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Sains Malaysiana 50(2)(2021): 373-381
http://dx.doi.org/10.17576/jsm-2021-5002-09
Degradation of Nonylphenol
Ethoxylate-10 (NPE-10) by Mediated Electrochemical Oxidation (MEO) Technology
(Degradasi Nonilfenol Etoksilat-10
(NPE-10) oleh Teknologi Gerak Balas Pengoksidaan Elektrokimia (MEO))
HENRY
SETIYANTO1,2*, MUHAMMAD. MUSLIM SYAIFULLAH1, I MADE
ADYATMIKA1, DIAN AYU SETYORINI1, MUHAMMAD YUDHISTIRA AZIS1,
VIENNA SARASWATY3 & MUHAMMAD ALI ZULFIKAR1
1Analytical
Chemistry Research Group, Institut Teknologi Bandung, Bandung, Indonesia
2Center
for Defense and Security Research, Institut Teknologi Bandung, Bandung 40132, Indonesia
3Research
Unit for Clean Technology, Indonesia Institute of Sciences, Bandung, Indonesia
Received:
2 January 2020/Accepted: 12 July 2020
ABSTRACT
Nonylphenol
ethoxylate (NPE-10) is a non-ionic surfactant that is synthesized from
alkylphenol ethoxylate. The accumulation of NPE-10 in wastewater will endanger
the ecosystem as well as the human being. Nowadays, NPE-10 can be degraded
indirectly by using an electrochemical treatment by the advancement of
technology. Thus, this study is aimed to evaluate the electro-degradation
potential of NPE-10 by MEO using Ce(IV) ionic mediator. In addition, the
influence of Ag(I) ionic catalyst in the performance of MEO for the degradation
of NPE-10 was also observed. The potency of MEO technology in the NPE-10
degradation was evaluated by voltammetry technique and confirmed by titrimetry and LC-MS analysis. The results
showed that in the absence of Ag(I) ionic catalyst, the degradation of NPE-10
by MEO was 85.93%. Furthermore, when the Ag(I) ionic catalyst was applied, the
performance of MEO in degradation of NPE-10 was improved to 95.12%. The back
titration using Ba(OH)2 confirmed the formation of CO2 by
46.79%, whereas the redox titration shows the total of degradation organic
compounds by 42.50%. It was emphasized by the formation of two new peaks in the
LC-MS chromatogram. In summary, our results confirmed the potential of MEO
technology for the NPE-10 degradation.
Keywords: Ag(I) catalyst ion; Ce(IV)
mediator ion; degradation; mediated electrochemical oxidation; NPE-10
ABSTRAK
Nonilfenol etoksilat (NPE-10) merupakan bahan surfaktan tidak berion yang disintesiskan daripada alkil fenoletoksilat. Pengumpulan NPE-10 dalam air buangan akan membahayakan ekosistem dan juga manusia.
Hari ini, NPE-10 dapat digradasikan secara tidak langsung dengan penggunaan rawatan elektrokimia oleh teknologi yang maju. Oleh itu, kajian ini adalah untuk mengkaji potensi degradasi elektro terhadap bahan NPE-10 oleh teknologi MEO dan menggunakan ion
Ce(IV) sebagai bahan perantara. Selain itu, pengaruh pemangkin ion Ag(I) dalam prestasinya kepada teknologi MEO untuk degradasi NPE-10 diperhati. Potensi teknologi MEO dalam degradasi NPE-10 telah dinilai daripada teknik voltametri dan disahkan dengan kaedah titrimetri dan analisis LC-MS. Keputusan kajian menunjukkan bahawa dengan ketiadaan pemangkin ion Ag(I), prestasi degradasi NPE-10 melalui teknologi MEO adalah 85.93%. Selain itu, apabila pemangkin ion Ag (I) digunakan, potensi MEO untuk degradasi NPE-10 ditingkatkan kepada 95.12%. Pentitratan balik menggunakan Ba(OH)2 mengesahkan bahawa terdapat penghasilan CO2 sebanyak 46.79%, sedangkan titrasi redoks menunjukkan jumlah sebatian organik yang digradasi sebanyak 42.50%. Jumlah degradasi ini ditekankan dengan penghasilan dua puncak daripada analisis kromatogram LC-MS. Secara kesimpulannya, keputusan kajian kami sah bahawa potensi teknologi MEO dalam degradasi NPE-10.
Kata kunci: Degradasi; ion perantara Ce(IV); gerak balas pengoksidaan elektrokimia; NPE-10; pemangkin ion Ag(I)
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*Corresponding
author; email: henry@chem.itb.ac.id
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