Evaluation of Lightweight Expanded-Clay Aggregates as Bed Material in Constructed Wetlands for Attenuation of Antibiotics

Recently, lightweight expanded-clay aggregates (LECAs) have emerged as a promising material for various geoenvironmental applications. This study aimed to explore the potential of LECAs as an adsorbent in a laboratory-scale constructed wetland to mitigate the impact of antibiotics, specifically eryt...

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Veröffentlicht in:	Journal of environmental engineering (New York, N.Y.) N.Y.), 2023-11, Vol.149 (11)
Hauptverfasser:	Adhikary, Avishek, Mondal, Suchhanda, Gantait, Jhilik, Pal, Supriya, Ghosh, Sudipta
Format:	Artikel
Sprache:	eng
Schlagworte:	Adsorbents Adsorption Aggregates Antibiotics Artificial wetlands Cation exchange Cation exchanging Clay Doxycycline Erythromycin High temperature Hydrogen Hydrogen bonding Ions Isotherms Lightweight Multilayers pH effects Physical characteristics Physical properties Sorbents Sorption Specific surface Surface area Surface chemistry Wetlands
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creator	Adhikary, Avishek Mondal, Suchhanda Gantait, Jhilik Pal, Supriya Ghosh, Sudipta
description	Recently, lightweight expanded-clay aggregates (LECAs) have emerged as a promising material for various geoenvironmental applications. This study aimed to explore the potential of LECAs as an adsorbent in a laboratory-scale constructed wetland to mitigate the impact of antibiotics, specifically erythromycin (ery) and doxycycline (doxy). The physical characteristics of LECA were determined, including hydraulic conductivity of 1.12×10−3 m/s, a specific surface area of 2,890 m2/kg, and a pH value of 7.6. In the laboratory-scale batch study, Langmuir (KL=3.2565 L/mg) and Freundlich [Kf=0.2376 (mg/g) (L/mg)] isotherm models provided the best fit for doxy and ery, respectively. Additionally, the pseudo-second-order kinetic model exhibited the best fit for both antibiotics. The adsorption of doxy was primarily attributed to π–π interactions and hydrogen bonding, explaining why it followed the Langmuir isotherm with most sorbents. On the other hand, ery exhibited electrostatic sorption and cation exchange as the dominant mechanisms, potentially demonstrating its multilayer sorption behavior. A shift from an acidic to an alkaline pH significantly enhanced the adsorption of both doxy (16% to 94%) and ery (45% to 89%). Similarly, raising the temperature from 5°C to 45°C increased the sorption capacity to 83% for doxy and 88% for ery. In the one-dimensional vertical-column study using LECA as the adsorbent, the exhaustion time for ery and doxy was determined to be 70 and 84 h, respectively. These results aligned well with the findings obtained from the HYDRUS model. Constructed wetlands employing LECA beds demonstrated remarkable removal efficiencies, with doxy removal from 93% to 96% and ery removal from 92% to 97%. A long-term study on LECA after pouring studied antibiotics solution in cycles revealed an appreciable drop in removal efficiencies at the end of an extensive period. Based on these observations, it can be concluded that LECA possesses a significant adsorption capacity against doxy and ery due to high in situ pH, specific surface area, and hydraulic conductivity. Under acidic conditions, ery exhibited higher sorption capacity in comparison to doxy because of the preponderance of H+ ions. However, in an alkaline state, the abundance of OH− ions hindered the release of H+ ions, resulting in minimal changes in the adsorption capacity of ery, unlike doxy, which displayed a steady increase. Furthermore, elevated temperatures enhanced the adsorption capacity
doi_str_mv	10.1061/JOEEDU.EEENG-7368
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This study aimed to explore the potential of LECAs as an adsorbent in a laboratory-scale constructed wetland to mitigate the impact of antibiotics, specifically erythromycin (ery) and doxycycline (doxy). The physical characteristics of LECA were determined, including hydraulic conductivity of 1.12×10−3 m/s, a specific surface area of 2,890 m2/kg, and a pH value of 7.6. In the laboratory-scale batch study, Langmuir (KL=3.2565 L/mg) and Freundlich [Kf=0.2376 (mg/g) (L/mg)] isotherm models provided the best fit for doxy and ery, respectively. Additionally, the pseudo-second-order kinetic model exhibited the best fit for both antibiotics. The adsorption of doxy was primarily attributed to π–π interactions and hydrogen bonding, explaining why it followed the Langmuir isotherm with most sorbents. On the other hand, ery exhibited electrostatic sorption and cation exchange as the dominant mechanisms, potentially demonstrating its multilayer sorption behavior. A shift from an acidic to an alkaline pH significantly enhanced the adsorption of both doxy (16% to 94%) and ery (45% to 89%). Similarly, raising the temperature from 5°C to 45°C increased the sorption capacity to 83% for doxy and 88% for ery. In the one-dimensional vertical-column study using LECA as the adsorbent, the exhaustion time for ery and doxy was determined to be 70 and 84 h, respectively. These results aligned well with the findings obtained from the HYDRUS model. Constructed wetlands employing LECA beds demonstrated remarkable removal efficiencies, with doxy removal from 93% to 96% and ery removal from 92% to 97%. A long-term study on LECA after pouring studied antibiotics solution in cycles revealed an appreciable drop in removal efficiencies at the end of an extensive period. Based on these observations, it can be concluded that LECA possesses a significant adsorption capacity against doxy and ery due to high in situ pH, specific surface area, and hydraulic conductivity. Under acidic conditions, ery exhibited higher sorption capacity in comparison to doxy because of the preponderance of H+ ions. However, in an alkaline state, the abundance of OH− ions hindered the release of H+ ions, resulting in minimal changes in the adsorption capacity of ery, unlike doxy, which displayed a steady increase. 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This study aimed to explore the potential of LECAs as an adsorbent in a laboratory-scale constructed wetland to mitigate the impact of antibiotics, specifically erythromycin (ery) and doxycycline (doxy). The physical characteristics of LECA were determined, including hydraulic conductivity of 1.12×10−3 m/s, a specific surface area of 2,890 m2/kg, and a pH value of 7.6. In the laboratory-scale batch study, Langmuir (KL=3.2565 L/mg) and Freundlich [Kf=0.2376 (mg/g) (L/mg)] isotherm models provided the best fit for doxy and ery, respectively. Additionally, the pseudo-second-order kinetic model exhibited the best fit for both antibiotics. The adsorption of doxy was primarily attributed to π–π interactions and hydrogen bonding, explaining why it followed the Langmuir isotherm with most sorbents. On the other hand, ery exhibited electrostatic sorption and cation exchange as the dominant mechanisms, potentially demonstrating its multilayer sorption behavior. A shift from an acidic to an alkaline pH significantly enhanced the adsorption of both doxy (16% to 94%) and ery (45% to 89%). Similarly, raising the temperature from 5°C to 45°C increased the sorption capacity to 83% for doxy and 88% for ery. In the one-dimensional vertical-column study using LECA as the adsorbent, the exhaustion time for ery and doxy was determined to be 70 and 84 h, respectively. These results aligned well with the findings obtained from the HYDRUS model. Constructed wetlands employing LECA beds demonstrated remarkable removal efficiencies, with doxy removal from 93% to 96% and ery removal from 92% to 97%. A long-term study on LECA after pouring studied antibiotics solution in cycles revealed an appreciable drop in removal efficiencies at the end of an extensive period. Based on these observations, it can be concluded that LECA possesses a significant adsorption capacity against doxy and ery due to high in situ pH, specific surface area, and hydraulic conductivity. 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Furthermore, elevated temperatures enhanced the adsorption capacity by accelerating intraparticle diffusion.</description><subject>Adsorbents</subject><subject>Adsorption</subject><subject>Aggregates</subject><subject>Antibiotics</subject><subject>Artificial wetlands</subject><subject>Cation exchange</subject><subject>Cation exchanging</subject><subject>Clay</subject><subject>Doxycycline</subject><subject>Erythromycin</subject><subject>High temperature</subject><subject>Hydrogen</subject><subject>Hydrogen bonding</subject><subject>Ions</subject><subject>Isotherms</subject><subject>Lightweight</subject><subject>Multilayers</subject><subject>pH effects</subject><subject>Physical characteristics</subject><subject>Physical properties</subject><subject>Sorbents</subject><subject>Sorption</subject><subject>Specific surface</subject><subject>Surface area</subject><subject>Surface chemistry</subject><subject>Wetlands</subject><issn>0733-9372</issn><issn>1943-7870</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><recordid>eNpFkMFOwzAQRC0EEqXwAdwscU6x49hOjiWEAir0QsXRchw7uApxsR2gf09KkbjsalezM6sHwCVGM4wYvn5cVdXtelZV1fMi4YTlR2CCi4wkPOfoGEwQJyQpCE9PwVkIG4Rwxgo-AbvqU3aDjNb10Bm4tO1b_NL7Cqvvrewb3SRlJ3dw3rZetzLqAGWAN7qBT-Pgreyg7WHp-hD9oOK4f9WxGw8DNM7DeYy6__ef99HW1kWrwjk4MbIL-uKvT8H6rnop75PlavFQzpeJSjmJ48-K0VQVjeSENtwwpQtFlUSsyJDkNaV11tSE0iyrGTI6ZYYzM0oRrWmOOZmCq4Pv1ruPQYcoNm7w_Rgp0pzhrMh5mo8qfFAp70Lw2oitt-_S7wRGYk9YHAiLX8JiT5j8AJjacPI</recordid><startdate>202311</startdate><enddate>202311</enddate><creator>Adhikary, Avishek</creator><creator>Mondal, Suchhanda</creator><creator>Gantait, Jhilik</creator><creator>Pal, Supriya</creator><creator>Ghosh, Sudipta</creator><general>American Society of Civil Engineers</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7QF</scope><scope>7QO</scope><scope>7QQ</scope><scope>7SC</scope><scope>7SE</scope><scope>7SP</scope><scope>7SR</scope><scope>7ST</scope><scope>7T7</scope><scope>7TA</scope><scope>7TB</scope><scope>7U5</scope><scope>8BQ</scope><scope>8FD</scope><scope>C1K</scope><scope>F28</scope><scope>FR3</scope><scope>H8D</scope><scope>H8G</scope><scope>JG9</scope><scope>JQ2</scope><scope>KR7</scope><scope>L7M</scope><scope>L~C</scope><scope>L~D</scope><scope>P64</scope><scope>SOI</scope><orcidid>https://orcid.org/0000-0003-0783-2005</orcidid></search><sort><creationdate>202311</creationdate><title>Evaluation of Lightweight Expanded-Clay Aggregates as Bed Material in Constructed Wetlands for Attenuation of Antibiotics</title><author>Adhikary, Avishek ; 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This study aimed to explore the potential of LECAs as an adsorbent in a laboratory-scale constructed wetland to mitigate the impact of antibiotics, specifically erythromycin (ery) and doxycycline (doxy). The physical characteristics of LECA were determined, including hydraulic conductivity of 1.12×10−3 m/s, a specific surface area of 2,890 m2/kg, and a pH value of 7.6. In the laboratory-scale batch study, Langmuir (KL=3.2565 L/mg) and Freundlich [Kf=0.2376 (mg/g) (L/mg)] isotherm models provided the best fit for doxy and ery, respectively. Additionally, the pseudo-second-order kinetic model exhibited the best fit for both antibiotics. The adsorption of doxy was primarily attributed to π–π interactions and hydrogen bonding, explaining why it followed the Langmuir isotherm with most sorbents. On the other hand, ery exhibited electrostatic sorption and cation exchange as the dominant mechanisms, potentially demonstrating its multilayer sorption behavior. A shift from an acidic to an alkaline pH significantly enhanced the adsorption of both doxy (16% to 94%) and ery (45% to 89%). Similarly, raising the temperature from 5°C to 45°C increased the sorption capacity to 83% for doxy and 88% for ery. In the one-dimensional vertical-column study using LECA as the adsorbent, the exhaustion time for ery and doxy was determined to be 70 and 84 h, respectively. These results aligned well with the findings obtained from the HYDRUS model. Constructed wetlands employing LECA beds demonstrated remarkable removal efficiencies, with doxy removal from 93% to 96% and ery removal from 92% to 97%. A long-term study on LECA after pouring studied antibiotics solution in cycles revealed an appreciable drop in removal efficiencies at the end of an extensive period. Based on these observations, it can be concluded that LECA possesses a significant adsorption capacity against doxy and ery due to high in situ pH, specific surface area, and hydraulic conductivity. Under acidic conditions, ery exhibited higher sorption capacity in comparison to doxy because of the preponderance of H+ ions. However, in an alkaline state, the abundance of OH− ions hindered the release of H+ ions, resulting in minimal changes in the adsorption capacity of ery, unlike doxy, which displayed a steady increase. Furthermore, elevated temperatures enhanced the adsorption capacity by accelerating intraparticle diffusion.</abstract><cop>New York</cop><pub>American Society of Civil Engineers</pub><doi>10.1061/JOEEDU.EEENG-7368</doi><orcidid>https://orcid.org/0000-0003-0783-2005</orcidid></addata></record>
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subjects	Adsorbents Adsorption Aggregates Antibiotics Artificial wetlands Cation exchange Cation exchanging Clay Doxycycline Erythromycin High temperature Hydrogen Hydrogen bonding Ions Isotherms Lightweight Multilayers pH effects Physical characteristics Physical properties Sorbents Sorption Specific surface Surface area Surface chemistry Wetlands
title	Evaluation of Lightweight Expanded-Clay Aggregates as Bed Material in Constructed Wetlands for Attenuation of Antibiotics
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