Graphene-like Carbon Material Research Articles

Ligin-derived graphene-like ultrathin carbon materials for ORR catalysis

Low-cost nitrogen-doped carbon materials with graphene-like structures were designed and prepared from extensive renewable biomass waste lignin. The obtained carbon materials exhibited well-designed ultrathin two-dimensional structures with high specific area and mesoporous characteristics. Benefiting from the well-designed structures with extensive catalytic active sites and efficient mass transfer and diffusion, as well as the modified electronic characteristics from nitrogen doping, the lignin-derived carbon materials exhibited pronounced ORR catalytic activity and methanol tolerance. Considering these, the lignin-derived carbon materials hold great application potentials as ORR catalysts and catalyst supports.

Synthesis of ultra-thin graphene-like nanosheets from lignin based on evaporation induced self-assembly for supercapacitors

Graphene-like carbon materials are widely used in power devices due to their excellent structural characteristics. In this study, ultra-thin graphene-like nanosheets (LGLNs) with rich surface wrinkles were prepared by classical evaporation induced self-assembly (EISA) using lignin biomass as carbon precursor, followed by chemical activation with KHCO3. The obtained LGLN900 material calcined at 900 °C had a thickness of ca. 3 nm, a large specific surface area of 2886 m2 g−1 with a high specific pore volume of 2.10 cm3 g−1. In addition, a large number of wrinkles on the surface of LGLN900 endows its effective compression resistance. When the LGLN900 material was used as electrode material of supercapacitor, a high specific capacitance of 388 F g−1 was obtained at 0.2 A g−1 current density in 6 M KOH aqueous solution, and 269 F g−1 specific capacitance could be at remained at 40 A g−1. The supercapacitor assembled with LGLN900 afforded a specific energy density of (11.0–13.7) Wh kg−1 at a power density of (128.8–6465) W kg−1. This work provides a facile and green strategy for the synthesis of highly wrinkled ultra-thin graphene-like nanosheets from sustainable biomass resources, which should have wide applications in adsorption, catalysis and energy storage.

Ultra-thin highly-wrinkled graphene-like nanosheets for supercapacitor electrodes via 4-nitrocatechol and solvent-induced self-assembly

Graphene-like carbon materials are in high demand due to their potential applications in power devices. However, conventional synthesis of graphene-like materials causes repacking to occur during high-pressure compression steps resulting in low surface areas and unfavorable structures for mass transfer. Herein, ultra-thin wrinkled graphene-like nanosheets (GNs) were prepared simply via classical evaporation induced self-assembly (EISA) of 4-nitrocatechol as carbon precursor. Combination of EISA and subsequent KHCO3 activation and calcination at 900 °C (GN-900) afforded materials with thicknesses of (2–3) nm, specific surface areas of 3300 m2 g−1 with specific pore volumes of 2.34 cm3 g−1 under optimum conditions. When GN-900 was evaluated as an electrode material, a specific capacitance of 367 F g−1 was achieved at 0.2 A g−1 current density in 6 M KOH aqueous solution with a rate capability of 228 F g−1 at 40 A g−1. Supercapacitors assembled with GN-900 had specific energy densities of 11.5 Wh kg−1 at power densities of 89.8 W kg−1. Moreover, capacitance retention was greater than 98% after 3000 cycles at 10A g−1. Materials prepared with the proposed methods in this study were determined to be structurally stable and to exhibit favorable electrochemical performance for present and near-future supercapacitor applications.

Microwave-assisted preparation of novel graphene-like carbon material from waste bamboo for high-performance supercapacitors

Microwave-assisted preparation of novel graphene-like carbon material from waste bamboo for high-performance supercapacitors

Preparation and mechanism of biomass-derived graphene-like Li+/Na+ battery anodes controlled by N/O functional groups and interlayer spacing

The universal electrode material can be applied to the traditional Li-ion battery of the emerging alkaline ion battery at the same time, providing a new idea for the development of energy storage systems (EESs). In this study, a porous graphene-like biomass carbon material anode was prepared by chemical blowing strategy and KOH activation method. As the anode of both Li/Na ion batteries, it has excellent cycle stability and extremely high-rate cycle performance. Under the charge-discharge rate of 0.2c, the reversible capacity of Li-ion battery assembled by anode material was 953.2 mA g −1 , and that of Na-ion battery was 378.2 mA g −1 . Under the condition of 10c, the reversible capacity was 352.6 mA g −1 and 127.6 mA g −1 . Its excellent electrochemical performance can be attributed to its wide interlayer spacing, rich pore structure and N/O double doping, and its pseudocapacitance mechanism is conducive to the diffusion of alkaline ions. First-principles calculations further show that its doped structure is beneficial to promote ion adsorption and improve the conductivity of the material. This work has promoted the development of sustainable energy storage materials and provided new ideas for the development of carbon-based anode materials. The porous graphene-like biomass carbon material anode was prepared by chemical blowing strategy and KOH activation method. Combining the effect of interlayer spacing regulation and doped N/O functional group, this carbon-based material has displayed excellent electrochemical performance. When used as anode for lithium-ion batteries, the reversible capacity was 953.2 mA g −1 under 0.2c, and that of Na-ion battery was 378.2 mA g −1 . Under 10c, the reversible capacities of Li-ion and Na-ion batteries were 352.6 mA g −1 and 127.6 mA g −1 . First-principles calculations show that the doped structure is beneficial to promote ion adsorption and improve the conductivity of the material. • Under 0.2c, the reversible capacity of Li-ion battery assembled by anode material was 953.2 mA g −1 , and that of Na-ion battery was 378.2 mA g −1 . • Under 10 c, the reversible capacities of Li-ion and Na-ion batteries were 352.6 mA g −1 and 127.6 mA g −1 . • First-principles calculations show that the doped structure is beneficial to promote ion adsorption and improve the conductivity of the material.

Biomass-derived graphene-like carbon nanoflakes for advanced supercapacitor and hydrogen evolution reaction

It is valuable that graphene-like carbon materials are prepared from the biomass resources due to their unique two-dimensional structure, heteroatom enriched, and high specific surface area. Herein, we use egg white and graphene oxides as precursor and employ post-hydrothermal carbonization approach, freeze-drying technique, carbonization, and activation methods by KOH to prepare the graphite carbon nanoflakes with Fe7C3 @graphite carbon nanoflakes hybrid materials. Morphology tests imply that the formation of graphite carbon nanoflakes are mainly depended by activation step, it implies that carbon flakes are exfoliated via introducing K+ into carbon layers and further destroying the van der Waals force (VDWF). As a result, this hybrid materials exhibit an attractive capacitance (528 mF·cm−2 @1 mA·cm−2) and durability (91 @10 mA·cm−2, 4000 cycles). For hydrogen evolution reaction (HER), the as-collected samples also deliver a low overpotential and remarkable stability. We believe that the as-obtained hybrid materials have a greatly application value in energy storage devices.

Ruthenium-based graphene-like layered carbon compos-ites as high-efficiency electrocatalyst for hydrogen evolu-tion reaction

The development of cheap and efficient nonplatinum catalysts under alkaline conditions is of great significance for hydrogen evolution. Here, a N-doped porous layered graphene-like carbon material was designed. When J = 10 mA cm−2, it showed good HER catalytic activity, the overpotential was 50.2 mV, and 186.0 mV at 100 mA cm−2. And its outstanding catalytic ability is confirmed by Tafel slope, EIS, Cdl, ECSA and electrochemical stability. Its excellent performance provides a reasonable way to explore and develop catalysts in the field of environment and energy.

F[formula omitted] adsorption on penta-graphene: A first-principles study

We have studied the adsorption behavior of F2 on the new two-dimensional graphene-like carbon material penta-graphene (PG) via the first-principles calculations based on density functional theory. By calculating adsorption energy, adsorption distance, charge transfer and electron density, it is found that eight stable adsorption configurations can be formed. These adsorption configurations are divided into two different adsorption types: physical adsorption and chemical adsorption. Further, the analysis of the energy band, total density of states and partial density of states of these adsorption configurations proves that the strong interaction of F2 adsorbed on PG has obvious influence on the electronic properties of PG, which makes PG have the potential to become a very sensitive sensor to F2. In addition, our results provide a new direction to study the regulation of electronic properties of PG, which can improve the application prospect of PG in electronic devices and photocatalysis.

A green route to synthesize nitrogen-enriched graphene-like carbon nanosheets from bio-oil for supercapacitors

Two-dimensional carbon materials with the combined characteristics of high surface area, plentiful exposed active sites as well as short ion transport distance, have received great attention for fast charge storage. Herein, an environmentally-friendly method is proposed for the fabrication of nitrogen-enriched graphene-like carbon nanosheet (NCS) from bio-oil by using graphitic carbon nitride (g-C3N4) as a self-sacrificing template and nitrogen source. Notably, compared with our previous work, the obtained carbon material possesses higher nitrogen content (8.09 at.%). Meanwhile, the carbon nanosheets have a much thinner thickness (~2.8 nm), large size and high electrical conductivity (85 S m−1). Consequently, the energy density of the symmetric supercapacitor displays high energy density of 10.6 W h kg−1 at a power density of 131.1 W kg−1 in 1 M H2SO4. This study proposes an eco-friendly and low-cost route for the preparation of graphene-like carbon materials for high-performance supercapacitors.

Nitrogen-doped graphene-like carbon from bio-waste as efficient low-cost electrocatalyst for fuel cell application

The development of metal-free carbon-based catalysts for alkaline fuel cells has been the subject of current interest, because of the low cost and improving fuel cell efficiency. Particularly, nitrogen-doped carbon shows prominent results. Here, we show an oxygen reduction reaction (ORR) activity of nitrogen-doped graphene-like carbon materials (N-GLC) prepared by heating bagasse-derived carbon and melamine in a 1:15 ratio. The N-GLC catalyst displays excellent electro-catalytic activity towards the ORR with an onset potential of 0.92 V vs. reversible hydrogen electrode (RHE) in alkaline media (0.1 M KOH). Moreover, the half-wave (E1/2) potential 0.83 V is almost the same compared to Pt-C (40 wt%) catalyst and the diffusion limiting current of 4 mA cm–2. The rotating ring disc experiment showed a four-electron pathway (n = 3.65) with the moderate peroxide ( $${{\rm HO}}^{-}_{2}$$ ) yield. Due to its promising ORR activity and long-term electrochemical stability, N-GLC catalyst is used in alkaline anion exchange membrane fuel cell (AEMFC) as a single cell, about 6 mW cm–2 peak power density was achieved at the load current density of ~20 mA cm–2. So the N-GLC can be a cheap alternative ORR catalyst for AEMFC applications.

Construction of hierarchically porous 3D graphene-like carbon material by B, N co-doping for enhanced CO2 capture

A unique 3D B, N co-doped carbon nanomaterial (B/N-CNs) is fabricated by simply carbonizing a mixture of orthoboric acid, soy bean oil and melamine. The obtained B/N-CNs are composed of B, N co-doped graphene-like carbon nanosheets (BCN) and hexagonal boron nitride (h-BN) domains with hierarchically porous structure, including erythrocyte-shaped macropores, narrowed mesopores and numerous micropores. The B/N-CNs sample shows enhanced CO 2 selective capture ability compared with the one without B doping (N-CNs). The higher CO 2 uptake and CO 2 /N 2 capture selectivity of B/N-CNs can be contributed to abundant ultramicropores within hierarchically porous structure and the suitable electrostatic interaction between CO 2 and adsorption sites both on the BCN nanosheets and h -BN domains. • A 3D B, N co-doped carbon material is prepared by a one-step carbonization. • The obtained B/N-CNs has hierarchical porous structure with numerous micropores. • The B/N-CNs is composed of B, N conjugated carbon nanosheets and h -BN domains. • CO 2 adsorption performance is enhanced compared with the one without B doping. • The CO 2 adsorption enhancement mechanisms are proposed.

The removal mechanism of nitrobenzene by the Cu-Fe/Carbon material under different aeration conditions

Zero-valent Cu-Fe bimetallic porous carbon materials were successfully applied to remediate organic wastewater. In this work, we successfully recycled the layered double hydroxides (LDHs) adsorbed with Orange II (OII) to form a zero-valent Cu-Fe bimetallic porous carbon material (CuFe/Carbon). The characterization results showed that CuFe/Carbon was a zero-valent Cu-Fe bimetallic porous graphene-like carbon material. In the course of the experiment, we found that aeration condition had a great influence on the activity of CuFe/Carbon. The removal efficiency of nitrobenzene (NB) was 100 % in nitrogen system and 48 % in air system. The active species of O2− and OH was formed under air condition, while there was no active species under nitrogen condition. NB was reduced to aniline directly under nitrogen condition. We proposed there were reduction and oxidation mechanisms under different aeration conditions. This work mainly investigated the conversion process of a novel material under different reaction conditions, which provided theoretical support for the removal of organic matters.

Surface Morphology and Composition of a NbC/C Composite Studied by Scanning Electron Microscopy and X-Ray Photoelectron Spectroscopy

The surface morphology and composition of a NbC/C composite prepared via thermal decomposition of the products of reaction between NbCl5 and acetylene [9] have been studied by scanning electron microscopy and X-ray photoelectron spectroscopy. The results demonstrate that the NbC thus synthesized consists of nanocrystals. The surface layer of the NbC/C composite contains nine carbon atoms per Nb atom. The niobium is present in the form of the NbC carbide (33%) and the NbO2 (10%) and Nb2O5 (57%) oxides, with Nb 3d5/2 electron binding energies of 203.8, 205.0, and 207.2 eV, which are tentatively attributed to Nb2+ (NbC), Nb4+, and Nb5+ ions, respectively. The presence of NbO2 and Nb2O5 in the surface layer is due to active reaction of the NbC/C composite with atmospheric oxygen and moisture during the sample preparation process. Our results on the structure of the C1s electron spectra lead us to assume that the carbon on the surface of the composite particles has the form of a graphene-like carbon material. The composite does not become charged when exposed to an X-ray beam, which suggests that it is a weak dielectric.

Nitrogen-doped graphene-like carbon material derived via a simple, cost-effective method as an excellent adsorbent for methylene blue adsorption

Nitrogen-enriched graphene-like carbon materials were successfully prepared via pyrolysis of a mixture of melamine, ammonia chloride (NH4Cl) and polyvinyl pyrrolidone (PVP) at a mild temperature without inert gas protection. Different techniques were used to analyze the physical and chemical properties of the products. All the prepared materials showed excellent performance in methylene blue (MB) adsorption, In particular, the materials prepared with 3 g polyvinyl pyrrolidone (PVP) (NCG-2) exhibited the best performance, a very high maximum adsorption capacity of 348.2 mg/g, much larger than many reported materials. The high adsorption capacity of the Nitrogen-doped graphene-like carbon materials was possible due to its uniform porous structure, high specific surface area. Moreover, NCG-2 could be recycled and only a only slightly decreased in the removal efficiency were observed after 5 cycles.

High activity of NiCo2O4 promoted Pt on three-dimensional graphene-like carbon for glycerol electrooxidation in an alkaline medium.

Spinel oxide NiCo2O4 supported on a three-dimensional hierarchically porous graphene-like carbon (3D HPG) material has been firstly used to enhance the activity of Pt for glycerol electrooxidation. The addition of NiCo2O4 into the Pt/HPG catalyst can significantly improve the catalytic performance for glycerol oxidation. When NiCo2O4 is added to the Pt/HPG catalyst, the onset potential is 25 mV more negative than that on the Pt/HPG catalyst without NiCo2O4. The current density at −0.3 V on the Pt–NiCo2O4 (wt 10 : 1)/HPG electrode is 1.3 times higher than that on the Pt (30 wt%)/HPG electrode. The Pt–NiCo2O4 electrode presented in this work shows great potential as an electrocatalyst for glycerol electrooxidation in an alkaline medium.

Microstructure engineering towards porous carbon materials derived from one biowaste precursor for multiple energy storage applications

Microstructure regulation is of great significance to carbon based materials for desired applications in the fields of energy storage and conversion. Herein, we report the microstructure engineering towards porous carbon materials from the same precursor enabling multiple energy storage applications. Highly disordered carbon materials (HDCMs) and graphene-like carbon materials (GLCMs) can be obtained from one biomass waste of peanut dregs. Thanks to the ultrahigh surface area, relative narrow pore size, and disordered structure, the as-resulted HDCMs display high hydrogen uptake of 3.03%, and high specific capacitance of 449 F g−1 at a current density of 0.5 A g−1, outstanding rate capability as well as remarkable cycling performance. As anode materials for LIBs, the resultant GLCMs exhibit reversible capacity of 731 mAh g−1 at a current density of 100 mA g−1 and excellent cycling stability, owing to the high graphitization, lamellar structure, and dominant mesoporosity. These results demonstrate that this microstructural engineering approach is promising and efficient to design and controllable preparation of porous carbon materials for multiple desirable energy storage applications.

Pulsed Laser Deposited Nanoporous Carbon As a Lithium Ion Battery Anode

Lithium-ion batteries (LIBs) find applications ranging from portable electronics to electric vehicles, due to their higher energy densities (~ 250 Wh.hr kg-1) than other rechargeable batteries. Since the invention of LIBs, commercialized anodes have mostly consisted of carbon-based materials such as natural graphite, mesophase carbon microbeads (MCMB) massive artificial graphite (MAG), and hard carbons. However, the employment of LIBs in electric vehicles is increasing demand for higher energy density LIBs. Graphite-based anodes are limited to a charge storage capacity of 372 mAh g-1 due to the tight interplanar spacing (3.35 Å) between the graphene sheets. Several alternative anode materials have been proposed to replace graphite. In particular, Si and Sn alloys are extensively studied, but enormous volume change while cycling is hindering their commercialization. Lithium titianate (Li4Ti5O12) anodes are successfully commercialized, but low lithium storage capacity (175 mAh g-1) and high voltage (~1.5 V) prevents their use for high energy density applications. Carbon allotropes with modified structures and crystallinity can achieve higher capacity relative to graphite, so they are potential candidates to enable higher energy density LIBs. Carbon materials vary drastically in terms of interplanar spacing, termination groups on the edges of graphite/graphene fragments, defects, and porosity within the carbon structures. These variations significantly affect the Coulombic efficiency, lithium storage capacity, irreversible capacity loss during the first cycle, and the voltage range for lithiation. We will present an investigation of nanoporous carbon (NPC) prepared via pulsed laser deposition as a model system to understand lithiation mechanisms in carbon anodes. NPC is grown directly on stainless steel current collectors at room temperature, resulting in randomly-oriented stacks consisting of a few layers of aligned nm-sized graphene sheets. NPC mass density can be controlled from 2.0 g/cm3 to below 0.1 g/cm3 by varying the carbon deposition energetics, enabling the tuning of interplanar spacing and porosity within NPC. Low-density NPC exhibits as much as a 55% larger interplanar spacing compared to graphite-like high-density NPC and larger open pore spaces between stacks of sheets. The ability to control interplanar spacings and porosity in otherwise identical carbon samples allows for a systematic study to understand how these characteristics affect lithiation and de-lithiation processes in graphene-like carbon materials. We will discuss how the mass density of this 3D graphene-like NPC nanomaterial affects lithiation mechanisms and will demonstrate that NPC anode storage capacity systematically increases with decreasing mass density. High capacity is enabled by a plethora of grain boundaries, large and controlled interplanar spacings between graphene sheets, and nanopores between the randomly-aligned sheet fragments, all potentially contributing to extra lithium storage sites. The primary mechanisms for lithium storage in nanoporous carbon varies with mass density. For example, the capacity increases with cycling for the lowest mass density materials, potentially indicating that lithium plates within the nanopores as electrolyte penetrates deeper into the structure with each cycle. NPC mass density also correlates with Coulombic efficiency, such that lower density NPC demonstrates lower coulombic efficiency. This may be related to solid electrolyte interphase formation in the lower mass density samples since the electrolyte is more likely to penetrate into the structure and enable higher carbon-electrolyte interface surface areas. However, initial data suggests that lower Coulombic efficiency with lower mass density is likely related to the trapping of lithium ions at termination groups on the edges of graphene sheets. This trapping of lithium can be reversed by increasing the voltage during delithiation. Finally, we will also present data showing that NPC can be sodiated. Sodiation processes mimic those of lithiation, with sodium storage capacity increasing with decreasing NPC mass-density. We thank Lyle Brunke for assistance growing NPC films and Carlos Gutierrez for programmatic guidance. This work was supported by the Laboratory Directed Research and Development program at Sandia National Laboratories, a multimission laboratory managed and operated by National Technology and Engineering Solutions of Sandia, LLC., a wholly owned subsidiary of Honeywell International, Inc., for the U.S. Department of Energy's National Nuclear Security Administration under contract DE-NA-0003525. SAND2019-4730 A

Perfect negative differential resistance, spin-filter and spin-rectification transport behaviors in zigzag-edged δ-graphyne nanoribbon-based magnetic devices

Many layered graphene and graphene-like two-dimensional carbon materials have been successively proposed in theory and experiment owing to their exceptional properties and potential applications. By employing the first-principles study, we find that a new graphene-like material, δ-graphyne, whose properties of the zigzag-edged nanoribbon are very similar to those ones of zigzag-edged graphene case. The band structure clearly exhibits a metallic property in non-magnetic state. And we can see a visible spin splitting within the ferromagnetic state, however, spin degeneracy within the antiferromagnetic state. To this end, here we propose a molecular junction based on the zigzag-δ-graphyne nanoribbon symmetrically with additional phenyl rings at both edges. The computational results imply that the device has many good electron transport performances, such as negative differential resistance, spin-filtering and rectification effects, and so on. In particular, the spin-filtering efficiency can be up to 99%, and the maximum of the rectification ratio reaches up to 106%. The mechanisms for these effects are revealed and discussed in terms of the band structure, spin-resolved electron transmission spectrum, the local density of state and the transmission pathway. Therefore, our research results can provide a basis for the experimental preparation of the δ-graphyne-based junction.

Synthesis of porous graphene-like carbon materials for high-performance supercapacitors from petroleum pitch using nano-CaCO3 as a template

Porous graphene-like carbon materials (PGCMs) for supercapacitors were synthesized from petroleum pitch by a nano-CaCO3 template strategy combined with KOH activation. The PGCMs were characterized by TEM, XPS, Raman spectroscopy and N2 adsorption. Results show that their specific surface areas are 1542-2305 m2·g−1, depending on the template/pitch ratio, KOH/pitch ratio and activation temperature. The PGCMs feature interconnected graphene-like carbon layers with abundant small pores. The optimum supercapacitor electrode is produced when the PGCM is synthesized with a template/pitch ratio of 1.5, a KOH/pitch ratio of 1.5 at 850 °C for 1h. It has a specific capacitance of 293 F·g−1 at a current density of 0.05 A·g−1, an excellent rate capability with a capacitance of 231 F·g−1 at a current density of 20 A·g−1 and an outstanding cycling stability with a 97.4% capacitance retention after 7000 cycles in a 6 M KOH aqueous electrolyte. It also exhibits a high specific capacitance of 267 F·g−1 at a current density of 0.05 A·g−1, and a high energy density of 148.3 Wh·kg−1 at a power density of 204.2 W·kg−1 in a BMIMPF6 ionic liquid electrolyte. This is a possible method for the synthesis of PGCMs for high-performance supercapacitors.

Porous Carbon Nanosheets Prepared from Plastic Wastes for Supercapacitors

With the rise of living standards, non-biodegradable waste, especially waste plastics, has caused serious environmental problems. Herein, we prepare nitrogen doped porous carbon nanosheets (N-PCNs) using magnesium hydroxide [Mg(OH)2] sheets, which are modified by Zn and Co bimetallic zeolitic imidazolate framework nanoparticles as templates and polystyrene (PS) as a carbon precursor. During the high-temperature pyrolysis process, PS pyrolyzes into small organic molecule gases, which can be converted into graphene-like carbon material under the catalyst magnesia (MgO) and Co species. Nitrogen is introduced into the carbon material in situ by the pyrolysis of imidazole ligands, and the evaporation of Zn helps increase the surface area. The obtained N-PCNs with porous structure and large specific surface area can be used as electrode material for supercapacitors, exhibiting excellent capacitance of 149 F g−1 at the current density of 0.5 A g−1, an excellent cycling stability of 97.6% for up to 5000 cycles.