Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution

Zeleke Zewde Babanto; Jafer Esmael; Guta Gonfa

doi:doi:10.11648/j.ajaic.20250901.11

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Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution

Zeleke Zewde Babanto^*

, Jafer Esmael, Guta Gonfa

Published in American Journal of Applied and Industrial Chemistry (Volume 9, Issue 1)

Received: 24 May 2025 Accepted: 11 June 2025 Published: 30 June 2025

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Abstract

This study focused on the remediation of methyl orange (MO) from wastewater by preparation of acid activated biochar from avocado pomace, which was obtained from Jimma Industrial Park, Ethiopia. This avocado pomace was considered as a solid waste and accumulated on waste disposal areas of the industrial park. The optimal temperature of 500 °C was selected for further biochar preparation. Physicochemical properties of the biochar have fixed carbon content (71.15 ± 0.84%), ash content (12.95 ± 0.35%), moisture content (10.40 ± 0.45%), volatile matter content (5.50 ± 0.62%) as well as PZC (7.4 ± 0.85). The acid activated biochar at optimum temperature of before and after adsorption was characterized via FTIR, XRD, and SEM. The main parameters of solution pH (5), initial concentration (60 mg/L), mass of adsorbent (0.5 g), and contact time (120 min) were optimized. Langmuir model was more fitted to experimental data and adsorption mechanism was chemisorption; leads to the formation monolayer on the homogenous active site with maximum adsorption capacity 22.988 mg/g. The adsorption phenomena were consistent with PSO kinetics model (R2=0.9997) and adsorption mechanism was chemisorption. Thus, this low cost environmental friendly industrial waste effectively removes MO dye and solves the problem of industrial wastewater through adsorption. More research finding is recommended to study how well this adsorbent works in real wastewater samples.

Published in	American Journal of Applied and Industrial Chemistry (Volume 9, Issue 1)
DOI	10.11648/j.ajaic.20250901.11
Page(s)	1-12
Creative Commons	This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.
Copyright	Copyright © The Author(s), 2025. Published by Science Publishing Group

Keywords

Acid Activated Biochar, Adsorption, Avocado Pomace, Methyl Orange

1. Introduction

Environmental pollution is a major challenge in the entire world. It is the release of chemical, physical and biological contaminants to the environment. In recent years contamination of the environment (water, soil and air) by pollutants from different activities has become an increasingly serious problem

[1]

. It has increased exponentially in the past few years and reached alarming level in terms of its effects on living. Many industries, such as the textile, leather, paper and plastics industries, are highly dye users. Textile industry consumes great amount of water and colored dyes, which generate high volume colorful wastewater

[2]

In Ethiopia, textile production becomes the source of income that contributes to their gross domestic product. However, this has brought both consequences to such countries either in a positive way that is an improvement of economy or in a negative way which led to an increased anthropogenic impact on the biosphere

[3]

. In Addis Ababa, there are many industrial establishments among which most of them are discharging their effluents directly to the river without any prior treatment

[4]

. Bahir Dar textile factory possesses serious pollution to aquatic habitat of the head of Blue Nile River in turn makes the water highly polluted

[5]

Most synthetic dyes are highly toxic to humans and aquatic beings, and have acute and chronic effects such as kidney and liver cancer in dye workers. MO is large class of synthetic dyes. The presence of aromatic rings and –N=N– groups in Azo dyes make them highly toxic, carcinogenic and teratogenic. MO dye was selected as a target dye because of its wider application in textile, printing, pharmaceutical, food industries, and chemical laboratories, as well as its negative effects on the environment, animals, and human being. It is water soluble organic synthetic dye with very high coloring ability and presents a bright orange color when dissolved in water

[6]

Different materials can be used to produce the adsorbent such as banana peel, potato peel, apple peel, lemon peel, grape waste and avocado peel fruit-vegetable wastes. Every year, approximately 1.3 billion tons of food is waste and 40-50% of these are fruit-vegetable waste. Valorization of this waste can both prevent the pollution of the environment and help to purify the water

[7]

. The production and processing of avocado oil leads to an abundance of organic waste that is sent directly into landfill. For every 1000 kg of avocado, only 78 kg of oil is produced

[8]

. The remaining mass is accounted for by-products in the form of seed (121 kg), skin (153 kg), pomace (150 kg), wastewater (448 kg)

[9]

There are various ways to remove dyes from wastewater discharges like coagulation, adsorption electrochemical process, membrane separation process, chemical oxidation, reverse osmosis and aerobic and anaerobic microbial degradation

[10]

. Considering their economic disadvantages and inefficiency, many of these processes are not popular. Adsorption is a surface process that leads to transfer of a molecule from a fluid bulk to solid surface which is the easiest, safest and most cost-effective separation methods for the removal of dye. This process involves a mass transfer and leads to the accumulation of atoms, ions or molecules at the interface of two phases, (liquid-solid) adhere using a surface of the adsorbent

[11]

. Thus, the result of this study finds low cost active adsorbent from avocado pomace and its effective utilization in the removal of MO as a model dye from aqueous solution.

2. Materials and Methods

2.1. Chemicals and Reagents

The chemicals and reagents which have been used in this study were; powder MO dye (C₁₄H₁₄N₃NaO₃S, 85% Aladdin Co., Ltd., China), phosphoric acid (H₃PO_4,98%, Nice Laboratories,India), nitric acid (HNO_3,69%_,Loba Chemie Pvt. Ltd., India), hydrochloric acid (HCl, 35.4%; Loba Chemie Pvt. Ltd. India), NaOH (90%, BDH, England) and sodium chloride (NaCl, 99.9%, Fisher Chemical, US). All chemicals used in this study were analytical reagent grade and were used without further purification.

2.2. Apparatus and Instruments

The apparatus and instruments which have been used in this study were; a double-beam UV–Vis spectrophotometer (Model: SPECORD 200/, AnalytiK Jena, Germany), a pH meter (Model: Bante902P, USA), a drying oven (Model GENLAB WIDNERS, England), a thermostatic water bath shaker (Model GrantGLS400, England), an electronic balance (Model: JA103P, China), a sieve (125 µm, ASTME11, UK), a FT-IR (Model: PerkinElmer, Spectrum Two, USA), a XRD (Model: Drawell XRD-7000) and a (Model: JCM-6000plus).

2.3. Preparations and Activation of Acid Activated Biochar

The avocado pomace was obtained from avocado oil processing of Jimma Industrial Park. It was separated from seed and washed as well as oven dried at 105 °C for 6 h. After that, it was crushed, sieved and stored in a desiccator

[12]

. Up on completion of that, 50 g of grounded-seized sample was soaked with 50% H₃PO₄ by ratio 1:1 and left for 24 h (Figure 1). After 24 h the sample was washed with distilled water to remove all the excess acid and oven dried at 105 °C for 3 h. About each 10 g of acid treated samples were placed in three ceramic crucibles and putted in the carbonization furnace. The carbonization process was carried out at three different temperatures 400 °C, 500 °C and 600 °C for 2 h and the contents were allowed to cool at room temperature. Each sample was thoroughly washed and rinsed using with distilled water until the pH of the filtrate was approximately 7. Then dried in an oven at a temperature of 105 °C for 3 h and kept in desiccator for further analysis

[13]

2.4. Characterization of Acid Activated Biochar

The proximate analysis of acid activated

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Figure 1. Schematic representation for the preparation of H₃PO₄ activated biochar from avocado pomace.

2.5. Batch Adsorption Experiments

For batch adsorption studies, the adsorption experiments were performed at room temperature. The adsorbent and the adsorbate were separated by filtration and the filtrate was analyzed for residual MO concentration using UV-Vis spectrophotometer at λ_max 465 nm. The percentage removal of MO dye from solutions was calculated by Eq 1.

R (%) = \frac{C_{o} - C_{e}}{C_{o}} x 100

(1)

where, 𝐶_𝑜 Initial dye concentration (mg/L) and 𝐶_𝑒 equilibrium dye concentration (mg/L).

The adsorption amounts at a time (q_t) and at equilibrium (q_e) are determined via Eqs (2) and (3)

q_{t} = \frac{(C_{o} - C_{t}) V}{m}

(2)

q_{e} = \frac{(C_{o} - C_{e}) V}{m}

(3)

where, V is volume of dye solution (L), m is mass of adsorbent (g), q_e is the equilibrium adsorption capacity (mg/g) and q_t is the adsorption capacity over time (mg/g)

[18]

. The effects of pH, initial MO concentration, contact time, and adsorbent dose on the adsorption of MO onto acid activated biochar were studied and optimized.

2.6. Data Analysis

2.6.1. Isotherm Studies

In this study, Langmuir

[19]

and Freundlich

[20]

isothermal adsorption models were applied to describe the distribution of adsorbate between the liquid and solid phase. Langmuir model is an ideal model for monolayer adsorption, supposing that the adsorption sites distributed on adsorbent surface uniformly

[21]

. The Freundlich isothermal model is used to describe the multilayer adsorption, assuming that the distribution of active adsorption sites on the adsorbent surface is heterogeneous. The liner equation of the Langmuir and Freundlich models are expressed via Eqs 4 and 5.

n \frac{C_{e}}{q_{e}}

\frac{1}{q_{m} K_{e}}

\frac{C_{e}}{q_{m}}

(4)

\log q_{e} = \log K_{F} + 1 / n \log C_{e}

(5)

where, 𝑞_𝑚 (mg/g) denote the maximum adsorption capacity, q_e is the amount of sorbate sorbed at equilibrium (mg/g), 𝐶_𝑒 equilibrium dye concentration (mg/L), K_F is the adsorption coefficient (L/mg); n is the coefficient of the Freundlich model. Generally, when 0 < 1/n < 1, the adsorption process is spontaneous; when 1/n=1, Freundlich isotherm model is linear, indicating the adsorption process is irreversible; when 1/n > 1, the adsorption process is relatively hard to proceed

[22]

2.6.2. Kinetic Studies

It is important to investigate the adsorption rate and the required time for adsorption to reach equilibrium. In order to understand and research the adsorption mechanism, many empirical models can be used to simulate the kinetics of the solid-liquid interface adsorption. In the context, pseudo first order (PFO) and pseudo second order (PSO) kinetic model were applied to simulate the adsorption kinetics of MO on to acid activated biochar from avocado pomace. PFO kinetic model assumes that the occupying rate of adsorbates onto adsorption sites is proportional to the quantity of the unoccupied sites. The linear form of the kinetic rate expression for PFO and PSO model are given by Eqs 6 and 7.

\log (q_{e} - q_{t}) = \log q_{e} - \frac{k_{1}}{2.303} t

(6)

\frac{t}{q_{t}} = \frac{1}{k_{2} q_{e}^{2}} + \frac{t}{q_{e}}

(7)

where q_e is the amount of dye adsorbed at equilibrium (mg/g), q_t is the number of dyes adsorbed at time t (mg/g), k₁ is the PFO rate constant (min^-1), t is time (min) and k₂ represents the rate constant of PSO (g/mg/min).. The straight-line plot of log (q_e-q_t) against time t, should give a linear relationship from which the PFO rate constant (k₁) and equilibrium sorption capacity (q_e), can be calculated from the slope and intercept respectively.

3. Results and Discussion

3.1. Optimization of Adsorbent

Temperature optimization experiments were performed to select adsorbent with better sorption capacity. Approximately 10 g of 50% H₃PO₄ soaked samples were placed in a ceramic crucible and in the carbonization furnace for 2 h. The reaction took place at 400, 500 and 600 °C final temperature. The highest removal efficiency of MO dye occurred for sample prepared at 500 °C (93.34%); due to its porosity and high surface area (Figure 2). The lowest MO dye removal efficiency (62.50%) was observed at 400°C. Therefore, 500°C was the optimal temperature for further adsorbent preparation and termed as acid activated biochar.

3.2. Characterization of Acid Activated Biochar

3.2.1. Physicochemical Characteristics

The physicochemical properties of acid activated biochar were determined by standard method and presented in Table 1. The results showed that prepared acid activated biochar have very high fixed carbon content, low moisture content, low ash content and very low volatile matter. This is due to during carbonization and activation processes, organic substances become unstable as a result of the heat causing the molecules to break their bonds and linkages. Volatile matter is also released as a gas and a liquid which evaporates off leaving material with high carbon content

[14]

. The high composition of the fixed carbon refers to high quality of the adsorbent which improves the surface area and adsorption performance. From the result the low ash content in the biochar indicates inorganic matter in the sample is insignificant. According to different scholar findings high fixed carbon, low moisture, low volatile matter and low ash content adsorbents are recommendable for adsorption activities

[23, 24]

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Figure 2. Removal efficiency of acid activated biochar prepared at different temperature.

Table 1. Result for proximate analysis of the acid activated biochar.

Parameters	Mass in percent (%)
Moisture content	10.40 ± 0.45
Ash content	12.95 ± 0.35
Volatile matter	5.50 ± 0.62
Fixed carbon	71.15 ± 0.84

The pH of prepared biochar was 4.7 ± 0.85. The surface area of the prepared acid treated biochar analysis was determined by Sear method. Based on this result the prepared adsorbent has very high surface area (391 m²/g), it was raised from H₃PO₄ activation. Upon high concentration H₃PO₄ activation, leads to reorganization of the chemical constituents and subsequent deposition of carbon rich molecules to the voids of biomass by the influence of temperature and pressure

[25, 26]

The PZC is defined as the condition in which the density of electric charge on the adsorbent surface is zero. In this study, the solid addition method was followed. Accordingly, 0.1 M of NaCl solution poured into 12 flasks each containing 0.1 g of adsorbent. The pH of the solutions was measured from 2 to 12 by using a pH meter and kept for 24 h. The results were then plotted between “∆pH final versus pH initial”. The point of intersection of the curves of “∆pH final versus pH initial” is the PZC of adsorbent. The plot of ∆pH final versus pH initial for adsorbents is presented in Figure 3. It was found to be 7.4. When the pH of the solution is below the PZC, the surface of the adsorbent will become positively charged and when the solution pH is greater than PZC, the surface of the adsorbent will become negatively charged. It implied that the prepared adsorbent was most probably adsorbing dye in acidic regions

[27]

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Figure 3. Determination of pHPZC for acid activated biochar.

3.2.2. FTIR Analysis

Fourier Transform Infrared Spectroscopy (FTIR) is the machine, which uses infrared, light to vibrate or rotate bond molecule to detect the functional group presence in the sample. FTIR spectrum was associated with the functional groups that were existed on the surface of acid activated biochar in the range 4000 – 500 cm^-1shown in Figure 4.

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Figure 4. FTIR spectra of acid activated bichar before and after adsorption for MO dye.

FTIR spectrum of before (red) and after adsorption (black) showed a strong peak shift of OH stretch from wavenumber 3477 to 3441 cm^-1

[28]

. Peak position 2918 cm^-1 was assigned to C-H stretching of single bond, which peak shifted to 2375 cm^-1 after the loading of MO dye. Peaks at 1640 cm^-1 after MO dye adsorption was C=C for aliphatic unsaturated ion. Peak corresponds at 1166 cm^-1 was characteristics of C-O stretching vibration of alcohols and phenols. FTIR spectrum of before adsorption showed additional peak at 1442 cm^-1 and 1371 cm^-1 for aromatic ring and C-N stretching, respectively. The shift of peaks and band width difference before and after adsorption tends to show the participation of functional groups of adsorbent surfaces on adsorption of MO and a suitable site for dye binding. The results confirm that there was deformation (bending and stretching) of bond molecule during interaction of MO dye ions with organic compound in the sample.

3.2.3. XRD Analysis

X-ray diffraction (XRD) studies are used for determining crystal and amorphous structures. The broad band or broad spectrum at 2θ 10-30^◦ was due to the amorphous structure of the adsorbent

[29]

. The presence of an amorphous phase within the acid activated biochar results an irregular base line with noise and pulsed shape. The analyzed structure and phase of acid activated biochar was performed and presented in Figure 5.

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Figure 5. XRD pattern of acid activated biochar (Black) before and (Red) after adsorption of MO dye.

3.2.4. SEM Analysis

Characterization of scanning electron microscopy (SEM) is widely used to study and provides information on size and morphology. As seen from the SEM images of before adsorption (Figure 6A), more porous and irregular shapes were observed. The structures signify the presence of macrospores and which was responsible for high surface area for acid activated biochar. On the other hand, porosity was decreased after adsorption (Figure 6B) toward smooth a surface as the MO dye molecules were mounted over the pores cavity of adsorbent

[30]

. Therefore the surface area and pore volume have significant effect on enhancing adsorption efficiency of pollutants

[31]

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Figure 6. SEM image of acid activated biochar before (A) and after (B) loading of MO dye molecules.

3.3. Effects of Solution pH

The effect of pH on the MO removal was studied in the pH range from 1 to 10. The removal efficiency of MO dye was increase from 80% to 99% as pH increased from pH 2 to 5 Figure 7. As such, the optimum solution pH for this finding was 5. This was occurred due to MO adsorption onto acid activated biochar via complex interplay of electrostatic and dispersion interactions with possible mechanisms namely, (i) π-π dispersion interaction between phenolic groups on the adsorbent with the aromatic rings in MO molecules. (ii) Electron donor–acceptor complex formation at the carbon surface. Although in adsorption process, electrostatic attraction exists between sulphonate and adsorbent surface plays a very significant role, the oxygen of the surface carbonyl group acts as the electron donor and the MO aromatic ring as the acceptor. This can lead to strong binding between the dye molecules and the adsorbent surface. Further increase in pH results in deprotonation of positively charged functional groups causing it to become negatively charged. At this point, electrostatic repulsion between the negatively charged surface and the negatively charged MO molecules could reduce adsorption efficiency

[32-34]

3.4. Effect of Initial MO Concentration

The effect of the initial concentration of MO dye was investigated by varying the concentration of dye ion from 20 to 100 mg/L. As shown in Figure 8, maximum removal efficiencies (98.8%) was obtained at a lower initial concentration (20 mg/L) due to the vacant active sites on the adsorbing surface. When the initial concentration of dye increases, the active sites necessary for the adsorption of dye molecules get occupied at 60 mg/L, where saturation of the active sites is achieved

[35]

. The optimal initial MO dye concentration was 60 mg/L. The decreasing removal efficiencies at high concentration was due to the limited number of active sites on the surface of adsorbent to accommodate higher concentration ions

[36]

. Generally, there were unoccupied binding sites on the adsorbent surface at a low concentration, and insufficient sites at higher concentration, thus decreasing the dye removal efficiency. On the contrary the adsorption capacity was increased with an increase of initial concentration of dye molecules due to the availability of a higher number of dye ions per unit mass of the adsorbents and also increase in the initial concentration of the dye enhances the interaction between the dye molecules and the surface of the adsorbent

[37]

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Figure 7. Effect of solution pH on MO adsorption by acid activated biochar, mass of adsorbent 0.1 g, initial concentration 20 mg/L and contact time 2 h.

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Figure 8. Effect of initial concentration for removal of MO at solution pH 5, mass of adsorbent 0.1 g and contact time 2 h.

An Adsorption isotherms are mathematical models used to clearly describe the distribution of adsorbate species among liquid and adsorbent

[38]

. Using the assumptions mainly related to the heterogeneity or homogeneity of adsorbents, there are types of coverage and possibility of interaction between adsorbate species. In this study, the correlation coefficients (R²) of Langmuir model (R²=0.9941) (Figure 9A) was higher than the R² values of Freundlich model (R²=0.9384) (Figure 9B)

[39]

. This result indicated that the Langmuir model more fitted to experimental data (Table 2) and hence adsorption was mainly chemisorption; lead to the formation monolayer on the homogenous active site on the adsorbent surface

[40]

Moreover, the Langmuir isotherm model which is described in terms of the dimensionless constant called separation factor or equilibrium parameter (R_L), is used to predict the nature of the adsorption process which obtained using the relation in Eq 8. The adsorption process is irreversible if R_L = 0, favorable if 0 < R_L < 1, linear if R_L = 1, and unfavorable if R_L > 1.

R_{L} = \frac{1}{1 + K_{L} C_{o}}

(8)

where C_o is the initial MO concentration (mg/L) and K_L is the Langmuir constant (L/mg)

[41]

In this study, average values of R_L was 0.010182 indicate verifying favorability of adsorption

[39]

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Figure 9. Langmuir (A) and Freundlich (B) linear isotherm model of adsorption of MO dye.

Table 2. Adsorption isotherm parameters and constants for Langmuir and Freundlich models.

Parameters	Isotherm models
Parameters	Langmuir	Freundlich
q_m(mg/g)	22.988	-
b (L/mg)	2.069	-
R_L	0.010182	-
K_F ((mg^1−1/n L^1/n⁾/g)	-	0.001
N	-	0.3075
R²	0.9941	0.9384

3.5. Effect of Contact Time

The effect of contact time was determined by varying the time from 5 to 210 min. As shown in Figure 10, the rapid rate of MO dye ion uptake and reach 98.7% during the first 45 min. The amount of adsorbed dyes was rapidly increased, and then gradually increase until equilibrium was reached at optimal time near to 120 min. This was perhaps due to the most readily availability of sufficient number of active sites which gets saturated with time

[42]

. Thus 120 min was saturation time (Figure 10) a t which the adsorbent attained maximum percentage removal of MO dye

[43]

. Beyond 120 min, equilibrium was established. This might be due to the concentration of adsorbate in the pores and concentration of adsorbate in the bulk was dynamic state of equilibrium. Therefore, the contact time of 120 min was selected for further studies for MO dye adsorption.

The study of adsorption kinetics is very important to determine how quickly or slowly the reaction is proceeding

[44]

. The fast adsorption at the initial stage can be associated with the presence of vacant active sites initially, which are responsible for the rapid adsorption of MO dye on the adsorbent’s surfaces. When equilibrium is achieved, the amount of MO dye migrates from the solution to the adsorbent and amount of MO dye desorbed from the surface of the adsorbent to the solution were in the state of dynamic equilibrium. The time required to attain this equilibrium process is termed as equilibrium time and the amount of MO dye adsorbed on the adsorbent at this time implies equilibrium adsorption capacity.

The linear forms of the PFO and PSO were applied to the experimental data to assess the adsorption kinetics as seen Figure 11. Since the correlation coefficient value of PFO kinetics was low (R²=0.9280) (Figure 11A) compared to PSO kinetic (R²=0.9997) (Figure 11B). The highest R² values indicating that most satisfactory for describing the adsorption kinetics

[44]

. Therefore, based on the R² value it can be concluded that, PSO kinetic model predicted as well suited for the whole adsorption process and the reaction was appears to be controlled by the chemical reaction adsorbate and adsorbent species

[2]

. Moreover, the experimental number of adsorbed MO dyes per unit mass of adsorbent at equilibrium and theoretical value of adsorbed MO dyes per unit mass of adsorbent at equilibrium were calculated based on PSO model have showed good agreement as compare to PFO Table 3.

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Figure 10. Effect of contact time for the removal of MO at mass of adsorbent 0.1 g, pH 5, and initial concentration 20 mg/L.

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Figure 11. Linear plot for adsorption of PFO (A) and PSO (B) kinetics.

Table 3. Parameters of the PFO and PSO kinetic models for MO dye removal.

Parameters	Kinetic models
Parameters	PFO	PSO
C_o (mg/L)	20	40
q_e,exp(mg/g)	10.06	10.06
q_e,cal(mg/g)	5.2	10.47
k₁(min^-1)	0.0115	-
k₂(g/(mg.min))	-	0.0955
R²	0.9280	0.9997

3.6. Effect of Adsorbent Dose

The effect of adsorbent mass on the MO dye removal efficiency was determined with 0.1 to 0.8 g of adsorbent. As shown in Figure 12, the MO dye removal efficiency increased linearly from 86% to 97% as adsorbent mass increases from 0.1 to 0.5 g. This behavior could be explained considering that with adsorbent mass increase, more active sites were available to bind MO dye from aqueous phase

[45]

. The result after 0.5 g (Figure 12), the amount of adsorbed MO dye was slowly increases up to 0.7 g. Then beyond 0.7, the removal efficiency was observed to be constant, (i.e. no more adsorption takes place). This was due to the aggregation and overlapping of particles of adsorbent in the solution

[46-48]

. As a result, 0.5 g was selected as, the optimum dose for the subsequent experiments.

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Figure 12. Effect of amount of adsorbent for at contact time 2 h, pH 5 and initial concentration 20 mg/ L.

3.7. Adsorption Mechanism

The adsorption of MO dye from aqueous solution by acid activated biochar derived from avocado pomace was strongly dependent on the various functional groups on the surface of adsorbent such as hydroxyl, phenols, aromatics and etc. those were supported by FTIR spectral described results. The probable adsorption mechanisms between the surface functional groups of adsorbent and MO dye can be assigned to the various interactions such as electrostatic attractions, hydrogen bonding interaction and π–π interactions between the adsorbent and adsorbate

[49, 50]

. The MO dye adsorption onto acid activated biochar aligns more closely with the Langmuir isotherm model than with the Freundlich model, indicating monolayer chemosorption on its surface. Similarly, the PSO model was more suitable than the PFO model, indicating the chemisorption of MO dye onto the adsorbents. Thus, the adsorption of MO dye onto acid activated biochar occurs through chemisorption mechanism.

3.8. Reliability and Validity of the Work

In order to determine the accuracy of the data collected, all batch tests were carried out by triplicated and only mean values were reported. Blank tests were carried out at the same time. All polyethylene plastic and laboratory items were washed with detergent, followed by repeated rinse with distilled water and soaked overnight in 10% HNO₃, then rinsed three times with distilled water and dried. Experimental analyses were carried out using MO containing a working solution. Regressions of experimental data were performed using Origin 19.0 software. The correlation coefficient R²of parameters were determined to characterize the accuracy of the optimal analysis of the data fit.

4. Conclusion

In this study, acid activated biochar was prepared from pomace of avocado oiling industry at optimal temperature of 500 °C with 93.34% removal efficiency. The adsorbent was tested and evaluated for removal of MO dye from model wastewater through batch adsorption experiment. In this regard, the optimum values for removal of MO dye have been obtained as the pH of solution, adsorbent dose, contact time and initial MO concentration value pH 5, 0.5 g, 120 min and 60 mg/L respectively. The surface area of adsorbent was 391 m²/g. The results of physicochemical properties of adsorbent were showed that the prepared adsorbent has very high fixed carbon content 71.15 ± 0.84%, low moisture content 10.4 ± 0.45%, low ash content 12.95 ± 0.35% and very low 5.5 ± 0.62% volatile matter content. The high composition of the fixed carbon refers to high quality of the adsorbent which improves the surface area and adsorption performance.

The peaks position was shifted and changed in intensity after adsorption of MO dye in the FTIR spectra analysis. This indicates that most of the functional groups were participated on adsorption process and demonstrate the availability of suitable adsorption sites. The adsorption isotherm data were well fitted to Langmuir model (R²=0.9941) than Freundlich model (R²=0.9384). This result addressed the process leads to monolayer formation with maximum adsorption capacity 22.988 mg/g. The experimental and theoretical kinetics data showed good agreement for the PSO kinetic model (R²=0.9997) than PFO models (R²=0.9280), which indicates chemisorption mechanisms. Thus, the avocado pomace based acid activated biochar is an effective, low cost, and locally available alternative for remediation of MO dye from aqueous solutions.

Abbreviations

FTIR	Fourier Transform Infrared Spectroscopy
MO	Methyl Orange
PFO	Pseudo First Order
PSO	Pseudo Second Order
PZO	Point of Zero Charge
SEM	Scanning Electron Microscope
UV-Vis	Ultra Violet-Visible
XRD	X-Ray Diffraction

Acknowledgments

The authors would like to thank the Department of Chemistry, Jimma University, Ethiopia, for providing access to laboratory facilities.

Author Contributions

Zeleke Zewde Babanto: Writing – review & editing, Writing – original draft, Formal analysis, Software, Resources, Conceptualization, Methodology, Data curation, Validation, Visualization

Guta Gonfa: Supervision, Formal analysis, Conceptualization, Methodology

Jafer Esmael: Investigation, Formal analysis, Methodology

Data Availability Statement

Data will be made available on request.

Conflicts of Interest

The authors declare no conflicts of interest.

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APA Style

Babanto, Z. Z., Esmael, J., Gonfa, G. (2025). Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution. American Journal of Applied and Industrial Chemistry, 9(1), 1-12. https://doi.org/10.11648/j.ajaic.20250901.11

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ACS Style

Babanto, Z. Z.; Esmael, J.; Gonfa, G. Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution. Am. J. Appl. Ind. Chem. 2025, 9(1), 1-12. doi: 10.11648/j.ajaic.20250901.11

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AMA Style

Babanto ZZ, Esmael J, Gonfa G. Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution. Am J Appl Ind Chem. 2025;9(1):1-12. doi: 10.11648/j.ajaic.20250901.11

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@article{10.11648/j.ajaic.20250901.11,
  author = {Zeleke Zewde Babanto and Jafer Esmael and Guta Gonfa},
  title = {Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution
},
  journal = {American Journal of Applied and Industrial Chemistry},
  volume = {9},
  number = {1},
  pages = {1-12},
  doi = {10.11648/j.ajaic.20250901.11},
  url = {https://doi.org/10.11648/j.ajaic.20250901.11},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajaic.20250901.11},
  abstract = {This study focused on the remediation of methyl orange (MO) from wastewater by preparation of acid activated biochar from avocado pomace, which was obtained from Jimma Industrial Park, Ethiopia. This avocado pomace was considered as a solid waste and accumulated on waste disposal areas of the industrial park.  The optimal temperature of 500 °C was selected for further biochar preparation. Physicochemical properties of the biochar have fixed carbon content (71.15 ± 0.84%), ash content (12.95 ± 0.35%), moisture content (10.40 ± 0.45%), volatile matter content (5.50 ± 0.62%) as well as PZC (7.4 ± 0.85). The acid activated biochar at optimum temperature of before and after adsorption was characterized via FTIR, XRD, and SEM. The main parameters of solution pH (5), initial concentration (60 mg/L), mass of adsorbent (0.5 g), and contact time (120 min) were optimized. Langmuir model was more fitted to experimental data and adsorption mechanism was chemisorption; leads to the formation monolayer on the homogenous active site with maximum adsorption capacity 22.988 mg/g. The adsorption phenomena were consistent with PSO kinetics model (R2=0.9997) and adsorption mechanism was chemisorption. Thus, this low cost environmental friendly industrial waste effectively removes MO dye and solves the problem of industrial wastewater through adsorption. More research finding is recommended to study how well this adsorbent works in real wastewater samples.
},
 year = {2025}
}

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TY  - JOUR
T1  - Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution

AU  - Zeleke Zewde Babanto
AU  - Jafer Esmael
AU  - Guta Gonfa
Y1  - 2025/06/30
PY  - 2025
N1  - https://doi.org/10.11648/j.ajaic.20250901.11
DO  - 10.11648/j.ajaic.20250901.11
T2  - American Journal of Applied and Industrial Chemistry
JF  - American Journal of Applied and Industrial Chemistry
JO  - American Journal of Applied and Industrial Chemistry
SP  - 1
EP  - 12
PB  - Science Publishing Group
SN  - 2994-7294
UR  - https://doi.org/10.11648/j.ajaic.20250901.11
AB  - This study focused on the remediation of methyl orange (MO) from wastewater by preparation of acid activated biochar from avocado pomace, which was obtained from Jimma Industrial Park, Ethiopia. This avocado pomace was considered as a solid waste and accumulated on waste disposal areas of the industrial park.  The optimal temperature of 500 °C was selected for further biochar preparation. Physicochemical properties of the biochar have fixed carbon content (71.15 ± 0.84%), ash content (12.95 ± 0.35%), moisture content (10.40 ± 0.45%), volatile matter content (5.50 ± 0.62%) as well as PZC (7.4 ± 0.85). The acid activated biochar at optimum temperature of before and after adsorption was characterized via FTIR, XRD, and SEM. The main parameters of solution pH (5), initial concentration (60 mg/L), mass of adsorbent (0.5 g), and contact time (120 min) were optimized. Langmuir model was more fitted to experimental data and adsorption mechanism was chemisorption; leads to the formation monolayer on the homogenous active site with maximum adsorption capacity 22.988 mg/g. The adsorption phenomena were consistent with PSO kinetics model (R2=0.9997) and adsorption mechanism was chemisorption. Thus, this low cost environmental friendly industrial waste effectively removes MO dye and solves the problem of industrial wastewater through adsorption. More research finding is recommended to study how well this adsorbent works in real wastewater samples.

VL  - 9
IS  - 1
ER  -

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Author Information

Zeleke Zewde Babanto

Department of Chemistry, Wolaita Sodo University, Wolaita Sodo, Ethiopia

Contact Email

http://orcid.org/0009-0008-3081-6138
Jafer Esmael

Institute of Health Sciences, Jimma University, Jimma, Ethiopia
Guta Gonfa

Department of Chemistry, Jimma University, Jimma, Ethiopia

http://orcid.org/0000-0001-7547-4348

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APA Style

Babanto, Z. Z., Esmael, J., Gonfa, G. (2025). Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution. American Journal of Applied and Industrial Chemistry, 9(1), 1-12. https://doi.org/10.11648/j.ajaic.20250901.11

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ACS Style

Babanto, Z. Z.; Esmael, J.; Gonfa, G. Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution. Am. J. Appl. Ind. Chem. 2025, 9(1), 1-12. doi: 10.11648/j.ajaic.20250901.11

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AMA Style

Babanto ZZ, Esmael J, Gonfa G. Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution. Am J Appl Ind Chem. 2025;9(1):1-12. doi: 10.11648/j.ajaic.20250901.11

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@article{10.11648/j.ajaic.20250901.11,
  author = {Zeleke Zewde Babanto and Jafer Esmael and Guta Gonfa},
  title = {Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution
},
  journal = {American Journal of Applied and Industrial Chemistry},
  volume = {9},
  number = {1},
  pages = {1-12},
  doi = {10.11648/j.ajaic.20250901.11},
  url = {https://doi.org/10.11648/j.ajaic.20250901.11},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajaic.20250901.11},
  abstract = {This study focused on the remediation of methyl orange (MO) from wastewater by preparation of acid activated biochar from avocado pomace, which was obtained from Jimma Industrial Park, Ethiopia. This avocado pomace was considered as a solid waste and accumulated on waste disposal areas of the industrial park.  The optimal temperature of 500 °C was selected for further biochar preparation. Physicochemical properties of the biochar have fixed carbon content (71.15 ± 0.84%), ash content (12.95 ± 0.35%), moisture content (10.40 ± 0.45%), volatile matter content (5.50 ± 0.62%) as well as PZC (7.4 ± 0.85). The acid activated biochar at optimum temperature of before and after adsorption was characterized via FTIR, XRD, and SEM. The main parameters of solution pH (5), initial concentration (60 mg/L), mass of adsorbent (0.5 g), and contact time (120 min) were optimized. Langmuir model was more fitted to experimental data and adsorption mechanism was chemisorption; leads to the formation monolayer on the homogenous active site with maximum adsorption capacity 22.988 mg/g. The adsorption phenomena were consistent with PSO kinetics model (R2=0.9997) and adsorption mechanism was chemisorption. Thus, this low cost environmental friendly industrial waste effectively removes MO dye and solves the problem of industrial wastewater through adsorption. More research finding is recommended to study how well this adsorbent works in real wastewater samples.
},
 year = {2025}
}

Copy | Download

TY  - JOUR
T1  - Acid Activated Biochar Prepared from Avocado Pomace for Remediation of Methyl Orange Contaminated Aqueous Solution

AU  - Zeleke Zewde Babanto
AU  - Jafer Esmael
AU  - Guta Gonfa
Y1  - 2025/06/30
PY  - 2025
N1  - https://doi.org/10.11648/j.ajaic.20250901.11
DO  - 10.11648/j.ajaic.20250901.11
T2  - American Journal of Applied and Industrial Chemistry
JF  - American Journal of Applied and Industrial Chemistry
JO  - American Journal of Applied and Industrial Chemistry
SP  - 1
EP  - 12
PB  - Science Publishing Group
SN  - 2994-7294
UR  - https://doi.org/10.11648/j.ajaic.20250901.11
AB  - This study focused on the remediation of methyl orange (MO) from wastewater by preparation of acid activated biochar from avocado pomace, which was obtained from Jimma Industrial Park, Ethiopia. This avocado pomace was considered as a solid waste and accumulated on waste disposal areas of the industrial park.  The optimal temperature of 500 °C was selected for further biochar preparation. Physicochemical properties of the biochar have fixed carbon content (71.15 ± 0.84%), ash content (12.95 ± 0.35%), moisture content (10.40 ± 0.45%), volatile matter content (5.50 ± 0.62%) as well as PZC (7.4 ± 0.85). The acid activated biochar at optimum temperature of before and after adsorption was characterized via FTIR, XRD, and SEM. The main parameters of solution pH (5), initial concentration (60 mg/L), mass of adsorbent (0.5 g), and contact time (120 min) were optimized. Langmuir model was more fitted to experimental data and adsorption mechanism was chemisorption; leads to the formation monolayer on the homogenous active site with maximum adsorption capacity 22.988 mg/g. The adsorption phenomena were consistent with PSO kinetics model (R2=0.9997) and adsorption mechanism was chemisorption. Thus, this low cost environmental friendly industrial waste effectively removes MO dye and solves the problem of industrial wastewater through adsorption. More research finding is recommended to study how well this adsorbent works in real wastewater samples.

VL  - 9
IS  - 1
ER  -

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