 2020, pp. 115-124  115 

                 DOI: 10.17977/um016v4i22020p115 

Surface Properties and Adsorption Capacities                                                  

of Rice Bran-Activated Carbon  

Dewa Ngakan Ketut Putra Negara1,2*, Tjokorda Gde Tirta Nindhia1,                                   

Wayan Nata Septiadi1                                           

1Mechanical Engineering Department, Udayana University,                                                                             

Jl. Raya Kampus Unud, Bukit Jimbaran, South Kuta, Badung Bali, 80361, Indonesia 
2Master Program of Mechanical Engineering, Udayana University, Jalan P.B. Sudirman, Denpasar Bali, 

80232, Indonesia 

*Corresponding author:devputranegara@unud.ac.id 

ABSTRACT  

The growing need for activated carbon requires alternative raw materials to replace non-renewable raw 

materials whose existence is decreasing. Biomass is a very promising precursor, one of which is from rice 

bran. This research concerns the development of activated carbon derived from rice bran. Carbonization was 

carried out at 600 OC and physically activated with nitrogen flow rates of 150 mL/min for 40, 80, and 120 

minutes. The activated carbons produced (AC-D40, AC-D80, and AC-D120) were characterized to 

determine the surface properties, surface morphology, and adsorption capacity for nitrogen and blue 

methylene adsorptions. The results showed that activated carbon that activated for 80 minutes (AC-D80) 

had the best characteristics. With a pore surface area of 109.389 m2/g, a pore volume of 0.083 cm3/g, and 

pores that mostly distributed in the micropore area, this activated carbon has the highest adsorption for 

nitrogen (53.874 cm3/g) and methylene blue (87.560 mg/g) adsorptions compared to activated carbon with 

activation times of 40 minutes (AC-D40) and 120 minutes (AC-D120). 

Copyright © 2020. Journal of Mechanical Engineering Science and Technology. 

All rights reserved. 

Keywords: Activated carbon, activation, adsorption, characteristic, rice bran, surface 

I.  Introduction 

Activated carbon is an adsorbent that has unique characteristics. It has a high pore 

volume and surface area that causes activated carbon to have high adsorption. Because of its 

high adsorption capacity, activated carbon widely applied in various fields of life such as for 

the purification of water from industrial waste pollutants [1] [2], removal of methylene blue 

[3]-[5], a cathode battery material in electrochemical devices [6], CO2 adsorption [7] [8], 

biogas purification [9] [10], and supercapacitor [11]. 

To be applied optimally, the properties or characteristics of activated carbon and the 

type of adsorbate to be adsorbed must be well known. For instance, for gas storage and 

purification, the surface characteristics of activated carbon such as pore-volume, surface 

area, and distribution of pore size play an important role. In the gas storage process, an 

adsorption process occurs, which is the accumulation of gas molecules on the surface of the 

activated carbon due to the Van der Walls forces. The pore volume, surface area, and pore 

distribution of activated carbon determine the number of gas molecules that can be adsorbed. 

The behavior of porous media such as movement and fluid flow are largely influenced by 

these characteristics. The pore size distribution of activated carbon is the relative pore 



116  Journal of Mechanical Engineering Science and Technology           ISSN 2580-0817 
 Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Properties and Adsorption Capacities of Rice Bran-Activated Carbon) 

volume associated with different pore sizes [12], and in gas storage and separation 

application strongly associated with adsorption capacity [13]. 

The high use of activated carbon demands high availability of activated carbon as well. 

Unfortunately, the raw material for activated carbon generally comes from coal or petroleum 

residue, whose availability is decreasing. Some researchers have started to develop activated 

carbon using raw materials from biomass such as palm-shell [14], rice straw [15], 

agricultural solid wastes [16], chips from spruce and birch [17], and bamboo [18][19]. But 

it is still very minim literature associated with activated carbon made from rice bran. Rice 

bran is a waste from rice milling with a proportion of 10% of the weight of rice harvested  

[20]. The chemical composition and physical element content of rice bran strongly 

determined by rice varieties and environmental factors. 

The characteristics and quality of activated carbon depend on the chemical and physical 

properties of the precursor [21], the activator, the temperature, and the method of activation 

[22]. The process of making activated carbon consists of dehydration of raw materials, 

carbonization, and activation processes. Dehydration is done to reduce the moisture content 

of raw materials. Carbonization is carried out by heating the raw material at a temperature 

of 400-850OC [23] in order to form an initial porosity. Activation is a process to form new 

porosity, widen the porosity that has been formed during the carbonization process and can 

be done without involving agents (physical activation) and by involving agents (chemical 

activation). The purpose of this study was to determine the characteristics and adsorption 

ability of activated carbon derived from rice bran that is physically activated with different 

activation times. 

II. Material and Methods

A. Production of Activated Carbons

The raw material used as activated carbon is rice bran obtained from the home industry

of the rice mill in Banjar Pengaji, Payangan, Gianyar Bali Indonesia, as shown in Figure 1 

(a). Thermo Gravimetric Analyzer (TGA) test results showed that rice bran contained 

15.04% moisture, 62.05% volatile, 13.21% ash, and 9.7% fixed carbon. Rice bran is dried 

under the sunlight for seven days for 5 hours from 10.00 AM to 03.00 PM and meshed with 

60 mesh. The meshed powder was dried in an electric furnace at 105OC for 2 hours. A 20 

gram of dried powder rice bran was loaded into a stainless cylindrical reactor, and the reactor 

was then entered into an electric furnace for furthermore heated to a temperature of 600OC. 

The heating was held at that temperature for 40 minutes, at the same time, an activation 

process was carried out by flowing nitrogen with a flow rate of 150 mL/min. The activated 

carbon cooled in the electric furnace for 12 hours. The same steps were carried out for 

activation times of 80 and 120 minutes. The produced activated carbons were then coded as 

AC-D40, AC-D80, and AC-D120 for the activation period of 40, 80, and 120 minutes, 

respectively. The sample of activated carbon produced is shown in Figure 1(b). 

B. Characterization of Activated Carbons

Characterization carried out included SEM, adsorption isotherm, and methylene blue 

tests. SEM test equipment (JSM-651OLA) was used to observe the activated carbon surface 

morphology. Adsorption isotherm test equipment (The Micromeritics® TriStar II Plus) was 

applied to determine the surface structure of the activated carbon, including pore surface 

area (SBET), pore-volume, and adsorption of nitrogen. Methylene blue test was undertaken 

to determine the adsorption of activated carbon against methylene blue using an Ultra Violet-



ISSN: 2580-0817  Journal of Mechanical Engineering Science and Technology 117 
        Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Characteristics and Adsorption Capacities of Rice Bran-Activated Carbon) 

Visible (UV-Vis) spectroscopy. Determination of the adsorption of methylene blue by 

measuring the maximum wavelength of the 5 mg/L methylene blue solution in the range 664 

nm. 

(a) Rice bran (b) Activated carbon

Fig.1. Precursor and sample of activated carbon produced 

III. Results and Discussions

A. Adsorption Isotherm of Activated Carbons

The adsorption isotherm of activated carbon, as shown in Figure 2, is the relationship of

the amount of nitrogen absorbed by activated carbon at different relative pressure levels. The 

three activated carbons produced have almost the same pattern, only differing in the rate of 

nitrogen adsorption. The activated carbon AC-DP40 has the lowest adsorption rate, whereas 

the relative pressure increases the amount of nitrogen adsorbed is relatively constant until 

the relative pressure of 0.9. Then it increases significantly and reaches a peak at a relative 

pressure of 1. The low absorption of activated carbon AC-D40 is due to its short activation 

time resulting in less opportunity for the formation of new pores and widening of the pores 

formed during the carbonization process. As a result, this activated carbon has a low surface 

area and pore volume as shown in Figure. 4 and 5. 

Fig. 2. Adsorption isotherm of activated carbons 



118  Journal of Mechanical Engineering Science and Technology           ISSN 2580-0817 
 Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Properties and Adsorption Capacities of Rice Bran-Activated Carbon) 

Whereas AC-D80 and AC-D120, nitrogen adsorption began to increase until the relative 

pressure of 0.1, then remain constant until the relative pressure was 0.9. From a relative 

pressure of 0.9, it increases dramatically and reaches a peak at relative pressure 1. Both 

activated carbons have a Type II of adsorption isotherm classification related to IUPAC-

1985 [24]. In this type, there is a single and double layers adsorption mechanism that is 

characterized by a convex shape at a relative pressure (P/PO) less than 0.2 followed by a 

linear form over a long-range. The point of transition from convex to linear is the condition 

for the completion of single layer adsorption and when entering the linear portion indicates 

the start of double-layer adsorption [24]. Activated carbon AC-D80 and AC-D120 have 

higher adsorption at all relative pressure levels compared to AC-D40. At the end of the 

adsorption process, AC-D80 has a higher nitrogen adsorption capacity than AC-D120. 

B. Pore Size Distribution of Activated Carbons

The pore size distribution is a graph that shows the relationship between the amount of

nitrogen absorbed per gram of activated carbon at different pore sizes. As shown in Figure. 

3, the three activated carbons have almost the same pore distribution pattern. Most of them 

are distributed in the micropore area (less than 2 nm) in the 0.4 nm to 1.75 nm range, but 

with different adsorption rates. AC-D80 has a pore size distribution with a peak adsorption 

rate of 0.0089 cm3/g at a pore diameter of 0.652 nm, followed by AC-D120 and AC-D40 

with the highest adsorption rates of 0.00837 cm3/g and 0.00227 cm3/g, at pore diameter of 

0.652 nm and 0.591 nm, respectively. Even though they are in almost the same distribution 

range (micropore area), activated carbon AC-D40 has the lowest adsorption capacity. The 

40-minutes activation duration of activated carbon AC-D40 provided less opportunity for

the formation of new pores or widening of existing pores during the activation process. As

a result, the number of pores formed is also less compared to activated carbons AC-D80 and

AC-D120.

Fig. 3. Pore size distribution of samples 



ISSN: 2580-0817  Journal of Mechanical Engineering Science and Technology 119 
        Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Characteristics and Adsorption Capacities of Rice Bran-Activated Carbon) 

C. Surface Pore Structure of Activated Carbons

The surface pore structure of the activated carbons, as shown in Figure. 4 and 5,  show

that produced activated carbons have a pore surface varying from 26.613-109.389 m2/g, and 

pore volume from 0.028-0.083 cm3/g. Activated carbon AC-D80 has the highest surface area 

and pore volume followed by AC-DP120 and AC-DP40. In this case (Figure. 4 and 5),  the 

pore surface area of activated carbon is proportional to the pore volume,  where the higher 

the pore surface area higher the pore volume of activated carbon. The existence of pores in 

the surface of activated carbons is shown in the SEM image of the surface morphology of 

activated carbon in Figure. 6, where there is a difference between the morphology of 

precursors and activated carbon. The formation of pores occurs when the precursor was 

heated in the carbonization process [25] [26] and then continued in the activation process 

[21]. 

Fig. 4. Surface area (SBET) of activated carbons 

Fig. 5. Pore volumes of activated carbons 



120  Journal of Mechanical Engineering Science and Technology           ISSN 2580-0817 
 Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Properties and Adsorption Capacities of Rice Bran-Activated Carbon) 

D. Adsorption of Nitrogen and Methylene Blue Through Activated Carbons

The adsorption capacity of activated carbons for nitrogen and methylene blue is

presented in Table 1. Activated carbon AC-D80 has the highest adsorption capacity of 

nitrogen and methylene blue. In this case, there is a linear relationship between the pore 

surface area, pore-volume, and the adsorption capacity of nitrogen and methylene blue. The 

higher the surface area and pore volume of activated carbon, the higher the adsorption 

capacity. Activated carbon AC-D80 that has the highest pore area (109.389 m2/g) and the 

highest pore volume (0.083 cm3/g), also has the highest adsorption of nitrogen (53.874 

cm3/g) and methylene blue 87.56 (mg/g). The comparison of methylene blue adsorption of 

the activated carbons produced in this study and other adsorbents is shown in Table 1. 

Rice bran AC-D40 

AC-D80 AC-D120 

Fig. 6. Surface morphology of activated carbon 



ISSN: 2580-0817  Journal of Mechanical Engineering Science and Technology 121 
        Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Characteristics and Adsorption Capacities of Rice Bran-Activated Carbon) 

Fig. 7. Adsorption capacity of activated carbon 

Table 1. Methylene blue adsorption capacity of some adsorbents 

Adsorbens/Activated carbons 
Methylene blue adsorbed 

[mg/g] 
References 

Rice bran 82.84-87.56 This study 

Modified activated carbon by 

surfactants 

64.4-195.7 [27] 

Periwinkle 

Shells activated carbon 

89.8-431.1 [28] 

Parthenium hysterophorus activated 

carbon with H2SO4 treated 

39.7 [29] 

Bagasse activated carbon with H2SO4 

treatment 

49.8-56.5 [30] 

Ficus carica activated carbon with 

H2SO4 treatment 

47.6 [31] 

Delonix regia pods activated carbon 

with H2SO4 treatment 

23.3 [32] 

Coconut leaves activate carbon 127-149 [33] 

IV. Conclusions
The rice bran precursor has been manufactured to become activated carbon with

promising characteristics. Activated carbon that produced with an activation duration of 80 

minutes (AC-D80) has the most optimal properties and adsorption capacity. With increasing 

surface area and pore volume, the adsorption capacity of activated carbon to nitrogen and 

methylene blue also increases. Activated carbon AC-D80 has the greatest surface area, pore-

volume, and ability for adsorption of nitrogen and methylene blue. With its characteristics, 

activated carbon AC-D80 has the potential to be used for the purification of biogas from CO2 

and H2S impurities or for adsorption of motor vehicle exhaust emissions. 



122  Journal of Mechanical Engineering Science and Technology           ISSN 2580-0817 
 Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Properties and Adsorption Capacities of Rice Bran-Activated Carbon) 

Acknowledgment 

The deep thanks to conveyed to the Institute of Research and Community Services of 

Udayana University (LPPM Unud) through the Faculty of Engineering Udayana University, 

which has funded the flagship research of this study program (PUPS). 

Reference 

[1] Cheung, W.H., Lau, S.S.Y., Leung, S.Y., Ip, A.W.M., and McKay, G., “Characteristics

of Chemical Modified Activated Carbons from Bamboo Scaffolding”, Chinese

Journal of Chemical Engineering, vol. 20 (3), pp. 515–23, 2012.

[2] Esteves, I. A.A.C., Marta, S.S.L., Pedro, M.C. N., and José, P.B. M, “Adsorption of

Natural Gas and Biogas Components on Activated Carbon”, Separation and

Purification Technology, vol. 62 (2), pp. 281–96, 2008.

[3] Zohre, S., Ataallah, S.G., and Mehdi, A.W., “Experimental Study of Methylene Blue

Adsorption from Aqueous Solutions onto Carbon Nano Tubes”, International Journal

of Water Resources and Environmental Engineering, vol. 2 (2), pp. 016-028, March

2010.

[4] Al Othman, Zeid, A., Mohamed, A.H., Rahmat, A., Ayman, A.G., and Mohamed, S.,

El-din H, “Valorization of Two Waste Streams into Activated Carbon and Studying

Its Adsorption Kinetics, Equilibrium Isotherms and Thermodynamics for Methylene

Blue Removal”, Arabian Journal of Chemistry, vol. 7 (6), pp. 1148–1158, 2014.

[5] Yu, K., Xiaoping, Z., and Shaoqi, Z., ”Adsorption of Methylene Blue in Water onto

Activated Carbon by Surfactant Modification”, Water, vol. 12 (587), pp. 1-19,

February 2020.

[6] Gu, X., Wang, Y., Lai, C., Qiu, J., Li, S., Huo, Y.L., Martens, W., Mahmood, N., and

Zhang, S, “Microporous Bamboo Biochar for Litium - Sulfur Battery”, Nano

Research, pp. 1-14, 2014.

[7] Peredo-Mancilla, D., Ghouma, I., Hort, C., Camelia, M. G., Jeguirim, M., and

Bessieres, D., “CO2 and CH4 Adsorption Behavior of Biomass-Based Activated

Carbons”,  Energies, vol. 11 (3136),  pp. 1-13, 2018.

[8] L. Jiang, A. Gonzalez-Diaz, J. Ling-Chin, A.P. Roskilly, A.J. Smallbone,

“Combustion CO2 Capture from A Natural Gas Combined Cycle Power Plant Using

Activated Carbon Adsorption”, Applied Energy, vol. 245, pp. 1-15, 2019.

[9] Maile, O.I., Muzenda, E., Tesfagiorgis, H., “Chemical Adsorption of Carbon Dioxide

in Biogas Purification”, Procedia Manufacturing, vol. 7, pp. 639-646, 2017.

[10] Sutanto, J.W.S.,  Dijkstra, J.A.Z. Pieterse, J. Boon, Hauwert, P., Brilman, D.W.F., “

CO2 Removal From Biogas with Supported Amine Sorbents: First Technical

Evaluation Based on Experimental Data”, Separation and Purification Technology,

vol. 184, pp. 12–25, 2017.

[11] Huang, T., Qiu, Z., Wu, D. and Hu, Z, “Bamboo-Based Activated Carbon @ MMO2
Nanocomposites for Flexible High-Performance Supercapacitor Electrode Materials”,

Int. J. Electrochem. Sci, vol. 10, pp. 6312-6323, 2015.



ISSN: 2580-0817                      Journal of Mechanical Engineering Science and Technology 123 
                                                         Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Characteristics and Adsorption Capacities of Rice Bran-Activated Carbon) 

[12]   Kuila, U., “Measurement and Interpretation of Porosity and Pore Size Distribution in 

Mudrocks: The Hole Story of Shales.” A thesis, Doctor of Philosophy, Petroleum 

Engineering, The Colorado School of Mines, 2013. 

[13]  Sych, N. V., Trofymenko, S.I., Poddubnaya, O.I., Tsyba, M.M., Sapsay, V.I.,  

Klymchuk, D.O., and Puziy, A.M., “Porous Structure and Surface Chemistry of 

Phosphoric Acid Activated Carbon from Corncob,” Applied Surface Science, vol. 261, 

pp. 75–82, 2012.  

[14] Khalil, S. H, “Effects on Surface Area, Intake Capacity and Regeneration of 

Impregnated Palm-Shell Activated Carbon with Monoethanolamide and 2-Amino-2-

Methyl-1-Propanol Equipped for CO2 Adsorption”, Journal of Earth Science & 

Climatic Change, vol. 9 (7), pp. 2-10, 2018. 

[15] Hassan, A.H., and Sami, M.A.A., “Removal of Nitrate and Nitrite Anions from 

Wastewater Using Activated Carbon Derived from Rice Straw”, Journal of 

Environmental & Analytical Toxicology, vol. 6 (1), pp. 1-6, 2016. 

[16] El-Demerdash, F.M., Abdullah, A.M., and Ibrahim, D.A, “Removal of Trihalo 

Methanes Using Activated Carbon Prepared from Agricultural Solid Wastes,” 

Hydrology current research, vol. 6 (1), pp. 1-6, 2015. 

[17]  Bergna, D., Varila, T., Henrik , R.U.L., “Comparison of the  Properties of Activated 

Carbons Produced in One-Stage and Two-Stage Processes”, Journal of Carbon 

Research, vol. 4 (41), pp. 1-10, 2018. 

[18]  Negara, D.N.K.P., Tirta Nindhia, T.G.,  Surata, I.W., Hidajat, F., and Sucipta, M.,“ 

Nanopore Structures, Surface Morphology, and Adsorption Capacity of Tabah 

Bamboo-Activated Carbons”, Surfaces and Interfaces, vol. 16, pp. 22-28, 2019. 

[19] Negara, D.N.K.P., Tirta Nindhia, T.G., Lusiana, Astika, I.M., and Kusuma 

Kencanawati, C.I.P., ”Development and Characterization of Activated Carbons 

Derived from Lignocellulosic Material”, Materials Science Forum, vol. 988, pp. 80-

86, 2020. 

[20]  Akbarillah, T., Hidayat dan Khoiriyah, T., “Rice brand quality of several rice varieties 

In North Bengkulu”, Jurnal Sain Peternakan Indonesia, vol. 2(1), pp. 36-41, 2007. (In 

Indonesia) 

[21]  Patil, B.S. and Kulkarni, K.S, “Development of High Surface Area Activated Carbon 

from Waste Material”, International Journal of Advanced Engineering and Studies 

(IJAERS), vol. 1, pp. 109-113, 2012. 

[22]  Lempang, M., “Pembuatan dan Kegunaan Arang Aktif”, Info Teknis EBONI, vol. 11, 

pp. 65-80, 2014. (In Indonesia) 

[23]  Gokce, C.G.S., Aydin, S., and Arayici, S., “Comparison of Activated Carbon and 

Pyrolyzed Biomass for Removal of Humic Acid from Aqueous Solution”, Open 

Environ Pollut Toxicol J, vol. 1, pp. 43–48, 2009. 

[24]  Thommes, M., Katsumi, K., Alexander V. Neimark, James P. O., Rodriguez-Reinoso, 

F., Rouquerol, J., and Kenneth, S.W.S., “Physisorption of Gases, with Special 

Reference to the Evaluation of Surface Area and Pore Size Distribution (IUPAC 

Technical Report)”, Pure and Applied Chemistry, vol. 87 (9–10), pp. 1051–69, 2015.  



124   Journal of Mechanical Engineering Science and Technology                       ISSN 2580-0817 
                                           Vol. 4, No. 2, November 2020, pp. 115-124 

Negara et al. (Surface Properties and Adsorption Capacities of Rice Bran-Activated Carbon) 

 

[25]  Daud, W.M.A.W., Ali, S.S.W., and Sulaiman, M.Z., “The Effects of Carbonization 

Temperature on Pore Development in Palm-Shell-Based Activated Carbon”, Carbon,  

vol. 38, pp. 1925–1932, 2000. 

[26]  Martinez, M.L., Agnese, M., and Guzman, C., “Making and Some Properties of 

Activated Carbon Produced from Agricultural Industrial Residues from Argentina”,  J 

Argent Chem Soc., vol. 91, pp. 103–108, 2003. 

[27]  Yu, K., Xiaoping, Z., and Shaoqi, Z., “Adsorption of Methylene Blue in Water onto 

Activated Carbon by Surfactant Modification”, Water, vol. 12 (587), pp. 1-19, 2020.   

[28]  Belloa, O.S., Adeogunb, I.A., Ajaeluc, J.C., and Fehintolad, E.O., ”Adsorption of 

Methylene Blue Onto Activated Carbon Derived from Periwinkle Shells: Kinetics And 

Equilibrium Studies”, Chemistry and Ecology, vol. 24 (4), pp. 285-295, August 2008. 

[29]  Liang, S.X. Guo, Feng, N., and Tian, Q., “Isotherms, Kinetics, and Thermodynamic 

Studies of Adsorption of Cu2+from aqueous solutions by Mg2+/K+ Type Orange Peel 

Adsorbent”, J. Hazard. Mater, vol. 174, pp. 756–762, 2010. 

[30]  Low, L.W., Teng, T.T., Ahmad, A., Morad, N., Wong, Y.S., “A Novel Pretreatment 

Method of Lignocellulosic Material as Adsorbent and Kinetic Study of Dye Waste 

Adsorption”, Water Air and Soil Pollut, vol. 218, pp. 293–306, 2011. 

[31]  Pathania, D.S. and Sharma, P. S., “Removal of Methylene Blue by Adsorption onto 

Activated Carbon Developed from Ficus Carica Bast”, Arab. J. Chem, vol. 10 (Suppl. 

1), pp. S1445–S1451 1–7, 2017. 

[32]  Ho, Y.S., Malaryvizhi, R., and Sulochana, N., “Equilibrium Isotherm Studies of 

Methylene Blue Adsorption onto Activated Carbon Prepared from Delonix Regia 

Pods”, J. Environ. Prot. Sci., vol. 3 (1), pp. 1-6, 2009. 

[33]  Jawada, A.H., Rashida, R.A., Mohd Ishaka, M.A., and Lee, D. W., “Adsorption of 

Methylene Blue onto Activated Carbon Developed from Biomass Waste by H2SO4 

Activation: Kinetic, Equilibrium and Thermodynamic Studies”, Desalination and 

Water Treatment, vol. 57, pp. 25194–25206, 2016.