AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
PDF (4.1 MB)
Collect
Submit Manuscript AI Chat Paper
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Research Article | Open Access

Fabrication of N-Doped Graphene@TiO2 Nanocomposites for Its Adsorption and Absorbing Performance with Facile Recycling

Pravin Onkar Patil1( )Sopan Namdev Nangare1Pratiksha Pramod Patil1Ashwini Ghanashyam Patil2Dilip Ramsing Patil2Rahul Shankar Tade1Arun Madhukar Patil2Prashant Krishnarao Deshmukh3Sanjay Baburao Bari1
H.R. Patel Institute of Pharmaceutical Education and Research, Karvand Naka, Shirpur, Dist-Dhule, Maharashtra, 425405 India
R.C. Patel Arts, Science, and Commerce College, Shirpur, Maharashtra, 425405 India
Dr. Rajendra Gode College of Pharmacy, Malkapur, Dist-Buldhana, Maharashtra, 443101 India
Show Author Information

Abstract

The present work aims to synthesize nitrogen-doped reduced graphene oxide-titanium dioxide nanocomposite (N-rGO@TiO2) using a simple, eco-friendly method and its applications in spectroscopic detection of heavy metal ions such as lead (Pb2+), mercury (Hg2+), and chromium-VI [Cr(VI)] in potable water. Initially, TiO2 nanoparticles loaded N doped rGO sheets were fabricated by an ecological method using Gossypium hirsutum (cotton) seeds extract as a green reducing agent. Then, the N-rGO@TiO2 nanocomposites were subjected for characterizations such as spectroscopic techniques, particle size analysis, zeta potential analysis, and spectroscopic sensing. Notably, the results of this study confirmed that N-rGO@TiO2 exhibited countless stupendous features in terms of sensing of an analyte. Briefly, the UV-visible spectroscopy and Fourier transform infrared (FTIR) spectroscopy confirmed the successful synthesis of N-rGO@TiO2. The SEM images showed the wrinkled, folded, and cross-linked network structures that confirmed the surface modification and nitrogen doping in the rGO sheet and synthesis of N-rGO@TiO2. The EDAX study confirmed the elemental composition of the N-rGO@TiO2 nanocomposite. Finally, due to the larger surface area, porous nature, high electron mobility, etc. the N-rGO@TiO2 probe provides the lower detection limit for Pb2+, Hg2+, and Cr (VI) as low as 50 nM, 15 μM, and 25 nM, respectively. Concisely, our study affirms the admirable sensitivity of N-rGO@TiO2 nanocomposite to the Pb2+, Hg2+, and Cr (VI) in potable water can provide better environmental remediation.

References

[1]

A.K. Geim, K.S. Novoselov, The rise of graphene. Nature Materials, 2007, 6: 183-191.

[2]

Y. Kopelevich, P. Esquinazi, Graphene physics in graphite, Advanced Materials, 2007, 19: 4559-4563.

[3]

R. Tade, S.N. Nangare, and P.O. Patil, Fundamental aspects of graphene and its biosensing applications. Functional Composites and Structures, 2021, 3: 012001.

[4]

X. Li, X. Wang, L. Zhang, et al., Chemically derived, ultrasmooth graphene nanoribbon semiconductors. Science, 2008, 319: 1229-1232.

[5]

C. Stampfer, E. Schurtenberger, F. Molitor, et. al., Tunable graphene single electron transistor. Nano Letters, 2008, 8: 2378-2383.

[6]

D.A. Dikin, S. Stankovich, E.J. Zimney, et al., Preparation and characterization of graphene oxide paper. Nature, 2007, 448: 457-460.

[7]

Y. Xu, K. Sheng, C. Li, et al., Self-assembled graphene hydrogel via a one-step hydrothermal process. ACS Nano, 2010, 4: 4324-4330.

[8]

H. Bai, K. Sheng, P. Zhang, et al., Graphene oxide/conducting polymer composite hydrogels. Journal of Materials Chemistry, 2011, 21: 18653-18658.

[9]

Y. Xie, S. Xu, Z. Xu, et al., Interface-mediated extremely low thermal conductivity of graphene aerogel. Carbon, 2016, 98: 381-390.

[10]

L. Xu, G. Xiao, C. Chen, et al., Superhydrophobic and superoleophilic graphene aerogel prepared by facile chemical reduction. Journal of Materials Chemistry A, 2015, 3: 7498-7504.

[11]

M.A. Worsley, P.J. Pauzauskie, T.Y. Olson, et al., Synthesis of graphene aerogel with high electrical conductivity. Journal of the American Chemical Society, 2010, 132: 14067-14069.

[12]

J.L. Vickery, A.J. Patil, and S. Mann, fabrication of graphene-polymer nanocomposites with higher-order three-dimensional architectures. Advanced Materials, 2009, 21: 2180-2184.

[13]

W. Gao, L.B. Alemany, L. Ci, et al., New insights into the structure and reduction of graphite oxide. Nature chemistry, 2009, 1: 403-408.

[14]

J. Liu, H. Bai, Y. Wang, et al., Self-assembling TiO2 nanorods on large graphene oxide sheets at a two-phase interface and their anti-recombination in photocatalytic applications. Advanced Functional Materials, 2010, 20: 4175-4181.

[15]

E. Gao, W. Wang, M. Shang, et al., Synthesis and enhanced photocatalytic performance of graphene-Bi2WO6 composite. Physical Chemistry Chemical Physics, 2011, 13: 2887-2893.

[16]

Y.H. Ng, A. Iwase, A. Kudo, et al., Reducing graphene oxide on a visible-light BiVO4 photocatalyst for an enhanced photoelectrochemical water splitting. The Journal of Physical Chemistry Letters, 2010, 1: 2607-2612.

[17]

T. Ramanathan, A. Abdala, S. Stankovich, et al., Functionalized graphene sheets for polymer nanocomposites. Nature Nanotechnology, 2008, 3: 327-331.

[18]

T. Szabó, O. Berkesi, P. Forgó, et al., Evolution of surface functional groups in a series of progressively oxidized graphite oxides. Chemistry of Materials, 2006, 18: 2740-2749.

[19]

X. Li, H. Wang, J.T. Robinson, et al., Simultaneous nitrogen doping and reduction of graphene oxide. Journal of the American Chemical Society, 2009, 131: 15939-15944.

[20]

F. Kim, L.J. Cote, and J. Huang, Graphene oxide: Surface activity and two-dimensional assembly. Advanced Materials, 2010, 22: 1954-1958.

[21]

K.A. Mkhoyan, A.W. Contryman, J. Silcox, et al., Atomic and electronic structure of graphene-oxide. Nano letters, 2009, 9: 1058-1063.

[22]

M. Agharkar, S. Kochrekar, S. Hidouri, et al., Trends in green reduction of graphene oxides, issues and challenges: A review. Materials Research Bulletin, 2014, 59: 323-328.

[23]

S. Thakur, N. Karak, Alternative methods and nature-based reagents for the reduction of graphene oxide: A review. Carbon, 2015, 94: 224-242.

[24]

J. Gao, F. Liu, Y. Liu, et al., Environment-friendly method to produce graphene that employs vitamin C and amino acid. Chemistry of Materials, 2010, 22: 2213-2218.

[25]

Y. Wang, Z. Shi, and J. Yin, Facile synthesis of soluble graphene via a green reduction of graphene oxide in tea solution and its biocomposites. ACS Applied Materials & Interfaces, 2011, 3: 1127-1133.

[26]

C. Zhu, S. Guo, Y. Fang, et al.,, Reducing sugar: new functional molecules for the green synthesis of graphene nanosheets, ACS Nano, 2010, 4: 2429-2437.

[27]

P. Zhang, T. Tachikawa, M. Fujitsuka, et al., Efficient charge separation on 3D architectures of TiO2 mesocrystals packed with a chemically exfoliated MoS2 shell in synergetic hydrogen evolution. Chemical Communications, 2015, 51: 7187-7190.

[28]

Y. Agrawal, G. Kedawat, P. Kumar, et al., High-performance stable field emission with ultralow turn on voltage from rGO conformal coated TiO2 nanotubes 3D arrays. Scientific Reports, 2015, 5: 11612.

[29]

A.L. Linsebigler, G. Lu, and J.T. Yates Jr, Photocatalysis on TiO2 surfaces: principles, mechanisms, and selected results. Chemical Reviews, 1995, 95: 735-758.

[30]

W. Han, C. Zang, Z. Huang, et al., Enhanced photocatalytic activities of three-dimensional graphene-based aerogel embedding TiO2 nanoparticles and loading MoS2 nanosheets as Co-catalyst. International Journal of Hydrogen Energy, 2014, 39: 19502-19512.

[31]

F. Wu, W. Liu, J. Qiu, et al., Enhanced photocatalytic degradation and adsorption of methylene blue via TiO2 nanocrystals supported on graphene-like bamboo charcoal. Applied Surface Science, 2015, 358: 425-435.

[32]

L.L. Tan, W.J. Ong, S.P. Chai, et al., Visible-light-active oxygen-rich TiO2 decorated 2D graphene oxide with enhanced photocatalytic activity toward carbon dioxide reduction. Applied Catalysis B: Environmental, 2015, 179: 160-170.

[33]

W. Yan, F. He, S. Gai, et al., A novel 3D structured reduced graphene oxide/TiO2 composite: Synthesis and photocatalytic performance. Journal of Materials Chemistry A, 2014, 2: 3605-3612.

[34]

W. Wang, J. Yu, Q. Xiang, et al., Enhanced photocatalytic activity of hierarchical macro/mesoporous TiO2-graphene composites for photodegradation of acetone in air. Applied Catalysis b: Environmental, 2012, 119: 109-116.

[35]

M. Aleksandrzak, P. Adamski, W. Kukułka, et al., Effect of graphene thickness on photocatalytic activity of TiO2-graphene nanocomposites. Applied Surface Science, 2015, 331: 193-199.

[36]

K. Fujisawa, R. Cruz-Silva, K.S. Yang, et al., Importance of open, heteroatom-decorated edges in chemically doped-graphene for supercapacitor applications. Journal of Materials Chemistry A, 2014, 2: 9532-9540.

[37]

M. Khandelwal, A. Kumar, One-pot environmentally friendly amino acid mediated synthesis of N-doped graphene–silver nanocomposites with an enhanced multifunctional behavior. Dalton Transactions, 2016, 45: 5180-5195.

[38]

K. Gong, F. Du, Z. Xia, et al., Nitrogen-doped carbon nanotube arrays with high electrocatalytic activity for oxygen reduction., Science, 2009, 323: 760-764.

[39]

K.A. Kurak, A.B. Anderson, Nitrogen-treated graphite and oxygen electroreduction on pyridinic edge sites. The Journal of Physical Chemistry C, 2009, 113: 6730-6734.

[40]

P.H. Matter, E. Wang, M. Arias, et al., Oxygen reduction reaction catalysts prepared from acetonitrile pyrolysis over alumina-supported metal particles. The Journal of Physical Chemistry B, 2006, 110: 18374-18384.

[41]

P.H. Matter, L. Zhang, and U.S. Ozkan, The role of nanostructure in nitrogen-containing carbon catalysts for the oxygen reduction reaction. Journal of Catalysis, 2006, 239: 83-96.

[42]

T. Iijima, K. Suzuki, Y. Matsuda, Electrodic characteristics of various carbon materials for lithium rechargeable batteries. Synthetic Metals, 1995, 73: 9-20.

[43]

Y. Wu, S. Fang, and Y. Jiang, Carbon anode materials based on melamine resin. Journal of Materials Chemistry, 1998, 8: 2223-2227.

[44]

F. Jaouen, M. Lefèvre, J.P. Dodelet, et al., Heat-treated Fe/N/C catalysts for O2 electroreduction: Are active sites hosted in micropores? The Journal of Physical Chemistry B, 2006, 110: 5553-5558.

[45]

S. Lim, H. Elim, X. Gao, et al., Electronic and optical properties of nitrogen-doped multiwalled carbon nanotubes. Physical Review B, 2006, 73: 045402.

[46]

S. Glenis, A. Nelson, and M. Labes, Formation of nitrogen doped carbon during arc-discharge of carbon rods in the presence of pyrrole. Journal of Applied Physics, 1996, 80: 5404-5407.

[47]

S. Lim, H. Elim, X. Gao, et al., Electronic and optical properties of nitrogen-doped multiwalled carbon nanotubes. Physical Review B (Covering condensed matter and material physics), 2006, 73: 045402.

[48]

L. Li, E. Liu, Y. Yang, et al., Nitrogen-containing carbons prepared from polyaniline as anode materials for lithium secondary batteries. Materials Letters, 2010, 64: 2115-2117.

[49]

W.S. Hummers Jr, R.E. Offeman, Preparation of graphitic oxide. Journal of the American Chemical Society, 1958, 80: 1339-1339.

[50]

Y. Wu, S. Fang, and Y. Jiang, Effects of nitrogen on the carbon anode of a lithium secondary battery. Solid State Ionics, 1999, 120: 117-123.

[51]

A.M. Massadeh, A.W.O. El-Rjoob, and S.A. Gharaibeh, Analysis of selected heavy metals in tap water by inductively coupled plasma-optical emission spectrometry after pre-concentration using chelex-100 ion exchange resin. Water, Air, & Soil Pollution, 2020, 231: 1-14.

[52]

A. Mahar, P. Wang, A. Ali, et al., Challenges and opportunities in the phytoremediation of heavy metals contaminated soils: A review. Ecotoxicology and Environmental Safety, 2016, 126: 111-121.

[53]

R. Karkra, P. Kumar, B.K. Bansod, et al., Analysis of heavy metal ions in potable water using soft computing technique. Procedia Computer Science, 2016, 93: 988-994.

[54]

M.B. Gumpu, S. Sethuraman, U.M. Krishnan, et al., A review on detection of heavy metal ions in water–an electrochemical approach. Sensors and Actuators B: Chemical, 2015, 213: 515-533.

[55]
A. Odobašić, I. Šestan, and S. Begić, Biosensors for determination of heavy metals in waters. Biosensors for Environmental Monitoring, Intech Open, 2019.
[56]

N. Zaaba, K. Foo, U. Hashim, et al., Synthesis of graphene oxide using modified hummers method: Solvent influence. Procedia Engineering, 2017, 184: 469-477.

[57]

R. Chandrashekhar, B. Ram, and N.L. Bhavani, Quantitative analysis of phytochemical compounds in the cotton (Gossypium) seed xetracts; an important iommercial crop plant. Bulletin of Pure & Applied Sciences-Botany, 2019, 38: 56-62.

[58]

J.H. Patil, M.P. More, M.R. Mahajan, et al., Green synthesis of graphene based manocomposite for sensing of heavy metals. Journal of Pharmaceutical and Biological Sciences, 2019, 7: 56-62.

[59]

J. Liu, K.Y. Chen, J. Wang, et al., Preparation and photocatalytic properties of N-doped graphene/TiO2 composites. Journal of Chemistry, 2020, 2020: 2928189.

[60]
S.R.B. Nazri, W.W. Liu, C.S. Khe, et al., Synthesis, characterization and study of graphene oxide. AIP Conference Proceedings, AIP Publishing LLC, Dec. 6, 2018, 2045: 020033.
[61]

S. Ida, P. Wilson, B. Neppolian, et al., Tuning the type of nitrogen on N-RGO supported on N-TiO2 under ultrasonication/hydrothermal treatment for efficient hydrogen evolution–A mechanistic overview. Ultrasonics Sonochemistry, 2020, 64: 104866.

[62]

Y. Li, J. Yang, S. Zheng, et al., One-pot synthesis of 3D TiO2-reduced graphene oxide aerogels with superior adsorption capacity and enhanced visible-light photocatalytic performance. Ceramics International, 2016, 42: 19091-19096.

[63]

X. Shi, J. Chen, and W. Wang, Effects of TiO2 content on the microstructure, mechanical properties and photocatalytic activity of three dimensional TiO2-Graphene composite prepared by hydrothermal reaction. Materials Research Express, 2016, 3: 075602.

[64]

N.N. Malinga, A.L. Jarvis, Synthesis, characterization and magnetic properties of Ni, Co and FeCo nanoparticles on reduced graphene oxide for removal of Cr (VI). Journal of Nanostructure in Chemistry, 2020, 10: 55-68.

Nano Biomedicine and Engineering
Pages 179-190
Cite this article:
Patil PO, Nangare SN, Patil PP, et al. Fabrication of N-Doped Graphene@TiO2 Nanocomposites for Its Adsorption and Absorbing Performance with Facile Recycling. Nano Biomedicine and Engineering, 2021, 13(2): 179-190. https://doi.org/10.5101/nbe.v13i2.p179-190

914

Views

70

Downloads

3

Crossref

4

Scopus

Altmetrics

Received: 11 December 2020
Accepted: 29 March 2021
Published: 26 May 2021
© Pravin Onkar Patil, Sopan Namdev Nangare, Pratiksha Pramod Patil, Ashwini Ghanashyam Patil, Dilip Ramsing Patil, Rahul Shankar Tade, Arun Madhukar Patil, Prashant Krishnarao Deshmukh, and Sanjay Baburao Bari.

This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Return