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Ag/ZnO Nanocomposite for Effective Dye Degradation in Presence Of Sunlight and Antibacterial Activity


Affiliations
1 Department of Chemistry, Madras Christian College (Affiliated to University of Madras), East Tambaram, Chennai 600 059,, India
 

In recent years search for efficient material to detoxify the environment has received great interest. Nanomaterials made up of transition metal oxide proved to be promising material for future owing to their extraordinary physical, chemical, and electronic properties. Among the different metal oxides, zinc oxide (ZnO) with wide band, good photostability, easy to prepare and low cost make it a viable source to remediate the environment. Addition of plasmonic structure to ZnO inhibits the charge carrier recombination and aids to absorb visible light. In this work, Ag/ZnO nanocomposites have been prepared using thermal method and characterized using X-ray diffraction, diffuse reflectance spectroscopy, scanning electron microscopy and energy dispersive analysis. Photocatalytic studies under sunlight to degrade methylene blue dye indicates the ability of synthesized material that can be utilized to treat dye effluents. The synthesized material has also shown good antibacterial activity.

Keywords

Dye degradation, Environment remediation, Photocatalysis, Plasmonic catalyst
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  • Nie M, Liao J, Cai H, Sun H, Xue Z, Guo P & Wu M, Chem Phys Lett, 768 (2021) 138394.
  • Anwer H, Mahmood A, Lee J, Kim K H, Park J W & Yip A C, Nano Res, 12 (2019) 955.
  • Montoya-Rodríguez D M, Serna-Galvis E A, Ferraro F & Torres-Palma R A, J Environ Manage, 261 (2020) 110224.
  • Samadi M, Zirak M, Naseri A, Kheirabadi M, Ebrahimi M & Moshfegh A Z, Res Chem Intermed, 45 (2019) 2197.
  • Murugan E & Pakrudheen I, Appl Catal A: General, 439 (2012) 142.
  • Murugan E, Jebaranjitham J N, Raman K J, Mandal A, Geethalakshmi D, Dharmendira Kumar M & Saravanakumar A, New J Chem, 41 (19) 10860.
  • Mauter M S, Zucker I, Perreault F, Werber J R, Kim J H & Elimelech M, Nat Sustain, 1 (2018) 166.
  • Zhao L, Denga J, Sun P, Liu J, Ji Y, Nakada N, Qiao Z, Tanaka H & Yang Y, Sci Total Environ, 627 (2018) 1253.
  • Weinberg N L & Weinberg H R, Chem Rev, 68 (1968) 449.
  • Azbar N U R I, Yonar T & Kestioglu K, Chemosphere, 55 (2004) 35.
  • Lee K M, Lai C W, Ngai K S & Juan J C, Water Res, 88 (2016) 428.
  • Ratnayake S P, Mantilaka M M M G P G, Sandaruwan C, Dahanayake D, Murugan E, Santhosh Kumar S, Amaratunga G A J & Nalin de Silva K M, Appl Catal A: Gen, 570 (2019) 23.
  • Murugan E & Rangasamy R, J Biomed Nanotechnol, 7 (2011) 225.
  • Murugan E & Shanmugam P, Bull Mater Sci, 38 (2015) 629.
  • Kudo A & Miseki Y, Chem Soc Rev, 38 (2009) 253.
  • Li Y, Gao C, Long R & Xiong Y, Mater Today Chem, 11 (2019) 197.
  • Danish M S S, Estrella L L, Alemaida I M A, Lisin A, Moiseev N, Ahmadi M, Nazari M, Wali M, Zaheb H & Senjyu T, Metals, 11 (2021) 80.
  • Prasad V, Gnanamani Simiyon G, Ansha E M & Jayaprakash N, Rasayan J Chem, 12 (2019) 860.
  • Lee K M, Lai C W, Ngai K S & Juan J C, Water Res, 88 (2016) 428.
  • Murugan E & Shanmugam P, J Nanosci Nanotechnol, 16 (2016) 426.
  • Murugan E & Jebaranjitham J N, J Biomed Nanotechnol, 7 (2011)158.
  • Ong C B, Ng L Y & Mohammad A W, Renew Sustain Energy Rev, 81 (2018) 536.
  • Cushing S K & Wu N, J Phys Chem Lett, 7 (2016) 666.
  • Wu N, Nanoscale, 10 (2018) 2679.
  • Li R, Li T & Zhou Q, Catalysts, 10 (2020) 804.
  • Yogaraj V, Gowtham G, Akshata C R, Manikandan R, Murugan E & Arumugam M, J Drug Deliv Sci Technol, 58 (2020) 101785.
  • Murugan E, Santhosh Kumar S, Reshna K M & Govindaraju S, J Mater Sci, 54 (2019) 5294.
  • Santhoshkumar S & Murugan E, Appl Surf Sci, 553 (2021) 149544.
  • Santhoshkumar S & Murugan E, Dalt Trans, 50 (2021) 17988.
  • Gopakumar D A, Pai A R, Pasquini D, Ben L S Y, Khalil H P S A & Thomas S, Nanoscale Mater Water Purif, (2019) 1.
  • Wanga Z, Ye X, Chen L, Huang P, Wang Q, Ma L, Hua N, Liu X, Xiao X & Chen S, Mater Sci Semicond Process, 121 (2021) 105354.
  • Murugan E, Akshata C R, Yogaraj V, Sudhandiran G & Babu D, Ceram Int, 48 (2022) 16000.
  • Mahmoud M S, Farah J Y & Farrag T E, J Pet, 22 (2013) 211.
  • Ziashahabi A, Mirko P, Zhiya D, Reza P & Naimeh N, Sci Rep, 9 (2019) 1.
  • Khan M J, Photodiagnosis Photodyn Ther, 36(2021) 102619.
  • Chauhan A, Sci Rep, 10 (2020) 1.
  • Lim H, Mohammad Y, Sehwan S, Sungkyun P & Kang H P, RSC Adv, 11 (2021) 8709.

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  • Ag/ZnO Nanocomposite for Effective Dye Degradation in Presence Of Sunlight and Antibacterial Activity

Abstract Views: 161  |  PDF Views: 99

Authors

Gnanamani Simiyon G
Department of Chemistry, Madras Christian College (Affiliated to University of Madras), East Tambaram, Chennai 600 059,, India
Mary Vergheese T
Department of Chemistry, Madras Christian College (Affiliated to University of Madras), East Tambaram, Chennai 600 059,, India

Abstract


In recent years search for efficient material to detoxify the environment has received great interest. Nanomaterials made up of transition metal oxide proved to be promising material for future owing to their extraordinary physical, chemical, and electronic properties. Among the different metal oxides, zinc oxide (ZnO) with wide band, good photostability, easy to prepare and low cost make it a viable source to remediate the environment. Addition of plasmonic structure to ZnO inhibits the charge carrier recombination and aids to absorb visible light. In this work, Ag/ZnO nanocomposites have been prepared using thermal method and characterized using X-ray diffraction, diffuse reflectance spectroscopy, scanning electron microscopy and energy dispersive analysis. Photocatalytic studies under sunlight to degrade methylene blue dye indicates the ability of synthesized material that can be utilized to treat dye effluents. The synthesized material has also shown good antibacterial activity.

Keywords


Dye degradation, Environment remediation, Photocatalysis, Plasmonic catalyst

References