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Graphene/Multi-Walled Carbon Nanotubes Hybrid Materials for Supercapacitors

  • Lee, Bo-Reum (Department of Chemical Systematic Engineering, Catholic University of Daegu) ;
  • Chang, Dong Wook (Department of Industrial Chemistry, Pukyong National University)
  • Received : 2015.02.04
  • Accepted : 2015.02.13
  • Published : 2015.03.31

Abstract

We have developed a versatile method for the preparation of chemically linked graphene/multi-walled carbon nanotubes (MWNTs) hybrid materials via simple acid-catalyzed dehydration reaction between graphene oxide (GO) and amine-functionalized MWNTs (af-MWNTs). In this condition, ketone (-C=O) groups in GO and primary amine (-NH2) moieties in af-MWNTs readily react to form imine (-C=N-) linkage. The chemical structures of graphene/MWNTs hybrid materials have been investigated using various microscopic and spectroscopic measurements. As a result of the synergetic effects of hybrid materials such as improved surface area and the superior structural restoration of graphitic networks, the hybrid materials demonstrate improved capacitance with excellent long-term stability. Furthermore, controlled experiments were conducted to optimize the weight ratio of graphene/MWNTs in hybrid materials. The highest capacitance of 132.4 F/g was obtained from the GM7.5 material, in which the weight ratio between graphene and MWNTs was adjusted to 7.5/1, in 1M KOH electrolyte at a scan rate of 100 mV/s.

본 연구에서는 그래핀과 다중벽 탄소나노튜브를 포함하는 하이브리드 소재의 제조 및 슈퍼캐패시터 전극물질로의 활용에 관한 내용이 진행되었다. 이를 위하여 산화그래핀과 아민(-NH2) 그룹이 치환된 다중벽 탄소나노튜브를 산 촉매 하에서 반응시켜, 새로운 이민(-C=N-) 결합이 도입된 하이브리드 복합체를 합성하였다. 상기 제조된 하이브리드 소재를 슈퍼캐패시터 전극 물질로 사용하고자 수산화칼륨 전해질 기반의 3상 전극 시스템을 활용하여 전기화학적 특성을 살펴보았다. 또한 하이브리드 소재에 존재하는 그래핀과 다중벽 탄소나노튜브의 비율 변화 실험을 통하여, 그래핀/탄소나노튜브의 질량비가 7.5/1일 때 그 특성이 최적화가 됨을 알 수 있었다. 최적화된 전극은 높은 비축천용량(132 F/g)을 나타내었을 뿐만 아니라, 반복된 충방전 실험에서 높은 안정성(95%, retention after 5000 cycles)을 나타내었다.

Keywords

1. Introduction

Owing to increasing demands for the development of clean and renewable energy resources in order to solve emerging energy-related problems, various energy conversion and storage systems such as solar cells, fuel cells, lithium-ion batteries, and supercapacitors have attracted a great deal of interest in both academia and industry [1-3]. In particular, supercapacitors, also known as ultracapacitors or electrochemical capacitors, have become of great importance. This is because of their great potential as electrical storage units in portable electronic devices and electric vehicles, owing to their superior power density, high charge/discharge rate, and enhanced cycle life [4,5]. Based on their energy storage mechanism, supercapacitors can be categorized into three types: (i) electrical double-layer capacitors (EDLCs), in which the electrostatic charge is accumulated on the surface of the electrode by the formation of an electrical double-layer, (ii) pseudocapacitors with fast and reversible Faradaic charge transfer processes on or near the electrode surface, and (iii) hybrid capacitors in which the EDLCs and pseudocapacitors can work together. In general, carbon-based nanomaterials with a high specific surface area, for example, activated carbon, carbon nanotubes (CNTs), and graphene, have been widely used in EDLCs [4]. This is because the surface area of the electrode plays an important role in the performance of EDLCs. Furthermore, composite electrodes composed of carbonbased nanomaterials, together with conducting polymers or metal oxides have usually been applied to pseudocapacitors [4].

Among various carbon-based nanomaterials, graphene, as a two-dimensional single layer of graphite with carbon networks, has emerged as an ideal electrode for supercapacitors. This is because of its high specific surface area, excellent electron mobility, and superior mechanical properties [6]. Although the theoretical maximum double-layer capacitance of graphene can attain a value of up to 550 F/g [4], most graphene-based supercapacitors have limited capacitances. This is because of the structural and morphological defects of graphene sheets, such as the significant reduction in electrical conductivity and the ease of formation of large clusters, with reduced specific surface area. To solve these problems, the incorporation of CNTs into graphene networks has been suggested by several researchers [7-10]. In this condition, the significant reduction of electrical conductivity in graphene networks can be considerably minimized and the restacking of graphene sheets can be efficiently prevented by CNTs. However, most graphene/CNTs composites are prepared by physical adsorption or electrostatic forces, in which the interactions between graphene and CNTs are relatively weak and unstable. Therefore, it is necessary to develop alternative methods in order to enhance their relationship within composites.

Herein, we report a versatile and scalable approach to produce graphene-based hybrid materials for supercapacitors, using graphene oxide (GO) and 4-aminobenzoyl functionalized multiwalled carbon nanotubes (af-MWNTs) as precursors. GO and af-MWNTs are chemically connected by newly formed imine linkage (-C=N-) during the acid-catalyzed dehydration reaction between ketone (C=O) groups in GO and primary amine (-NH2) in af-MWNTs (Figure 1). In addition, GO can be readily reduced to restore the graphitic structure during the acid-catalyzed reaction at high temperature. The chemical structures of graphene/MWNTs hybrid materials have been confirmed by various microscopic and spectroscopic analyses. Furthermore, the weight ratio of graphene/MWNTs in hybrid materials can be simply controlled by changing the initial feed ratio. The optimum weight ratio is determined to be 7.5/1. The resultant hybrid materials demonstrated not only improved thermal stability but also superior capacitance with long-term stability.

Figure 1.Synthesis of graphene/MWNTs hybrid materials.

 

2. Material and methods

2.1. Synthesis of materials

Graphite nanopowders (450 nm APS, 99.9% purity) were obtained from Nanostructured and Amorphous Materials Inc., and were used as a starting material. Firstly, GO was prepared from graphite nanopowders, using a modified Hummer’s method [11]. The af-MWNTs were synthesized according to procedures in literature [12]. Subsequently, GO (300 mg) and varied amounts of af-MWNTs, ranging from 20 mg to 300 mg, were reacted to produce graphene/MWNTs hybrid materials; these were designated as GM1, GM3, GM7.5, and GM15 (the numbers denote the weight ratio between GO and af-MWNTs, and the higher the number, the larger the amount of graphene). The amount of af-MWNTs for the preparation of the GM1, GM3, GM7.5, and GM15 materials was 300 mg, 100 mg, 40 mg, and 20 mg, respectively. The experimental procedures are described as follows; GO and af-MWNTs were dispersed in a dimethylformamide (40 ml)/acetic acid (20 ml) mixture under sonication for 1 h. Subsequently, the mixture was reacted with continuous stirring at 110 ℃ for 24 h. On cooling to room temperature, the reaction mixture was filtered with a nylon membrane (0.45 μm) and washed several times with methanol and water. The resultant hybrid materials were further purified by Soxhlet extraction with water, THF, and methanol. Finally, hybrid materials were obtained as a black powder after vacuum drying at 50 ℃ overnight.

2.2. Characterizations

Elemental analysis (EA) was conducted with a Thermo Scientific Flash 2000. Fourier transform infrared (FT-IR) spectroscopy was performed on a Perkin-Elmer Spectrum 100 using KBr pellets. Themogravimetric analysis (TGA) was performed with a TA Q200 (TA Instrument) at a heating rate of 10 ℃ min−1, in air. Raman spectra were obtained by confocal Raman microscopy (Alpha 300S, WITec, Germany), in conjunction with atomic force microscopy (AFM) with a He-Ne laser (532 nm) as the excitation source. The field emission scanning electron microscopy (FE-SEM) was performed using a FEI Nanonova 230. Cyclic voltammetry (CV) analyses were conducted using a potentiostat (IVIUM CompactStat, IVIUM Technologies) with a standard three-electrode cell. Glassy carbon electrodes coated with hybrid materials were used as working electrodes. A platinum wire and an Ag/AgCl (3M NaCl filled) electrode were used as a counter and reference electrode, respectively.

 

3. Results and Discussion

Elemental analyses (EAs) were conducted to investigate the chemical compositions of all samples (i.e., GO, af-MWNTs, GM1, GM3, GM7.5 and GM15) and the results are summarized in Table 1. As expected, the main composition of af-MWNTs is carbon (78.56%); however, they also contain noticeable amounts of oxygen (10.97%) and nitrogen (5.95%), originating from 4-aminobenzoyl moieties on the surface [12]. GO possesses a high amount of oxygen (44.83%), owing to the existence of oxygenated functionalities (such as epoxy, hydroxyl, and carboxylic groups), which are generated by the severe oxidation process during the modified Hummer’s condition [13]. In comparison to GO, dramatic decreases in the oxygen content accompanied by a significant increase in carbon and nitrogen atoms have been observed in hybrid materials of graphene/MWNTs. It is noteworthy that these compositional changes from GO to hybrid materials can be attributed to two simultaneous dehydration reactions in an acidic condition; i.e., the reaction between the hydroxyl groups and the adjacent hydrogen atoms in GO, and the imine formation between the ketone (C=O) groups in GO and primary amine (-NH2) in af-MWNTs. These results indicate that the efficient structural restoration of graphene structures, in addition to the successful incorporation of MWNTs in graphene networks via imine linkage, can take place during the acid-catalyzed reaction that was used in this study.

Table 1.Summary of elemental analyses of GO, af-MWNTs, GM1, GM3, GM7.5, and GM15

FT-IR measurements using KBr pellets were also conducted to investigate the structural changes prior to and after the reactions. Typically, a sp3C-H peak at 2920 cm−1 and a carbonyl peak at 1707 cm−1 have been observed in af-MWNTs. In addition, GO shows several peaks from various oxygenated functionalities at 1726 (vC=O), 1624 (vC=C), 1388 (vO-H), 1226 (vepoxy), and 1057 cm−1 (vC-O), in addition to strong hydroxyl bands (3358 cm−1). These observations correlate well with previous reports (Figure 2(a)) [13]. However, all graphene/MWNTs hybrid materials display two distinct peaks at 1581 cm−1 and 1221 cm−1, which represent in-plane vibrations of aromatic C=C sp2 hybridized carbon combined with C=N stretching vibrations, and C-N stretching modes, respectively [14,15]. Therefore, these results clearly demonstrate the chemical structures of graphene/MWNTs hybrid materials, which is coherent with the proposed scheme shown in Figure 1.

Figure 2.(a) FT-IR spectra and (b) TGA thermograms of GO, af-MWNTs, GM1, GM3, GM7.5, and GM15.

The thermal stability of all samples was examined by thermogravimetric analysis (TGA). As demonstrated in Figure 2(b), af-MWNTs start to decompose at 450 ℃, while GO exhibits a drastic thermal decomposition near 200 ℃, due to the presence of large amounts of oxygenated functionalities. Surprisingly, all hybrid materials show improved thermal stability regardless of the weight ratio between graphene and MWNTs. This can be attributed to the efficient restoration of the graphitic structure by the removal of various oxygenated groups as well as the formation of imine linkage during acid-catalyzed reactions. These results reveal, once again, that the acid-catalyzed reaction used in this study is beneficial to the production of high quality graphene/MWNTs hybrid materials.

Raman spectra obtained from all the powder samples are shown in Figure 3. The broad and strong D band at 1353 cm−1 and G band at 1590 cm−1 were clearly observed in GO and af-MWNTs. The ratio of the intensity of the D and G bands (ID/IG) can attain values up to 1.06 and 1.24 for GO and af-MWNTs, respectively. This is due to the large structural distortion and the reduction in size of the sp2 domains [16]. Similarly, all graphene/MWNTs hybrid materials show D and G bands at 1352 and 1590 cm−1, respectively, with a relatively high ID/IG ratio of 1.10. This indicates the presence of disordered graphitic structures within the hybrid materials. However, the almost identical value of the ID/IG ratio reveals that the amount of af-MWNTs on graphene does not introduce a noticeable amount of defects in hybrid materials.

Figure 3.Raman spectra of GO, af-MWNTs, GM1, GM3, GM7.5, and GM15.

Raman spectra obtained from all the powder samples are shown in Figure 3. The broad and strong D band at 1353 cm−1 and G band at 1590 cm−1 were clearly observed in GO and af-MWNTs. The ratio of the intensity of the D and G bands (ID/IG) can attain values up to 1.06 and 1.24 for GO and af-MWNTs, respectively. This is due to the large structural distortion and the reduction in size of the sp2 domains [16]. Similarly, all graphene/MWNTs hybrid materials show D and G bands at 1352 and 1590 cm−1, respectively, with a relatively high ID/IG ratio of 1.10. This indicates the presence of disordered graphitic structures within the hybrid materials. However, the almost identical value of the ID/IG ratio reveals that the amount of af-MWNTs on graphene does not introduce a noticeable amount of defects in hybrid materials.

SEM measurements were performed to investigate the morphological and micro-structural changes during the formation of hybrid materials. The unique densely packed sheets of GO and tubular structures of af-MWNTs can be observed in Figure 4(a) and 4(b), respectively. The entangled MWNTs in good contact with the graphene sheets, in addition to the wrinkled paper-like structures with relatively high electron transparency, appear in the SEM images of the hybrid materials (Figure 4(c)-(f)). In addition, the quantity of MWNTs in hybrid materials is almost disproportional to the weight ratio of graphene/MWNTs. Therefore, the SEM images clearly demonstrate that the chemically linked MWNTs on the graphene surface act as a spacer material to prevent the undesirable coalescence of graphene sheets and it also facilitates the control of MWNTs content within the hybrid materials.

Figure 4.SEM images of GO, af-MWNTs, GM1, GM3, GM7.5, and GM15. Scale bars in the images are 4 μm.

To investigate the electrochemical performance of hybrid materials as electrodes in supercapacitors, cyclovoltametric (CV) analyses were conducted in 1 M KOH solution, using a standard three-electrode cell. As demonstrated in Figure 5(a) and Table 2, all hybrid materials exhibit an enhanced current density when compared with af-MWNTs, implying a larger specific capacitance. In addition, the CV curves of the hybrid materials were of almost rectangular geometry, which implies a low contact resistance during CV measurements. However, a significant reduction in capacitance was observed in the hybrid materials with a lower weight ratio of graphene, i.e., GM1 and GN3. The limited electrochemical performance was due to the huge irregular aggregation of MWNTs on the graphene layers. Interestingly, the current density of the hybrid materials increased in proportion to the weight ratio of graphene/MWNTs, and subsequently finally saturated. When the weight ratio of graphene/MWNTs was 7.5/1, the highest capacitance of 132.4 F/g, at a scan rate of 100 mV/s, was obtained (Table 2). These enhancements in the electrochemical performance of the hybrid materials can be attributed to their unique 3D architectures. The 3 D architectures are composed of highly exfoliated graphene layers, owing to the incorporation of MWNTs through chemical linkage. These configurations can provide several advantages to supercapacitive applications, such as the fast transportation of ions and electrons, facilitation of electrolyte penetration, and the reduction of energy loss during charge-discharge. Figure 5(b) shows the CV curves of the GM7.5 material in 1 M KOH solution, with various scan rates ranging from 5 to 200 mV/s. The specific capacitance of the GM7.5 material gradually decreased as the scan rate increased; this observation correlates well with previous reports [7,8]. Moreover, the GM7.5 material demonstrates a specific capacitance of 118.1 F/g, even at 200 mV/s. This correlates to a retention of approximately 72%, in comparison to the value at 5 mW/s. This result demonstrates the significant potential of hybrid materials for high rate applications in supercapacitors.

Figure 5.(a) Cyclic voltamograms of af-MWNTs, GM1, GM3, GM 7.5, and GM15 in 1 M KOH solution at a scan rate of 100 mV/s; (b) Capacitance of GM7.5 in 1 M KOH solution at various scan rates.

Table 2.Capacitance of af-MWNTs, GM1, GM3, GM7.5, and GM15 in 1 M KOH solution at a scan rate of 100 mV/s.

The cyclic stability of hybrid materials as electrodes in supercapacitors was also evaluated by operating the electrochemical cell at a scan rate of 100 mV/s for 5000 cycles. As shown in Figure 6, the specific capacitance of the GM7.5 material demonstrates excellent stability during all cycles, and the retention of the initial capacity can reach up to 95%, even after 5000 cycles. This high retention value of the hybrid materials originates from the efficient prevention of the selling and shrinkage of the electrode during the charge-discharge process, owing to the highly stable chemical linkages between graphene and af-MWNTs in the hybrid materials.

Figure 6.Stability test of GM7.5 in 1 M KOH solution at a scan rate of 100 mV/s.

 

4. Conclusions

We have developed a simple, but efficient method to produce graphene/MWNTs hybrid materials via the acid-catalyzed dehydration reaction between the most commonly studied GO and primary amine-containing MWNTs. The weight ratio between the GO and MWNTs in the hybrid materials was varied from 1/1 to 15/1. A maximum capacitance of 132.4 F/g was obtained when the weight ratio was 7.5/1. These hybrid materials show not only improved capacitance but also excellent long-term stability. The process developed in this study provides new insights into the simple synthesis of graphene/MWNTs hybrid structures through stable chemical linkages. Furthermore, it suggests a simple and large-scale production method for highquality graphene/MWNTs hybrid materials for various applications such as supercapacitors, fuel cells, and optoelectronic devices.

References

  1. Dai, L., "Carbon Nanomaterials for Advanced Energy Conversion and Storage," Small, 8, 1130-1166 (2012). https://doi.org/10.1002/smll.201101594
  2. Dai, L., "Functionalization of Graphene for Energy Conversion and Storage," Accounts Chem. Res., 46, 31-42 (2013). https://doi.org/10.1021/ar300122m
  3. Zhang, Q., Uchaker, E., Candelaria, S. L., and Guozhong, C., "Nanomaterials for Energy Conversion and Storage," Chem. Soc. Rev., 42, 3127-3171 (2013). https://doi.org/10.1039/c3cs00009e
  4. Chen, T., and Dai, L., "Flexible Supercapacitors Based on Carbon Nanomaterials," J. Mater. Chem. A, 2, 10756-10775 (2014). https://doi.org/10.1039/c4ta00567h
  5. Peng, X., Peng, L., Changzheng, W., and Xie, Y., "Two Dimensional Nanomaterials for Flexible Supercapacitors," Chem. Soc. Rev., 43, 3303-3323 (2014). https://doi.org/10.1039/c3cs60407a
  6. Tan, Y. B., and Lee, J. M., "Graphene for Supercapacitor Applications", J. Mater. Chem. A, 1, 14814-14943 (2013). https://doi.org/10.1039/c3ta12193c
  7. Cheng, Q., Tang, J., Ma, J., Zhang, H., Shinya, N., and Qin, L. C., "Graphene and Carbon Nanotube Composite Electrodes for Supercapacitors with Ultra-high Energy Density," Phys. Chem. Chem. Phys., 13, 17615-17624 (2011). https://doi.org/10.1039/c1cp21910c
  8. Zeng, F., Kuang, Y., Zhang, N., Huang, Z., Pan, Y., Hou, Z., Zhou, H., and Yan, C., and Schmidt, O. G., "Multilayer Super-short Carbon Nanotube/Reduced Graphene Oxide Architecture for Enhanced Supercapacitor Properties," J. Power Sources, 247, 396-401 (2014). https://doi.org/10.1016/j.jpowsour.2013.08.122
  9. Kim, K. S., and Park, S. J., "Influence of Multi-walled Carbon Nanotubes on the Electrochemical Performance of Graphene Nanocomposites for Supercapacitor Electodes," Electrochim. Acta, 56, 1629-1635 (2011). https://doi.org/10.1016/j.electacta.2010.10.043
  10. Yu, D., and Liming, D., "Self-assembled Graphene/Carbon Nanotube Hybrid Films for Supercapacitors," J. Phys. Chem. Lett., 1, 467-470 (2010). https://doi.org/10.1021/jz9003137
  11. Hummers, W. S., and Offeman, R. E., "Preparation of Graphitic Oxide," J. Am. Chem. Soc., 80, 1339-1339 (1958). https://doi.org/10.1021/ja01539a017
  12. Jeon, I. Y., Kang, S. W., Tan, L. S., and Baek, J. B., "Grafting of Polyaniline onto the Surface of 4-Aminobenzoyl Functionalized Multiwalled Carbon Nanotube and Its Electrochemical Properties," J. Polym. Sci. A: Polym. Chem., 48, 3103-3112 (2010). https://doi.org/10.1002/pola.24091
  13. Stankovich, S., Dikin, D. A., Piner, R. D., Kohlhaas, K. A., Kleinhammes, A., Jia, Y., Wu, Y., Nguyen, S., and Ruoff, R. S., "Synthesis of Graphene-based Nanosheet via Chemical Reduction of Exfoliated Graphite Oxide," Carbon, 45, 1558-1565 (2007). https://doi.org/10.1016/j.carbon.2007.02.034
  14. Almandhoun, M. N., Hedhili, M., Odeh, I. N., Xavier, P., Bhansali, U. S., and Alshareef, H., "Influence of Stacking Morphology and Edge Nitrogen Doping on the Dielectric Performances of Graphene-polymer Nanocomposites," Chem. Mater., 26, 2856-2861 (2014). https://doi.org/10.1021/cm5004565
  15. Lin, Y., and Su, D., "Fabrication of Nitrogen-Modified Annealed Nanodiamond with Improved Catalytic Activity," ACS Nano, 8, 7828-7833 (2014).
  16. Chang, D. W., Choi, H. J., Jeon, I. Y., Seo, J. M., Dai, L., and J. B. Baek, "Solvent-free Mechanochemical Reduction of Graphene Oxide," Carbon, 77, 501-507 (2014). https://doi.org/10.1016/j.carbon.2014.05.055

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