Facile and green synthesis of silver nanoparticle-reduced graphene oxide composite and its application as nonenzymatic electrochemical sensor for hydrogen peroxide

Bhangoji, J.; Sahoo, S.; Satpati, A.; Shendage, S.

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Current Chemistry Letters

ISSN 1927-730x (Online) - ISSN 1927-7296 (Print) Quarterly Publication Volume 10 Issue 3 pp. 295-308 , 2021

Facile and green synthesis of silver nanoparticle-reduced graphene oxide composite and its application as nonenzymatic electrochemical sensor for hydrogen peroxide Pages 295-308 Download PDF

Authors: Jagdish C. Bhangoji, Srikant Sahoo, Ashis Kumar Satpati, Suresh S. Shendage

DOI: 10.5267/j.ccl.2021.3.002

Keywords: Electrocatalysis, Electrochemical sensors, Hydrogen peroxide, rGO, Silver NPs

Abstract: Due to the new hopes for treatment of multiple sclerosis (MS) diseases by Teriflunomide (TFN), in this project, a cheap, robust, and fully validated method has been developed both for determination of assay content in API (active pharmaceutical ingredient), and for related impurities analysis (RIA). To operate the method, a common C18, end-capped (250 × 4.6) mm, 5µm liquid chromatography column, was applied. The mobile phase A was prepared by dissolving 2.74 g (20mM) of PDP (potassium dihydrogen phosphate) and 3.72 g (50mM) of PC (potassium chloride) in water (1000 mL). Then, pH was adjusted to 3.0 by adding OPA (ortho-phosphoric acid) 85%; while, the mobile phase B was acetonitrile (ACN) (100%). In order to confirm the experimental data about the λmax of TFN, we have used the Born-Oppenheimer molecular dynamics (BOMD) simulations, quantum mechanics (QM), and TD-DFT calculations. According to the results, the method showed a high level of suitability, specificity, linearity, accuracy, precision, repeatability, robustness, and reliable detection limit.

How to cite this paper

 Bhangoji, J., Sahoo, S., Satpati, A & Shendage, S. (2021). Facile and green synthesis of silver nanoparticle-reduced graphene oxide composite and its application as nonenzymatic electrochemical sensor for hydrogen peroxide.Current Chemistry Letters, 10(3), 295-308.

Refrences

1. Mahaseth T., Kuzminov A (2017) Potentiation of Hydrogen Peroxide Toxicity From Catalase Inhibition to Stable DNA-iron Complexes. Mutat Res., 773 274–281.
2. Zhao L., Wang Y., Zhao X., Deng Y., Li Q., Xia Y (2018) Green Preparation of Ag-Au Bimetallic Nanoparticles Supported on Graphene with Alginate for Non-Enzymatic Hydrogen Peroxide Detection. Nanomaterials, 8 (7) 507.
3. Fu L., Lai G., Jia B., Yu A (2015) Preparation and Electrocatalytic Properties of Polydopamine Functionalized Reduced Graphene Oxide-Silver Nanocomposite. Electrocatalysis, 6 (1) 72-76.
4. Noor AM., Shahid MM., Rameshkumar P., Huang NM (2016) A glassy carbon electrode modified with graphene oxide and silver nanoparticles for amperometric determination of hydrogen peroxide. Microchim Acta, 183 (2) 911-916.
5. Nia PM., Meng WP., Alias Y (2015) Hydrogen peroxide sensor: Uniformly decorated silver nanoparticles on polypyrrole for wide detection range. Applied Surface Science, 357-B 1565-1572.
6. Li X., Liu Y., Zheng L., Dong M., Xue Z., Lu X., Liu X (2013) A novel nonenzymatic hydrogen peroxide sensor based on silver nanoparticles and ionic liquid functionalized multiwalled carbonnanotube composite modified electrode. Electrochimica Acta, 113 170-175.
7. Hurdis EC., Romeyn H (1954) Accuracy of determination of hydrogen peroxide by cerate oxidimetry. Anal. Chem., 26 (2) 320-325.
8. Abo M., Urano Y., Hanaoka K., Terai T., Komatsu T., Nagano T (2011) Development of a highly sensitive fluorescence probe for hydrogen peroxide. J. Am. Chem. Soc., 133 (27) 10629-10637.
9. Jiao T., Leca-Bouvier BD., Boullanger P., Blum LJ., Girard-Egrot AP (2008) Electrochemiluminescent detection of hydrogen peroxide using amphiphilic luminol derivatives in solution. Colloids and Surfaces A: Physicochem. Eng. Aspects, 321 (1-3) 143-146.
10. Pappas AC., Stalikas CD., Fiamegos YC., Karayannis MI (2002) Determination of hydrogen peroxide by using a flow injection system with immobilized peroxidase and long pathlength capillary spectrophotometry. Analytica Chimica Acta, 455 (2) 305-313.
11. Yu A., Wang Q., Yong J., Mahon PJ., Malherbe F., Wang F., Zhang H., Wang J (2012) Silver nanoparticle–carbon nanotube hybrid films: preparation and electrochemical sensing. Electrochimica Acta, 74 111-116.
12. Yang Z., Qi C., Zheng X., Zheng J (2016) Sensing hydrogen peroxide with a glassy carbon electrode modified with silver nanoparticles, AlOOH and reduced graphene oxide. Microchim Acta, 183 (3) 1131-1136.
13. Feng L., Gao G., Huang P., Wang X., Zhang C., Zhang J., Guo S., Cui D (2011) Preparation of Pt-Ag alloy nanoisland/graphene hybrid composites and its high stability and catalytic activity in methanol electro-oxidation. Nanoscale Res. Lett., 6 (1) 1–10.
14. Rajabzade H., Daneshgar P., Tazikeh E., Mehrabian RZ (2012) Functionalized carbonnanotubes with gold nanoparticles to fabricate a sensor for hydrogen peroxide determination. E-J. Chemistry, 9 (4) 2540-2549.
15. Liu X., Xu X., Zhu H., Yang X (2013) Synthesis of graphene nanosheets with incorpo-rated silver nanoparticles for enzymeless hydrogen peroxide detection. Anal. Methods, 5 (9) 2298-2304.
16. Wang Q, Yun Y (2013) Nonenzymatic sensor for hydrogen peroxide based on the elec-trodeposition of silver nanoparticles on poly (ionic liquid)-stabilized graphene sheets. Microchim Acta 180 (3-4) 261–268.
17. Yu B., Feng J., Liu S., Zhang T (2013) Preparation of reduced graphene oxide deco-rated with high density Ag nanorods for nonenzymatic hydrogen peroxide detection. RSC Adv., 3 (34) 14303–14307.
18. Tian L., Xia K., Hu W., Zhong X., Chen Y., Yang C., He G., Su Y., Li L (2017) A wide linear range and stable H2O2 electrochemical sensor based on Ag decorated hierarchical Sn3O4. Electrochimica Acta, 231 190-199.
19. Nia PM., Meng WP., Alias Y (2015) Hydrogen peroxide sensor: Uniformly decorated silver nanoparticles on polypyrrole for wide detection range. Applied Surface Science, 357 (B) 1565–1572.
20. Lorestani F., Shahnavaz Z., Mn P., Alias Y., Manan NSA (2015) One-step hydrothermal green synthesis of silver nanoparticles carbonnanotube reduced-graphene oxide composite and its application as hydrogen peroxide sensor. Sensors and Actuators B, 208 389-398.
21. Golsheikh AM., Huang NM., Lim HN., Zakaria R., Yin CY (2013) One-step electrodeposition synthesis of silver-nanoparticle-decorated graphene on indium-tin-oxide for enzymeless hydrogen peroxide detection. Carbon, 62 405-412.
22. Abdolhosseinzadeh S., Asgharzadeh H., Kim HS (2015) Fast and fully-scalable synthesis of reduced graphene oxide. Sci. Rep., 5 1-7.
23. Zhang Y., Liu S., Wang L., Qin X., Tian J., Lu W., Chang G., Sun X (2012) One-pot green synthesis of Ag nanoparticles-graphene composites and their applications in SERS, H2O2, and glucose sensing. RSC Advances, 2 538-545.
24. Liu S., Tian J., Wang L., Sun X (2011) A method for the production of reduced graphene oxide using benzylamine as a reducing and stabilizing agent and its subsequent decoration with Ag nanoparticles for enzymeless hydrogen peroxide detection. Carbon, 49 3158-3164.
25. Zhao B., Liu Z., Fu W., Yang H (2013) Construction of 3D electrochemically reduced graphene oxide silver nanocomposite film and application as nonenzymatic hydrogen peroxide sensor. Electrochemistry Communications, 27 1–4.
26. Welch CM., Banks CE., Simm AO., Compton RG (2005) Silver nanoparticle assemblies supported on glassy carbon electrodes for the electro-analytical detection of hydrogen peroxide. Anal Bioanal Chem, 382 (1) 12-21.
27. Shendage SS., Patil UB., Nagarkar JM (2013) Electrochemical deposition of Highly Dispersed Palladium Nanoparticles on Nafion-Graphene Film in Presence of Ferrous ions for Ethanol Electrooxidation. Fuel Cells, 13 (3) 364–370.
28. Zhao L., Wang Y., Zhao X., Deng Y., Li Q., Xia Y (2018) Green Preparation of Ag-Au Bimetallic Nanoparticles Supported on Graphene with Alginate for Non-Enzymatic Hydrogen Peroxide Detection. Nanomaterials, 8 (7) 507.
29. Zhang K., Chen X., Li Z., Wang Y., Sun S., Wang L., Guo T., Zhang D., Xue Z., Zhou X., Lu X., Xue Z (2018) Au-Pt bimetallic nanoparticles decorated on sulfonated nitrogen sulphur co-doped graphene for simultaneous determination of dopamine and uric acid. Talanta, 178 315-323.
30. Noor AM., Shahid MM., Rameshkumar P., Huang NM (2016) A glassy carbon electrode modified with graphene oxide and silver nanoparticles for amperometric determination of hydrogen peroxide. Microchim Acta, 183 (2) 911–916.
31. Feng W., Yang L., Cao N., Du C., Dai H., Luo W., Cheng G (2014) In situ facile synthesis of bimetallic CoNi catalyst supported on graphene for hydrolytic dehydrogenation of amine borane. Int. J. Hydrogen Energy, 39 (7) 3371–3380.
32. Zhang W., Qiao X., Chen J (2006) Synthesis and characterization of silver nanoparticles in AOT microemulsion system. Chemical Physics, 330 (3) 495–500.
33. Zhao F., Zhou M., Wang L., Huang Z., Chu Y (2019) One-step voltammetric deposition of l-proline assisted silver nanoparticles modified glassy carbon electrode for electrochemical detection of hydrogen peroxide. J. Electroanalytical Chemistry, 833 205-212.
34. Zhou Y., Yin H., Meng X., Xu Z., Fu Y., Ai S (2012) Direct electrochemistry of sarcosine oxidase on graphene, chitosan and silver nanoparticles modified glassy carbon electrode and its biosensing for hydrogen peroxide. Electrochimica Acta, 71 294–301.
35. Anandalakshmi K., Venugobal J., Ramasamy V (2016) Characterization of silver nanoparticles by green synthesis method using Pedalium murex leaf extract and their antibacterial activity. Appl Nanosci, 6 (3) 399-408.
36. Ganesan V., Deepa B., Nima P., Astalakshmi A (2014) Bio-inspired of silver nanoparticles using leaves of Millingtonia hortensis L.f. J. Adv. Biotechnol. And Res., 5 (2) 93-100.
37. Park HH., Zhang X., Choi YJ., Park HH., Hill RH (2011) Synthesis of Ag Nanostructures by Photochemical Reduction Using Citrate-Capped Pt Seeds. J. Nanomaterials, 2011 1-7.
38. C. Li., Y. Yao (2020) Synthesis of bimetallic core-shell silver-copper nanoparticles decorated on reduced graphene oxide with enhanced electrocatalytic performance. Chemical Physics Letters, 761 137726.
39. D. Li., L. Meng., P. Xiao., D. Jiang., S. Dang., M. Chen (2017) Enhanced non-enzymatic electrochemical sensing of hydrogen peroxide based on Cu2O nanocubes/Ag-Au alloy nanoparticles by incorporation of RGO nanosheets. J. Electroanalytical Chemistry, 791 23-28.
40. J. Li., J. Jiang., Z. Xu., M. Liu., S. Tang., C. Yang., D. Qian (2018) with enhanced electrocatalytic activity for ultrasensitive detection of H2O2. Sensors and Actuators B, 260 529-540.
41. X. Qina, Y. Luoa., W. Lua., G. Changa., AM. Asiri., AO. Al-Youbi., X. Sun (2012) One-step synthesis of Ag nanoparticles-decorated reduced graphene oxide and their application for H2O2 detection. Electrochimica Acta, 79 46-51.
42. H. Wadhwa., D. Kumara., S. Mahendia., S. Kumar (2017) Microwave assisted facile synthesis of Reduced Graphene Oxide-Silver (RGO-Ag) Nanocomposite and their application as active SERS substrate. Materials Chemistry and Physics, 194 274-282.
43. Liu GF., Huang LJ., Wang YX., Tang JG., Wang Y., Cheng MM., Zhang Y., Kipper MJ., Belfiore LA., Ranilc WS (2017) Preparation of a graphene/silver hybrid membrane as a new nanofiltration membrane. RSC Adv., 7 (77) 49159–49165.
44. Sun XF., Qin J., Xia PF., Guo BB., Yang CM., Song C., Wang SG (2015) Graphene oxide–silver nanoparticle membrane for biofouling control and water purification. Chem. Eng. J., 281 53–59.
45. He D., Garg S., Waite TD (2012) H2O2-Mediated Oxidation of Zero-Valent Silver and Resultant Interactions among Silver Nanoparticles, Silver Ions, and Reactive Oxygen Species. Langmuir, 28 (27) 10266 – 10275.
46. Sang S., Li D., Zhang H., Sun Y., Jian A., Zhang Q., Zhang W (2017) Facile synthesis of AgNPs on reduced graphene oxide for highly sensitive simultaneous detection of heavy metal ions. RSC Adv., 7 (35) 21618-21624.
47. Han L., Liu CM., Dong SL., Du CX., Zhang XY., Li LH., Wei Y (2017) Enhanced conductivity of rGO/Ag NPs composites for electrochemical immunoassay of prostate- specific antigen. Biosensors and Bioelectronics, 87 466-472.
48. Kurowska TE., Gawlak K., Hnida K., Jaskuła M., Sulka GD (2016) Synthesis of porous thin silver films and their application for hydrogen peroxide sensing. Electrochimica Acta, 213 811–821.
49. Bas SZ (2015) Gold nanoparticle functionalized graphene oxide modified platinum electrode for hydrogen peroxide and glucose sensing. Mater. Lett., 150 20–23.
50. Tian J., Liu S., Sun X (2010) Supramolecular Microfibrils of o-Phenylenediamine Dimers: Oxidation-Induced Morphology Change and the Spontaneous Formation of Ag Nanoparticle Decorated Nanofibers. Langmuir, 26 (19) 15112–15116.
51. Maduraiveeran G., Kundu M., Sasidharan M (2018) Electrochemical detection of hydrogen peroxide based on silver nanoparticles via amplified electron transfer process. J. Mater. Sci., 53 (11) 8328–8338.
52. Tran HV., Le TA., Giang BL., Piro B., Tran LD (2019) Silver nanoparticles on graphene quantum dots as nanozyme for efficient H2O2 reduction in a glucose biosensor. Mater. Res. Express, 6 (11) 1-8.
53. Tran HV., Huynh CD., Tran HV., Piro B (2018) Cyclic voltammetry, square wave voltammetry, electrochemical impedance spectroscopy and colorimetric method for hydrogen peroxide detection based on chitosan/silver nanocomposite. Arabian J. Chemistry, 11 (4) 453-459.
54. Nguyen ND., Nguyen TV., Chu AD., Tran HV., Tran LT., Huynh CD (2018) A label-free colorimetric sensor based on silver nanoparticles directed to hydrogen peroxide and glucose. Arabian J. Chemistry, 11 (7) 1134-1143.
55. Sankarasubramanian K., Justice Babu K., Soundarrajan P., Logu T., Gnanakumar G., Ramamurthi K., Sethuraman K., Senthil Kumar SM (2019) A new catalyst Ti doped CdO thin film for non-enzymatic hydrogen peroxide sensor application. Sensors & Actuators: B. Chemical 285 164–172.
56. Gnana kumar G., Justice Babu K., Nahm KS., Hwang YJ (2014) A facile one-pot green synthesis of reduced graphene oxide and its composites for nonenzymatic hydrogen peroxide sensor applications. RSC Adv., 4 7944.
57. Ramachandran K., Zahoor A., Raj Kumar T., Nahm KS., Balasubramani A., Gnana Kumar G (2017) MnO2 nanorods grown NGNF nanocomposites for the application of highly sensitive and selective electrochemical detection of hydrogen peroxide. J. Industrial and Engineering Chem. 46, 19-27.
58. Vasuki K., Justice Babu K., Sheet S., Siva G., Kim AR., Yoo DJ., Kumar GG (2017) Amperometric hydrogen peroxide sensor based on the use of CoFe2O4 hollow nanostructures. Microchimica Acta 8, 2579-2586.
59. Karthikeyan C., Ramachandran K., Sheet S., Yoo DJ., Lee YS., Kumar YS., Kim AR., Kumar GG (2017) Pigeon-Excreta-Mediated Synthesis of Reduced Graphene Oxide (rGO)/CuFe2O4 Nanocomposite and Its Catalytic Activity toward Sensitive and Selective Hydrogen Peroxide Detection. ACS Sustainable Chem. Eng. 5, 4897−4905.