Academia.eduAcademia.edu

Outline

Title
Abstract
Introduction
Experimental Methods
Results and Discussion
Electrochemical Results
Voltammetric Results
Chronoamperometric Results
Chronopotentiometric Results
Conclusions
References
All Topics
Engineering

Graphene electrochemical responses sense surroundings

Profile image of Toribio Fernández OteroToribio Fernández Otero

2012, Electrochimica Acta

https://doi.org/10.1016/J.ELECTACTA.2012.07.037
visibility

description

9 pages

link

1 file

Abstract

Graphite oxide (GO) paper, obtained by direct filtration of exfoliated GO in water over PTFE membrane filters, was reduced by using hydrazine vapours. The graphene-paper thus obtained was characterized by the combination of different techniques. The electrochemical characterization by cyclic voltammetry, chronoamperometry and chronopotentiometry presents a strong influence of the working conditions: temperature, electrolyte concentration and current on the electrochemical responses, indicating a good ability of the material to sense ambient and working conditions. Electrochemical devices based on graphene are expected to work as dual, and simultaneous, sensing-actuators.

Related papers

Graphene Oxide and Its Electrochemical Performance
Siti Rohana Majid

2012

In this study, graphene oxide (GO) was synthesized from graphite flakes using simplified Hummer's method. Field Emission Scanning Electron Microscopy (FESEM) image showed that the GO nanosheets had an average area 7000 mu m(2) with lateral dimension of up to 150 mu m. The X-Ray Diffraction (XRD) pattern revealed a (002) diffraction peak, signifying the successful synthesis of GO. GO solution was cast on an aluminum (Al) foil placed in a petri dish and left to dry to form an electrode made up of GO film on the Al foil (GO-Al). It was found that GO-Al exhibited equivalent series resistance (ESR) close to that of the Al foil.

View PDFchevron_right
The electrochemical performance of graphene modified electrodes: An analytical perspective
Dale Brownson, Christopher Foster

The Analyst, 2012

We explore the use of graphene modified electrodes towards the electroanalytical sensing of various analytes, namely dopamine hydrochloride, uric acid, acetaminophen and p-benzoquinone via cyclic voltammetry. In line with literature methodologies and to investigate the full-implications of employing graphene in this electrochemical context, we modify electrode substrates that exhibit either fast or slow electron transfer kinetics (edge-or basal-plane pyrolytic graphite electrodes respectively) with well characterised commercially available graphene that has not been chemically treated, is free from surfactants and as a result of its fabrication has an extremely low oxygen content, allowing the true electroanalytical applicability of graphene to be properly de-convoluted and determined. In comparison to the unmodified underlying electrode substrates (constructed from graphite), we find that graphene exhibits a reduced analytical performance in terms of sensitivity, linearity and observed detection limits towards each of the various analytes studied within. Owing to graphene's structural composition, low proportion of edge plane sites and consequent slow heterogeneous electron transfer rates, there appears to be no advantages, for the analytes studied here, of employing graphene in this electroanalytical context.

View PDFchevron_right
Graphene electrochemistry: an overview of potential applications
Dale Brownson

The Analyst, 2010

Graphene, a 2D nanomaterial that possesses spectacular physical, chemical and thermal properties, has caused immense excitement amongst scientists since its freestanding form was isolated in 2004. With research into graphene rife, it promises enhancements and vast applicability within many industrial aspects. Furthermore, graphene possesses a vast array of unique and highly desirable electrochemical properties, and it is this application that offers the most enthralling and spectacular journey. We present a review of the current literature concerning the electrochemical applications and advancements of graphene, starting with its use as a sensor substrate through to applications in energy production and storage, depicting the truly remarkable journey of a material that has just come of age.

View PDFchevron_right
Ferrocene-functionalized graphene electrode for biosensing applications
Noureddine Raouafi
View PDFchevron_right
Cyanographene and Graphene Acid: The Functional Group of Graphene Derivative Determines the Application in Electrochemical Sensing and Capacitors
Eduardo Nunes Jacondino Jacondino

ChemElectroChem, 2018

Well-defined, stoichiometric derivatives of graphene afford many opportunities in fine-tuning of graphene properties and hence, extend the application potential of this material. Here, we present the electrochemical properties of cyanographene (GÀCN), and graphene acid (GÀCOOH) in order to understand the role of the covalently attached functional groups on the graphene sheet in electrochemical sensing for the detection of biomarkers. GÀCN shows better performance for the negatively charged analytes ascorbic and uric acids when compared to GÀCOOH. The less-favourable performance of GÀCOOH is explained by repulsion between negatively charged analytes and negatively charged functional groups of GÀCOOH. The capacitance of both materials is in a comparable range, but chronopotentiometry reveals that GÀCN shows a greater capacitance than GÀCOOH. The identified differences in electrochemical properties imprinted by the functional group show that its chemical nature can be exploited in fine-tuning of the selectivity of electrochemical sensing and energy storage applications.

View PDFchevron_right
Progress in the electrochemical modification of graphene-based materials and their applications
Muhammad Irfan

Electrochimica Acta, 2013

Graphene is a 2D allotrope of carbon with exciting properties such as extremely high electronic conductivity and superior mechanical strength. It has considerable potential for applications in fields such as bio-sensors, electrochemical energy storage and electronics. In most cases, graphene has been functionalized and modified with other materials to prepare composites. This work reviews the electrochemical modification of graphene. Commencing with a brief history, a summary of several different means of modifying graphene to effect diverse applications is provided. This is followed by a discussion on different composite materials that have been prepared with reduced graphene oxide prior to moving onto a detailed consideration of six different methods of electrochemically modifying graphene to prepare composite materials. These methods involve cathodic reduction of graphene oxide, electrophoretic deposition, electro-deposition techniques, electrospinning, electrochemical doping and electrochemical polymerization. Finally a consideration on the applications of electrochemically modified graphene composite materials in various fields is presented prior to discussing some prospects in enhancing the electrochemical process to realize excellent and economic composite materials in bulk.

View PDFchevron_right
An Electrochemical Route to Graphene Oxide
James Pak

Journal of Nanoscience and Nanotechnology, 2011

Large-scale graphene oxide (GO) with adjustable resistivity was synthesized from graphite via an electrochemical method using KCl solution as an effective electrolyte. During the exfoliation process, electrostatic force intercalates chloride ions between the expanded graphite layers on the anode. These chloride ions form small gas bubbles between the graphite layers in the electrochemical reaction. It is believed that the gas bubbles expand the gap between graphite sheets and produce a separating force between adjacent graphene layers. This separating force overcomes the Van der Waals force between adjacent sheets and exfoliates graphene layers from the starting graphite. Because the graphene is electrochemically oxidized by chorine during the exfoliation, the exfoliated GO sheets are hydrophilic and easily dispersed in the electrolyte solution. The GO solution prepared by the electrochemical exfoliation can be simply sprayed or spin-coated onto any substrate for device applications. The measured average thicknesses of a monolayer, bilayer, and trilayer exfoliated GO on SiO 2 substrate were 1.9, 2.8, and 3.9 nm, respectively. It was observed that the measured resistance of the exfoliated GO sheets increases due to electrochemical oxidation in the solution. This electrochemical approach offers a low-cost and efficient route to the fabrication of graphene based devices.

View PDFchevron_right
Electrochemical monitoring of biointeraction by graphene-based material modified pencil graphite electrode
Arzum Erdem

Biosensors & bioelectronics, 2017

Recently, the low-cost effective biosensing systems based on advanced nanomaterials have received a key attention for development of novel assays for rapid and sequence-specific nucleic acid detection. The electrochemical biosensor based on reduced graphene oxide (rGO) modified disposable pencil graphite electrodes (PGEs) were developed herein for electrochemical monitoring of DNA, and also for monitoring of biointeraction occurred between anticancer drug, Daunorubicin (DNR), and DNA. First, rGO was synthesized chemically and characterized by using UV-Vis, TGA, FT-IR, Raman Spectroscopy and SEM techniques. Then, the quantity of rGO assembling onto the surface of PGE by passive adsorption was optimized. The electrochemical behavior of rGO-PGEs was examined by cyclic voltammetry (CV). rGO-PGEs were then utilized for electrochemical monitoring of surface-confined interaction between DNR and DNA using differential pulse voltammetry (DPV) technique. Additionally, voltammetric results wer...

View PDFchevron_right
Electrochemically Exfoliated Graphene for Nanosensor Applications
senthilkumar elumalai

Journal of Nanoscience and Nanotechnology, 2018

Water dispersible graphene layer are the excellent nano materials used for wide range of electronic applications. High quality graphene was synthesized by an eco-friendly, easy and cost effective electrochemical exfoliation method. In this work, graphite rod was used both as an anode and cathode for the production of graphene. Potassium sulphate (K 2 SO 4) was used as an intercalating agent. Electrochemically exfoliated graphene (EEG) was coated on glassy carbon electrode (GCE) and evaluated towards the electrochemical oxidation of vanillin and L-phenylalanine. The fabricated electrode was able to detect vanillin and L-Phenylalanine as low as 0.2 M with signal to noise ratio of 3. A significant increase in the current was observed for the graphene coated electrode for both vanillin and L-phenylalanine when compared to bare Glassy electrode. The finding clearly demonstrated the higher detection capability, selectivity and reproducibility of EEG.

View PDFchevron_right
Written‐in Conductive Patterns on Robust Graphene Oxide Biopaper by Electrochemical Microstamping
satish kumar
View PDFchevron_right

References (43)

  1. U. Yogeswaran, S.M. Chen, Sensors 8 (2008) 290.
  2. X. Zhang, H. Ju, J. Wang, Electrochemical Sensors, Biosensors and their Biomed- ical Applications, Academic Press, London, 2008.
  3. A.K. Geim, K.S. Novoselov, Nature Materials 6 (2007) 183.
  4. C. Lee, X. Wei, J.W. Kysar, J. Hone, Science 321 (2008) 385.
  5. G. Eda, M. Chhowalla, Advanced Materials 22 (2010) 2392.
  6. D.A. Brownson, C.E. Banks, Analyst 135 (2010) 2768.
  7. T. Gan, S. Hu, Microchimica Acta 175 (2011) 1.
  8. T. Kuila, S. Bose, P. Khanra, A.K. Mishra, N.H. Kim, J.H. Lee, Biosensors and Bioelectronics 26 (2011) 4637.
  9. M. Noked, A. Soffer, D. Aurbach, Journal of Solid State Electrochemistry 15 (2011) 1563.
  10. M. Pumera, Chemical Record 12 (2012) 201.
  11. K.S. Novoselov, A.K. Geim, S.V. Morozov, D. Jiang, Y. Zhang, S.V. Dubonos, I.V. Grigorieva, A.A. Firsov, Science 306 (2004) 666.
  12. D.R. Dreyer, S. Park, C.W. Bielawski, R.S. Ruoff, Chemical Society Reviews 39 (2010) 228.
  13. Y. Hernandez, V. Nicolosi, M. Lotya, F.M. Blighe, Z. Sun, S. De, I. McGovern, B. Holland, M. Byrne, Y.K. Gun'ko, J.J. Boland, P. Niraj, G. Duesberg, S. Krishna- murthy, R. Goodhue, J. Hutchison, V. Scardaci, A.C. Ferrari, J.N. Coleman, Nature Nanotechnology 3 (2008) 563.
  14. S. Park, R.S. Ruoff, Nature Nanotechnology 4 (2009) 217.
  15. W.S. Hummers, R.E. Offeman, Journal of the American Chemical Society 80 (1958) 1339.
  16. I.K. Moon, J. Lee, H. Lee, Chemical Communications 47 (2011) 9681.
  17. H.J. Shin, K.K. Kim, A. Benayad, S.M. Yoon, H.K. Park, I.S. Jung, M.H. Jin, H.K. Jeong, J.M. Kim, J.Y. Choi, Y.H. Lee, Advanced Functional Materials 19 (2009) 1987.
  18. S. Stankovich, D.A. Dikin, R.D. Piner, K.A. Kohlhaas, A. Kleinhammes, Y. Jia, Y. Wu, S.T. Nguyen, R.S. Ruoff, Carbon 45 (2007) 1558.
  19. Y. Zhou, Q. Bao, L.A.L. Tang, Y. Zhong, K.P. Loh, Chemistry of Materials 21 (2009) 2950.
  20. F. Yavari, C. Kritzinger, C. Gaire, L. Song, H. Gullapalli, T. Borca-Tasciuc, P.M. Ajayan, N. Koratkar, Small 6 (2010) 2535.
  21. P. Gimenez, K. Mukai, K. Asaka, K. Hata, H. Oike, T. Otero, Electrochimica Acta 60 (2012) 177.
  22. Y. Huang, J. Liang, Y. Chen, Journal of Materials Chemistry 22 (2012) 3671.
  23. K. Mukai, K. Asaka, K. Hata, T. Fernandez Otero, H. Oike, Chemistry -A European Journal 17 (2011) 10965.
  24. T.F. Otero, J.G. Martinez, J. Arias-Pardilla, Electrochimica Acta (2012), doi:10.1016/j.electacta.2012.03.097.
  25. J.G. Martínez, T. Sugino, K. Asaka, T.F. Otero, ChemPhysChem 13 (2012) 2108.
  26. G.W. Rogers, J.Z. Liu, Journal of the American Chemical Society 133 (2011) 10858.
  27. X. Du, P. Guo, H. Song, X. Chen, Electrochimica Acta 55 (2010) 4812.
  28. Y. Zhai, Y. Dou, D. Zhao, P.F. Fulvio, R.T. Mayes, S. Dai, Advanced Materials 23 (2011) 4828.
  29. Y. Zhang, H. Li, L. Pan, T. Lu, Z. Sun, Journal of Electroanalytical Chemistry 634 (2009) 68.
  30. D. Yang, A. Velamakanni, G. Bozoklu, S. Park, M. Stoller, R.D. Piner, S. Stankovich, I. Jung, D.A. Field, C.A. Ventrice, R.S. Ruoff, Carbon 47 (2009) 145.
  31. J.I. Paredes, S. Villar-Rodil, P. Solis-Fernandez, A. Martinez-Alonso, J. Tascon, Langmuir 25 (2009) 5957.
  32. I.K. Moon, J. Lee, R.S. Ruoff, H. Lee, Nature Communications 1 (2010).
  33. E. Grodzka, P. Pieta, P. Dluzewski, W. Kutner, K. Winkler, Electrochimica Acta 54 (2009) 5621.
  34. H.W. Wang, Z.A. Hu, Y.Q. Chang, Y.L. Chen, Z.Q. Lei, Z.Y. Zhang, Y.Y. Yang, Elec- trochimica Acta 55 (2010) 8974.
  35. D.A.C. Brownson, D.K. Kampouris, C.E. Banks, Journal of Power Sources 196 (2011) 4873.
  36. T. Lu, Y. Zhang, H. Li, L. Pan, Y. Li, Z. Sun, Electrochimica Acta 55 (2010) 4170.
  37. D.A.C. Brownson, C.E. Banks, Chemical Communications 48 (2012) 1425.
  38. J. Liang, Y. Huang, J. Oh, M. Kozlov, D. Sui, S. Fang, R.H. Baughman, Y. Ma, Y. Chen, Advanced Functional Materials 21 (2011) 3778.
  39. T.F. Otero, J.M. Garcia de Otazo, Synthetic Metals 159 (2009) 681.
  40. B. West, T.F. Otero, B. Shapiro, E. Smela, Journal of Physical Chemistry B 113 (2009) 1277.
  41. T.F. Otero, M.T. Cortes, Advanced Materials 15 (2003) 279.
  42. T.F. Otero, Journal of Materials Chemistry 19 (2009) 681.
  43. L. Valero Conzuelo, J. Arias-Pardilla, J.V. Cauich-Rodriguez, M. Afra Smit, T.F. Otero, Sensors 10 (2010) 2638.

Related papers

Synthesis and utilisation of graphene for fabrication of electrochemical sensors
Abdulazeez lawal

Talanta, 2015

This review summarises the most recent contributions in the fabrication of graphene based electrochemical biosensors in recent years. It discusses the synthesis and application of graphene to the fabrication of graphene-based electrochemical sensors, its analytical performance and future prospects. An increasing number of reviews and publications involving graphene sensors have been reported ever since the first design of graphene electrochemical biosensor. The large surface area and good electrical conductivity of graphene allow it to act as an "electron wire" between the redox centers of an enzyme or protein and an electrode's surface, which make it a very excellent material for the design of electrochemical biosensors. Graphene promotes the different rapid electron transfers that facilitate accurate and selective detection of cytochrome-c, β-nicotinamide adenine dinucleotide, haemoglobin, biomolecules such as glucose, cholesterol, ascorbic acid, uric acid, dopamine and hydrogen peroxide .

View PDFchevron_right
Synthesizing Graphene Oxide as a Working Electrode for Decreasing pH with Alkaline Water Electrolysis
Aldwin Amireza

International Journal of Chemical Sciences, 2018

Graphene oxide (GO) is a new form of synthesized graphite. GO is an oxidized multilayer because chemical reaction that involved using oxidizing agent, potassium permanganate [1]. The difference between graphite and graphene oxide shown by layer structure that formed, thereby graphite is a hexagonal monolayer carbon with sp2 hybridization. Graphene is defined by the International Union for Pure and Applied Chemistry (IUPAC) as "a single carbon layer of graphite structure, describing its nature by analogy to a polycyclic aromatic hydrocarbon of quasi-infinite size". Producing graphite to graphene oxide has been done with involving chemical synthesizing, where the reaction by adding some acidic using Hummer method. This oxidation process which happened to graphite that has been added oxidizing agent then sonicated so its formed exfoliated and producing a few layers called graphene oxide (GO). One of the advantages of GO is its easy dispersability in water and other organic solvents, as well as in different matrixes. This is due to the presence of the oxygen functionality groups. This remains a very important property in mixing the material with ceramic or polymer matrixes

View PDFchevron_right
Graphene oxide for electrochemical sensing applications
Susanta Roy

Journal of Materials Chemistry, 2011

By exploiting the presence of abundant carboxylic groups (-COOH) on graphene oxide (GO) and using EDC-NHS (1-ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride-N-hydroxysuccinimide) chemistry to covalently conjugate protein molecules, we demonstrate a novel electrochemical immunosensor for detection of antibody-antigen (Rabbit IgG-AntiRabbit IgG) interactions. The interactions were verified using Electrochemical Impedance Spectroscopy (EIS). Although GO is known to be a poor conductor, the charge transfer resistance (R P ) of a GO modified glassy carbon electrode (GCE) was found to be as low as 1.26 U cm 2 . This value is similar to that obtained for reduced graphene oxide (RGO) or graphene and an order of magnitude less than bare GCE. The EIS monitored antibody-antigen interactions showed a linear increase in R P and the overall impedance of the system with increase of antibody concentration. Rabbit IgG antibodies were detected over a wide range of concentrations from 3.3 nM to 683 nM with the limit of detection (LOD) estimated to be 0.67 nM. The sensor showed high selectivity towards Rabbit IgG antibody as compared to non-complementary myoglobin. RGO modified GCE showed no sensing properties due to the removal of carboxylic groups which prevented subsequent chemical functionalization and immobilization of antigen molecules. The sensitivity and selectivity achievable by this simple label free technique hint at the possibility of GO becoming the electrode material of choice for future electrochemical sensing protocols.

View PDFchevron_right
Bio-inspired AgNPs, multilayers-reduced graphene oxide and graphite nanocomposite for electrochemical $$\hbox {H}_{2}{\hbox {O}}_{2}$$H2O2 sensing
Snigdha Saha

Bulletin of Materials Science

A bio-mediated route for the synthesis of silver nanoparticles (AgNPs) is an area of interest in research of many scientists, and this work aims to study the electrocatalytic activity of these particles during electrochemical sensing of H 2 O 2 in a phosphate buffer media. The composite electrodes were fabricated using nearly spherical AgNPs and reduced graphene oxide (rGO) with the graphite (99.999% purity) support made of graphite paste. Graphene oxide (GO) was first synthesized using the modified Hummers method followed by rGO synthesis by chemical reduction of GO. rGO is consisting of about nine layers of rGO sheets of a wrinkled surface morphology with an intensity ratio of D to G band (I D /I G) of 1.17 and an interplanar d-spacing of 0.36 nm as evidenced by HRTEM micrograph. There was about 10 times increase in the cell current with the AgNPs-impregnated composite-electrode compared to without AgNPs impregnation, and an overpotential of H 2 O 2 reduction was found to be −1.373 V with a detection limit of 19.04 μM and 95.3% electrode stability with the graphite-rGO-AgNPs composite electrode. A nafion membrane cast on the rGO-AgNPs prevented the leakage of this composite from the electrode surface. The interference of various electroactive compounds on the amperometric response of the graphite-rGO-AgNPs electrode was also investigated.

View PDFchevron_right
Synergic Exfoliation of Graphene with Organic Molecules and Inorganic Ions for the Electrochemical Production of Flexible Electrodes
Giuliano Giambastiani

Chempluschem, 2014

View PDFchevron_right

Related topics

  • Engineering
    • 580 California St., Suite 400
    San Francisco, CA, 94104
    © 2025 Academia. All rights reserved