Surface Area Of Graphene Nanosheets Research Articles

Graphene nanosheets from hazardous/solid wastes: An efficient CO2 capture material

Highly efficient CO2 capture at elevated temperatures has been achieved with a few-layered graphene nanosheets (GNS) prepared from solid waste generated from high energy explosive materials manufacturing industry. These materials were used to adsorb CO2 from simulated industrial flue gases with an aim to reduce CO2 concentration in the atmosphere. The GNS is a microporous material with pore volume of 0.59 cm3 g−1 and 70% of pores were of average size of 0.55 nm. The surface area of GNS was 964 m2 g−1 which was reduced to 268 m2 g−1 when the number of layers in GNS increased to >50. The adsorption capacity of 3.89 mmol g−1 was achieved at 303 K/0.5 bar and this adsorption capacity was further increased to 23.63 mmol g−1 at 303 K/20 bar. The Sips adsorption model was used for evaluating the relationship between surface heterogeneity of GNS and adsorption capacity at temperature. The GNS materials selectively captured CO2 in the presence of gases mixtures (CO2/N2 and CO2/CH4). The fast adsorption kinetics and recycling stability of GNS for about 20 cycles suggests that the solid adsorbents prepared in this study are efficient and technically feasible to capture CO2 from industrial stacks and other real-life situations.

Study on the hydrogen storage properties of the dual active metals Ni and Al doped graphene composites

The graphene nanosheets are synthesized by modified Hummer's method, based on which the dual active metals Ni and Al doped graphene composites are prepared through in-suit reaction and self-assembly with high-temperature reduction process. The molecular structure, morphology and specific surface area of graphene nanosheets are characterized systematically. The phase composition, surface morphology and hydrogen storage properties of dual active metals Ni and Al doped graphene composites are further investigated by X-ray diffraction, scanning electron microscopy and gas reaction controller. Results show that the graphene nanosheets have typical graphene feature, whose transparent graphene edges can be observed clearly, and the specific surface area is as high as 604.2 m2 g−1. The Ni and Al doped graphene composites are composed with Ni, Al and C phases, which have high hydrogen storage capacity and excellent hydriding/dehydriding stabilities. The maximum hydrogen storage uptake of such composites is up to 5.7 wt% at 473 K, and the dehydriding efficiency is high as 96%∼97% at the dehydriding temperature of 380 K. The hydrogen adsorption and desorption rate control step of the Ni and Al doped graphene composites is complied to the nucleation and two-dimensional growth mechanism.

Evaluation of viscosity and thermal conductivity of graphene nanoplatelets nanofluids through a combined experimental–statistical approach using respond surface methodology method

In the present study, three influential parameters including concentration, temperature and specific surface area of graphene nanosheets were investigated, which are the effective parameters on the viscosity and thermal conductivity of aqueous graphene nanosheets (GNP) nanofluids. A mathematical model developed by respond surface methodology (RSM) based on a central composite design (CCD). Also, the significance of the models was tested using the analysis of variance (ANOVA). The optimum results of aqueous GNP nanofluid showed that the concentration has a direct effect on the relative viscosity and thermal conductivity. Furthermore, predicted responses proposed by the Design Expert software were compared with the experimental results. The statistical analysis of the predicted values was in satisfactory agreement with the empirical data.

A Polymer Surfactant Assisted Method for the Synthesis of Clusters of Mn3O4 Nanoparticles on Few-Layer Exfoliated Graphene Platelet Surface and Its Application As Lithium-Ion Battery Anode

Composites synthesized through the deposition of Mn3O4 on graphene, carbon nanotube and other carbon based materials have attracted much attention recently as potential electrode materials for different electrochemical applications such as pseudocapacitor; Lithium-ion battery; and catalysis. The primary reason Mn3O4 is grown on these substrates in spite of having high charge storage capacity as pseudocapacitor or Lithium-ion battery electrodes on its own is to enhance its electrical conductivity and/or to impart flexibility to the electrode, which is difficult for a fully metallic electrode. Higher electrical conductivity prolongs the cycle life of an electrode. In addition, the substrate contributes capacity and thus, enhances the overall energy density of an electrode. Mn3O4 acts as a spacer and keeps graphene nanosheets separated when used as the substrate for capacitor electrode fabrication. This helps retain the high surface area of graphene nanosheets in the electrode which contributes additional capacitance. Mn3O4 supported on graphene and other carbon substrates have recently been investigated as catalyst for methanol electro-oxidation in alkaline media; CO oxidation; and Oxygen reduction reaction (ORR). High surface area substrate uniformly distributes metal particles and prevents their agglomeration and dissolution during catalytic process. In addition, high electrical conductivity of graphene and carbon substrates enhances the electronic conductivity of Mn3O4 which is of importance for superior catalytic activity. Composite of Mn3O4 combined with carbon based substrate has also found non-electrochemical application such as the removal of Pb and Cu ions from aqueous solution because of their adsorptive behaviour. A myriad of procedures have been adopted for the synthesis of Mn3O4 on graphene or other carbonaceous substrates. All of these methods involve one or more of the following factors that complicate the process, such as: long synthesis time; high synthesis temperature; use of hazardous/toxic chemicals; multistep process and the requirement for sophisticated device or highly controlled environment. In fact, the complicacies associated with the synthesis of Mn3O4 have already been acknowledged and investigations have been directed at finding relatively simpler route such as the use of microwave technique. In this research, we report the synthesis of clusters of nearly octahedral shaped Mn3O4 nanoparticles on few-layer exfoliated graphene platelet (15µm diameter, thickness 6-8 nanometer, 120-150 m2/g surface area) surface through a simple, wet-chemical, polyethyleneimine (PEI) mediated route. Few-layer exfoliated graphene platelets are ultrathin particles of graphite that can also be thought of as short stacks of graphene sheets prepared through proprietary manufacturing processes. Several grades and sizes with thicknesses ranging from 1-20 nanometers and width ranging from 1-50µm are manufactured by XG Sciences, Lansing, MI, USA. Unique manufacturing processes for these platelet materials are non-oxidizing; thus, yielding a pristine graphitic surface of sp2 carbon molecules. This makes these platelet particles especially suitable for applications requiring high electrical and thermal conductivities. The surface areas of the resulting platelets predominantly consist of the open surface areas of the graphene basal planes. The components involved in this synthesis method are manganese salts (KMnO4 and MnSO4.H2O); water; PEI; and few-layer exfoliated graphene platelet as the substrate. The synthesis is carried out at a temperature of 80°C only and in open air. Highly crystallized Mn3O4 particles, as observed by X-Ray Diffraction (XRD), can be synthesized on few-layer exfoliated graphene platelet surface. It has also been observed that PEI acts as a reducing agent and as a capping agent on a continuous network of ribbon-like Birnessite-MnO2 (IV) to produce a nearly octahedral shaped nanoparticles of Mn3O4 (II, III). It has already been mentioned that composites of Mn3O4 on graphene or other carbonaceous substrates find a myriad of applications. Thus, our research findings to synthesize few-layer exfoliated graphene platelet-Mn3O4 composite through a simple method should be of interest to a broad group of researchers. In this research, we have investigated the performance of this composite system as a Lithium-ion battery anode only. Our preliminary investigations reveal that the Mn3O4 composite synthesized through this method has just as much potential as the ones prepared through other alternative methods.

Synthesis of Clustered Mn3O4 Nanoparticles through a Polymer Surfactant Mediated Route on Few-Layer Exfoliated Graphene Platelet Surface and Its Application for Electrochemical Energy Storage: Lithium-Ion Battery Anode

Composites synthesized through the deposition of Mn3O4 on graphene, carbon nanotube and other carbon based materials have attracted much attention recently as potential electrode materials for different electrochemical applications such as pseudocapacitor; Lithium-ion battery; and catalysis. The primary reason Mn3O4 is grown on these substrates in spite of having high charge storage capacity as pseudocapacitor or Lithium-ion battery electrodes on its own is to enhance its electrical conductivity and/or to impart flexibility to the electrode, which is difficult for a fully metallic electrode. Higher electrical conductivity prolongs the cycle life of an electrode. In addition, the substrate contributes capacity and thus, enhances the overall energy density of an electrode. Mn3O4 acts as a spacer and keeps graphene nanosheets separated when used as the substrate for capacitor electrode fabrication. This helps retain the high surface area of graphene nanosheets in the electrode which contributes additional capacitance. Mn3O4 supported on graphene and other carbon substrates have recently been investigated as catalyst for methanol electro-oxidation in alkaline media; CO oxidation; and Oxygen reduction reaction (ORR). High surface area substrate uniformly distributes metal particles and prevents their agglomeration and dissolution during catalytic process. In addition, high electrical conductivity of graphene and carbon substrates enhances the electronic conductivity of Mn3O4 which is of importance for superior catalytic activity. Composite of Mn3O4 combined with carbon based substrate has also found non-electrochemical application such as the removal of Pb and Cu ions from aqueous solution because of their adsorptive behaviour. A myriad of procedures have been adopted for the synthesis of Mn3O4 on graphene or other carbonaceous substrates. All of these methods involve one or more of the following factors that complicate the process, such as: long synthesis time; high synthesis temperature; use of hazardous/toxic chemicals; multistep process and the requirement for sophisticated device or highly controlled environment. In fact, the complicacies associated with the synthesis of Mn3O4 have already been acknowledged and investigations have been directed at finding relatively simpler route such as the use of microwave technique. In this research, we report the synthesis of clusters of nearly octahedral shaped Mn3O4 nanoparticles on few-layer exfoliated graphene platelet (15µm diameter, thickness 6-8 nanometer, 120-150 m2/g surface area) surface through a simple, wet-chemical, polyethyleneimine (PEI) mediated route. Few-layer exfoliated graphene platelets are ultrathin particles of graphite that can also be thought of as short stacks of graphene sheets prepared through proprietary manufacturing processes. Several grades and sizes with thicknesses ranging from 1-20 nanometers and width ranging from 1-50µm are manufactured by XG Sciences, Lansing, MI, USA. Unique manufacturing processes for these platelet materials are non-oxidizing; thus, yielding a pristine graphitic surface of sp2 carbon molecules. This makes these platelet particles especially suitable for applications requiring high electrical and thermal conductivities. The surface areas of the resulting platelets predominantly consist of the open surface areas of the graphene basal planes. The components involved in this synthesis method are manganese salts (KMnO4 and MnSO4.H2O); water; PEI; and few-layer exfoliated graphene platelet as the substrate. The synthesis is carried out at a temperature of 80°C only and in open air. Highly crystallized Mn3O4 particles, as observed by X-Ray Diffraction (XRD), can be synthesized on few-layer exfoliated graphene platelet surface. It has also been observed that PEI acts as a reducing agent and as a capping agent on a continuous network of ribbon-like Birnessite-MnO2 (IV) to produce a nearly octahedral shaped nanoparticles of Mn3O4 (II, III). It has already been mentioned that composites of Mn3O4 on graphene or other carbonaceous substrates find a myriad of applications. Thus, our research findings to synthesize few-layer exfoliated graphene platelet-Mn3O4 composite through a simple method should be of interest to a broad group of researchers. In this research, we have investigated the performance of this composite system as a Lithium-ion battery anode only. Our preliminary investigations reveal that the Mn3O4 composite synthesized through this method has just as much potential as the ones prepared through other alternative methods.

Binder-free combination of graphene nanosheets with TiO2 nanotube arrays for lithium ion battery anode

Binder-free combination of graphene nanosheets with oriented TiO2 nanotube arrays was designed and achieved via one-step facile electrodeposition. The structure and morphology of as-prepared composite graphene nanosheets/TiO2 nanotube arrays were studied in terms of SEM, FESEM, EDX, TEM, Raman and FTIR. Furthermore, the corresponding electrochemical performances were evaluated in terms of galvanostatic charge/discharge, cycle stability and AC impedance. As expected, the composite graphene nanosheets/TiO2 nanotube arrays displayed higher discharge capacity, cycle stability and Li+ diffusion coefficient than bare TiO2 nanotube arrays. High Li-storage activity, superior conductivity and large surface area of graphene nanosheets should be responsible for improved electrochemical performances.

Investigation of thermal properties and mechanical properties of reduced graphene oxide/polyimide resin composites

In this article, reduced graphene oxide/polyimide resin composites which exhibited enhancements in mechanical properties were successfully fabricated by hot‐pressing, and reduced graphene oxide nanosheets were synthesized by thermal reduced method, which can readily mix with PI powders in aqueous solution by sonication process. The chemical structures of rGO were carefully characterized by X‐ray diffraction, Fourier transfer infrared spectroscopy and X‐ray photoelectron spectroscopy. The field emission scanning electron microscopy observations showed that the rGO displayed excellent dispersibility and compatibility with the PI matrix. The mechanical analysis indicated that the tensile and flexural strength values of the rGO/PI resin composite with 1.5 wt% rGO loading reached 80.7 and 133.3 MPa, respectively. Compared with pure PI, the optimized rGO/PI resin composite exhibited an enhancement of 30% in tensile strength, 19% in flexural strength and 27% in impact strength, due to the fine dispersion of high specific surface area of graphene nanosheets and the good adhesion between the rGO and the matrix. In addition, thermogravimetric analysis, dynamic mechanical analysis, and dielectric properties were also investigated. POLYM. COMPOS., 38:2321–2331, 2017. © 2015 Society of Plastics Engineers

Self-Assembled Multilayer Films of Sulfonated Graphene and Polystyrene-Based Diazonium Salt as Photo-Cross-Linkable Supercapacitor Electrodes

Photo-cross-linkable multilayer films composed of sulfonated reduced graphene oxide (SRGO) and polystyrene-based diazonium salt (PSDAS) were fabricated by electrostatic layer-by-layer (LbL) self-assembly. Polystyrene with narrow molecular weight distribution was synthesized by atom transfer radical polymerization (ATRP), and cationic PSDAS was prepared through nitration, reduction, and diazotization reactions. Negatively charged SRGO nanosheets were prepared through prereduced by NaBH4, modified by diazonium salt of sulfanilic acid, and then further reduced by hydrazine. The multilayer films were obtained by alternately dipping substrates in the PSDAS solution and SRGO dispersion in acidic conditions. The cross-linking between the components occurred during the multilayer formation process and was further achieved by the UV light irradiation after the film preparation. The assembling process and surface morphology of LbL multilayer films were monitored by UV-vis spectroscopy, atomic force microscopy (AFM), and scanning electron microscopy (SEM). The cross-linking between SRGO and PSDAS was verified by attenuated total reflectance FTIR (ATR-FTIR) spectroscopy, X-ray photoelectron spectroscopy (XPS), and contact angle measurement. The graphene nanosheets were found to be homogeneously distributed in the cross-linked network of the films. The large accessible surface area of graphene nanosheets and the cross-linking structure afforded the LbL films with high specific capacitance and excellent cyclic stability when used as supercapacitor electrodes. At a sweeping rate of 10 mV/s, the film with nine bilayers exhibited a specific capacitance of 150.4 F/g with ideal rectangular cyclic voltammogram. Large capacitance retention of 97% was observed after 10 000 charge-discharge cycles under the scanning rate of 1000 mV/s. This new approach for preparing graphene-containing multilayer films can be used to develop supercapacitor electrodes and other functional devices.

The deposition of iron and silver nanoparticles in graphene–polyelectrolyte brushes

The high surface area of graphene nanosheets (GNs) enables them to load metal nanoparticles (NPs) for various applications such as catalysis, sensors and biomedicine. To optimize the performance, it is desired to establish an effective approach that can tune the morphology of metal nanoparticles (NPs) on GNs. We here demonstrate that GN–poly(acrylic acid) (GN/PAA) brushes can control the size and spatial distributions of iron and silver NPs. Results of Raman, Fourier transform infrared and x-ray photoelectron spectroscopy confirm the covalent bonding between PAA chains and GNs. Thermogravimetric analysis reveals a PAA grafting density of ∼0.055 chain nm−2. Transmission electron microscopy is used to study the effect of PAA chain length and precursor concentration on the morphology of the metal NPs deposited on PAA brushes and graphene oxide (GO). Short PAA brushes are found to be effective for controlling the spatial and size distributions of the NPs, resulting in small particle sizes and homogeneous distributions compared to those deposited on GO. The concentration of precursors has a limited effect on the dimension of the NPs in the brushes due to the key role that polyelectrolyte brushes play in controlling the growth of NPs.

Graphene nanosheets reduced by a multi-step process as high-performance electrode material for capacitive deionisation

We employed a novel three-step reduction of graphite oxide (GO) to obtain graphene nanosheets with high specific surface area and good dispersion in aqueous solution. Iron powder, as a mild and environmentally friendly reducing agent, was used at first in partial-reduction of GO and then, sulphonic functional groups (–SO3−) were introduced on the surface of partially reduced GO. The negatively charged –SO3− units can effectively prevent the graphitic sheets from aggregating and enhance specific surface area of graphene nanosheets after further reduction by hydrazine. The resulting graphene nanosheets exhibited a high specific surface area of 464m2/g with mean pore size of 3.3nm and specific capacitance of 149.8F/g. Electrodes based on this kind of graphene nanosheets achieved a NaCl removal efficiency of 83.4% and specific electrosorptive capacity of 8.6mg/g with outstanding regeneration capability, demonstrating great potential in application of graphene-based materials in capacitive deionization process for water desalination.

Synthesis of Graphene Nanosheets <i>via</i> Thermal Exfoliation of Pretreated Graphite at Low Temperature

In this work, we synthesized graphene nanosheets via a soft chemistry synthetic route involving pre-exfoliation treatment, strong oxidation, and post thermal exfoliation. X-ray diffraction (XRD), Raman spectroscopy, atomic force microscopy (AFM), and transmission electron microscopy (TEM) confirmed the ordered graphite crystal structure and morphology of graphene nanosheets. N2 adsorption was used to determine the specific surface area of graphene nanosheets. As a result, pre-treatment of the graphite with HNO3/H2SO4 mixture produced the exfoliated graphite nanoplates, and the post thermal exfoliation of the graphite oxide nanosheets at low temperature led to produce a large number graphene nanosheets. The specific surface area of obtained graphene nanosheets was 333 m2/g.