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Abstract

Agricultural waste-based activated carbon has been applied to the treatment of antibiotics-loaded wastewater recently. In this article, cornstalk was employed as a raw material to manufacture a kind of granular activated carbon (GAC), which was then used to remove four antibiotics, including isoniazid (IN), sulfamethoxazole (SMZ), thiamphenicol (THI), and doxycycline (DOX), from water. The as-prepared GAC had a rough and porous structure; the surface area and total pore volume were 944.71 m²/g and 0.56 cm³/g, respectively. Kinetic and isothermal models were established to analyze the sorption mechanism and evaluate the sorption performance. Pseudo-second-order kinetic model fitted the sorption of IN, SMZ, THI, and DOX on the GAC better than pseudo-first-order model. Based on the Langmuir isothermal model, the maximum sorption capacities (q_m) of the GAC toward IN, SMZ, THI, and DOX were 27.0172, 36.9301, 28.0637, and 32.3902 mg/g, respectively. According to the Weber–Morris intraparticle diffusion model and the Boyd kinetics model, film diffusion was preponderant in the sorption process. Moreover, two-dimensional correlation spectroscopy integrated with Fourier-transform infrared spectroscopy was used to give the sequence of the different functional groups binding to the four antibiotics. To our knowledge, this is the first report on the sorption of IN, SMZ, THI, and DOX by cornstalk-based GAC. This work not only evaluated the application potential of cornstalk in the field of water purification but also provided a technical way for removing IN, SMZ, THI, and DOX from aqueous solution.

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References

Ahmed

M.J.

(2016). Preparation of activated carbons from date (Phoenix dactylifera L.) palm stones and application for wastewater treatments: Review. Process Saf. Environ. 102, 168.

Ahmed

M.J.

, and Theydan

S.K.

(2013). Microporous activated carbon from Siris, seed pods by microwave-induced KOH activation for metronidazole adsorption. J. Anal. Appl. Pyrol. 99, 101.

Armynah

, Atika., Djafar

, Piarah

W.H.

, and Tahir

(2018). Analysis of chemical and physical properties of Biochar from Rice Husk Biomass. J. Phys. Conf. Ser. 979, 12038.

Belhachemi

, and Djelaila

(2017). Removal of amoxicillin antibiotic from aqueous solutions by date pits activated carbons. Environ. Proc. 4, 549.

Z.Y.

, and Yu

S.L.

(2016). Occurrence of sulfamethoxazole in aquatic environment and its toxicity on zebrafish. J. P. Inst. Technol. 5, 78. [In Chinese.]

Çaliskan

, and Goktürk

(2010). Adsorption characteristics of sulfamethoxazole and metronidazole on activated carbon. Sep. Sci. Technol. 45, 244.

Chen

, Liu

, Xu

X.R.

, Zhou

G.J.

, Liu

S.S.

, Yue

W.Z.

, Sun

K.F.

, and Ying

G.G.

(2015a). Antibiotics in the coastal environment of the Hailing Bay region, South China Sea: Spatial distribution, source analysis and ecological risks. Mar. Pollut. Bull. 95, 365.

Chen

, Zhang

, Yue

, Li

, and Li

(2010). Equilibrium and kinetic studies of methyl orange and methyl violet adsorption on activated carbon derived from Phragmites australis. Desalination, 252, 149.

Chen

, Habibul

, Liu

X.Y.

, Sheng

G.P.

, and Yu

H.Q.

(2015b). FTIR and synchronous fluorescence heterospectral two-dimensional correlation analyses on the binding characteristics of copper onto dissolved organic matter. Environ. Sci. Technol. 49, 2052.

10.

Dai

J.L.

, Zhang

, Hu

Q.H.

, Huang

Y.Z.

, Wang

R.Q.

, and Zhu

Y.G.

(2009). Adsorption and desorption of iodine by various Chinese soils: II. Iodide and iodate. Geoderma, 153, 130.

11.

Dong

C.Y.

, Chen

, Guan

R.L.

, Li. X.J., and Xin

Y.F.

(2018). Dual-frequency ultrasound combined with alkali pretreatment of corn stalk for enhanced biogas production. Renew. Energ. 127, 444.

12.

Halling-Sørensen

, Sengeløv

, and Tjørnelund

(2002). Toxicity of tetracyclines and tetracycline degradation products to environmentally relevant bacteria, including selected tetracycline-resistant bacteria. Arch. Environ. Con. Tox. 42, 263.

13.

J.S.

, Dai

J.D.

, Zhang

, Sun

, Xie

A.T.

, Tian

S.J.

, Yan

Y.S.

, and Huo

P.W.

(2016). Preparation of highly porous carbon from sustainable α-cellulose for superior removal performance of tetracycline and sulfamethazine from water. R. Soc. Chem. 6, 28023.

14.

Y.S.

, and Mckay

(1999). Pseudo-second order model for sorption processes. Process Biochem. 34, 451.

15.

Jeong

, Song

W.H.

, Cooper

W.J.

, Jung

, and Greaves

(2010). Degradation of tetracycline antibiotics: Mechanisms and kinetic studies for advanced oxidation/reduction processes. Chemosphere, 78, 533.

16.

Kakavandi

, Esrafili

, Mohseni-Bandpi

, Jonidi

J.A.

, and Rezaei

K.R.

(2014). Magnetic Fe₃O₄@C nanoparticles as adsorbents for removal of amoxicillin from aqueous solution. Water Sci. Technol. 69, 147.

17.

Kaur

, Umar

, and Kansal

S.K.

(2015). Sunlight-driven photocatalytic degradation of non-steroidal anti-inflammatory drug based on TiO₂ quantum dots. J. Colloid Interf. Sci. 459, 257.

18.

Kong

W.D.

, and Zhu

Y.G.

(2007). A review on ecotoxicology of veterinary pharmaceuticals to plants and soil microbes. Asian J. Ecotoxicol. 2, 1. (in Chinese.)

19.

Koumaki

, Mamais

, and Noutsopoulos

(2017). Environmental fate of nonsteroidal anti-inflammatory drugs in riverwater/sediment systems. J. Hazard. Mater. 323, 233.

20.

, Shi

W.Z.

, Liu

, Li

H.M.

, Zhang

, Hu

J.R.

, Ke

Y.C.

, Sun

W.L.

, and Ni

J.R.

(2017). A duodecennial national synthesis of antibiotics in China's major rivers and seas (2005–2016). Sci. Total. Environ. 615, 906.

21.

, Schulz

, Ackley

, and Fenske

(2010). Adsorption of tetracycline on kaolinite with pH-dependent surface charges. J. Colloid Interf. Sci. 351, 254.

22.

Lipiec

, Birarda

, Kowalska

, Lekki

, Vaccari

, Wiecheć

, Wood

B.R.

, and Kwiatek

W.M.

(2013). A new approach to studying the effects of ionising radiation on single cells using FTIR synchrotron microspectroscopy. Radiat. Phys. Chem. 93, 135.

23.

Liu

A.P.

, Huang

, Wang

W.Q.

, and Tan

H.T.

(2018). Preparation of iron modified clinoptilolite and its adsorption results on Sb(V). J. Miner. Petrol. 38, 7.

24.

Liu

P.P.

, Wang

Q.R.

, Zheng

C.L.

, and He

(2017). Sorption of sulfadiazine, norfloxacin, metronidazole, and tetracycline by granular activated carbon: Kinetics, mechanisms, and isotherms. Water Air Soil Poll. 228, 129.

25.

Moussavi

, Alahabadi

, Yaghmaeian

, and Eskandari

(2013). Preparation, characterization and adsorption potential of the NH₄Cl-induced activated carbon for the removal of amoxicillin antibiotic from water. Chem. Eng. J. 217, 119.

26.

Ofomaja

A.E.

, Naidoo

E.B.

, and Modise

S.J.

(2010). Dynamic studies and pseudo-second order modeling of copper (II) biosorption onto pine cone powder. Desalination, 251, 112.

27.

Rivera-Utrilla

, Prados-Joya

, Sánchez-Polo

, FerroGarcía

M.A.

, and Bautista-Toledo

(2009). Removal of nitroimidazole antibiotics from aqueous solution by adsorption/bioadsorption on activated carbon. J. Hazard. Mater. 170, 298.

28.

Rodríguez-Alvarez

, Rodil

, Quintana

J.B.

, Trinanes

, and Cela

(2013). Oxidation of non-steroidal anti-inflammatory drugs with aqueous permanganate. Water Res. 47, 3220.

29.

Sayğılı

, and Güzel

(2016). Effective removal of tetracycline from aqueous solution using activated carbon prepared from tomato (Lycopersicon esculentum Mill.) industrial processing waste. Ecotox. Environ. Safe. 131, 22.

30.

Terzyk

A.P.

(2001). The influence of activated carbon surface chemical composition on the adsorption of acetaminophen (paracetamol) in vitro Part II. TG, FTIR, and XPS analysis of carbons and the temperature dependence of adsorption kinetics at the neutral pH. Colloid Surf. A, 177, 23.

31.

Tian

Z.H.

, Wu

, Liu

W.T.

, Shen

L.R.

, and Li

G.Y.

(2015). Two-dimensional infrared spectroscopic study on the thermally induced structural changes of glutaraldehyde-crosslinked collagen. Spectrochim. Acta A. 140, 356.

32.

Sun

F.S.

, Li

Y.Q.

, Wang

, Chi

Z.L.

, and Yu

G.H.

(2017). Using new hetero-spectral two-dimensional correlation analyses and synchrotron-radiation-based spectromicroscopy to characterize binding of Cu to soil dissolved organic matter. Environ. Pollut. 223, 457.

33.

Takdastan

, Mahvi

A.H.

, Lima

E.C.

, Shirmardi

, Babaei

A.A.

, Goudarzi

, Neisi

, Farsani

M.H.

, and Vosoughi

(2016). Preparation, characterization, and application of activated carbon from low-cost material for the adsorption of tetracycline antibiotic from aqueous solutions. Water Sci. Technol. 74, 2349.

34.

Tang

, Lin

Y.W.

, Yu

, and Luo

Y.B.

(2012). Study of aniline/ɛ-caprolactam mixture adsorption from aqueous solution onto granular activated carbon: Kinetics and equilibrium. Chem. Eng. J. 187, 69.

35.

B.X.

, and Zhang

(2015). Analysis of the pollution status and health risk of antibiotics in water environment and drinking water. J. Environ. Health. 32, 173.

36.

Zhang

, Yin

, Zhao

, Zhu

, and Wang

(2015a). Adsorption and removal of tetracycline from water by petroleum coke-derived highly porous activated carbon. J. Environ. Chem. Eng. 3, 1504.

37.

Zhang

, Chen

L.P.

, Yin

,L., Jin

, Liu

, and Chen

H.H.

(2017). Mechanism study of humic acid functional groups for Cr(VI) retention: Two-dimensional FTIR and ¹³C CP/MAS NMR correlation spectroscopic analysis. Environ. Pollut. 225, 86.

38.

Zhang

, and Chen

(2018). Dried powder of corn stalk as a potential biosorbent for the removal of iodate from aqueous solution. J. Environ. Radioactiv. 190–191, 73.

39.

Zhang

Q.Q.

, Ying

G.G.

, Pan

C.G.

, Liu

Y.S.

, and Zhao

J.L.

(2015b). Comprehensive evaluation of antibiotics emission and fate in the river basins of China: Source analysis, multimedia modeling, and linkage to bacterial resistance. Environ. Sci. Technol. 49, 6772.

40.

Zhang

, Sun

, Gao

, Zhang

, Liu

, and Zhao

(2011). A dsorption of tetracycline on soil and sediment: Effects of pH and the presence of Cu(II). J. Hazard. Mater. 190, 856.

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Preparation of Granular Activated Carbon and Its Mechanism in the Removal of Isoniazid,Sulfamethoxazole,Thiamphenicol,and Doxycycline from Aqueous Solution

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