Preparation of N-doped porous carbon materials and their supercapacitator performance

Zong, Shuang

01 1900

Supercapacitor is the best potential candidate of the energy storage system due to the superior charge or discharge efficiency, high power density (>10 kW kg-1), and long cycling life. Porous carbon materials as the promising electrode material have been widely used in supercapacitor. In fact, conventional porous carbon supercapacitor electrodes cannot fulfil the growing demand of high energy and power densities of supercapacitor. A large number of studies show that nitrogen doping can change the surface electronic structure of carbon materials, thus significantly improving the electrochemical properties. In addition to, the pore structure and morphology of carbon materials have great influence on the electrochemical performance. In this work, we firstly fabricated nitrogen-doped porous carbon nanotubes by using a simple mixed salts (NaCl/ZnCl2) activation strategy. The as-obtained porous carbon nanotubes exhibited excellent electrochemical performance in supercapacitor. Furthermore, two- dimension nitrogen-doping porous nanosheets were prepared by a salt template-assisted monomer deposition method. In this study, by optimizing the synthesis conditions, the as-obtained carbon nanosheets showed a high specific capacitance of 277 F g-1 at 1 A g-1 and excellent cycle stability retained 91 % after 10,000 cycles. / College of Engineering, Science and Technology / M. Tech.( Civil and Chemical Engineering

Porous carbon materials

Nitrogen-doping

Molten activation

Salt template

Supercapacitator

620.116

Porous materials -- Electric properties

Electrochemistry

Block Copolymer Derived Porous Carbon Fiber for Energy and Environmental Science

Serrano, Joel Marcos

26 April 2022

As the world population grows, a persistent pressure on natural resources remains. Resource requirements have extensively expanded due to industrialization. Several technological advancements continually aim to alleviate these resource shortages by targeting existing shortcomings in effective and efficient material design. Practical, high-performing, and economical materials are needed in several key application areas, including energy storage, energy harvesting, electronics, catalysis, and water purification. Further development into high-performing and economical materials remain imperative. Innovators must seek to develop technologies that overcome fundamental limitations by designing materials and devices which address resource challenges. Carbon serves as a versatile material for a wide range of applications including purification, separation, and energy storage owing to excellent electrical, physical, and mechanical properties. One-dimensional (1D) carbon fiber in particular is renowned for excellent strength with high surface-to-volume ratio and is widely commercially available. Although an exceptional candidate to address current energy and environmental needs, carbon fibers require further investigation to be used to their full potential. Emerging strategies for carbon fiber design rely on developing facile synthetic routes for controlled carbon structures. The scientific community has shown extensive interest in porous carbon fabrication owing to the excellent performance enhancement in separation, filtration, energy storage, energy conversion, and several other applications. This dissertation both reviews and contributes to the recent works of porous carbon and their applications in energy and environmental sciences. The background section shows recent development in porous carbon and the processing methods under investigation and current synthetic methods for designing porous carbon fibers (PCF). Later sections focus on original research. A controlled radical polymerization method, reversible addition-fragmentation chain transfer (RAFT), enabled a synthetic design for a block copolymer precursor, poly(methyl methacrylate) (PMMA) and polyacrylonitrile (PAN). The block copolymer (PMMA-b-PAN) possesses a unique microphase separation when electrospun and develop narrowly disperse mesopores upon carbonization. The PMMA and PAN domains self-assemble in a kinetically trapped disordered network whereby PMMA decomposes and PAN cross-links into PCF. The initial investigation highlights the block copolymer molecular weight and compositional design control for tuning the physical and electrochemical properties of PCF. Based on this study, mesopore (2 – 50 nm) size can be tuned between 10 – 25 nm while maintaining large surface areas, and the PAN-derived micropores (< 2 nm). The mesopores and micropores both contribute to the development of the unique hierarchical porous carbon structure which brings unprecedented architectural control. The pore control greatly contributes to the carbon field as the nano-scale architecture significantly influences performance and functionality. The next section uses PCF to clean water sources that are often tainted with undesirable ions such as salts and pollutants. Deionization or electrosorption is an electrochemical method for water purification via ion removal. I employed the PCFs as an electrode for deionization because of their high surface area and tunable pore size. Important for deionization, the adsorption isotherms and kinetics highlight the capacity and speed for purification of water. I studied PCF capacitive filtration on charged organic salts. Because PCF have both micropores and mesopores, they were able to adsorb ions at masses exceeding their own weight. The PFC adsorption efficiency was attributed to the diffusion kinetics within the hierarchical porous system and the double layer capacitance development on the PCF surface. In addition, based on the mechanism of adsorption, the PCFs showed high stability and reusability for future adsorption/desorption applications. The PCF performance as an electrosorption material highlights the rational design for efficient electrodes by hierarchical interconnected porosity. Another application of PFCs is updating evaporative desalination methods for water purification. Currently distillation is not widely used as a source of potable water owing to the high cost and energy requirement. Solar desalination could serve as a low-cost method for desalination; however, the evaporation enthalpy of water severely limits practical implementation. Here I apply the pore design of PCF as a method for water nano-confinement. Confinement effects reduce water density and lowers evaporation enthalpy. Desalination in PCF were studied in pores < 2 nm to 22 nm. The PCF pore size of ~ 10 nm was found to be the peak efficiency and resulted in a ~ 46% reduction in enthalpy. Interestingly, the PCF nano-confinement also contributed to the understanding in competing desorption energy for evaporation in micropores. The pore design in PCF also shows confinement effects that can be implemented in other environmental applications. Lastly, the block copolymer microphase morphology was explored in a vapor induced phase separation system. The resulting PCF properties showed a direct influence from the phase separation caused by nonsolvent. At low nonsolvent vapor, a disordered microphase separation occurred, however upon application of nonsolvent vapor, the polymer chains reorganized. The reorganization initially improved mechanical properties by developing more long-range ordered graphic chains in the PAN-derived carbon. However, at higher nonsolvent vapor concentrations, the fibers experienced polymer precipitation which resulted in bead and clump formation in the fiber mats. The beads and clumps lowered both mechanical properties and electrochemical performance. The vapor induced phase separation showed a method for enhancing mechanical properties without compromising electrochemical performance in flexible carbon fibers. / Doctor of Philosophy / Nanomaterials possess mechanical, physical, and electrical properties to address important growing demands for precious resources such as clean water and energy. Many advancements in nanomaterials focus on improving fine-tune architectures which facilitate efficiency in composites, filtration systems, catalytic systems, energy storage devices, and electronics. Carbon material has remained a valuable candidate in these fields owing to its abundancy economical cost, and excellent properties. Several carbon forms provide unique characteristics including 0D dots, 1D fibers, 2D sheets, and 3D monoliths. Of these, 1D fibers possess excellent strength, resiliency, and conductivity and have been commercially employed in modern automotive, airplanes, membranes, and conductors. However, traditional carbon fiber fabrication does not match the growing needs in performance. Therefore, in this dissertation I explore the design and processing of carbon fibers for controlled architectures. These designs were then systematically studied in filtration systems, solar desalination, and flexible electronics. Block copolymers provide a new way to combine polymers for drastically new materials and effects. Firstly, I conducted a comprehensive study on the synthesis and composition of this block copolymer which laid the foundation for future carbon fiber design. The polymer consists of two chains – one chain to develop carbon structures upon heating; the second which decomposes into pores upon heating. Therefore, with these two chains, a highly porous carbon fiber can be created. The reaction I studied could mostly be controlled with time to change the length of each chain. Ultimately, the pore size and surface area depend on the relative lengths of each chain. Future studies, including ones in this work, could therefore tune pore size and surface area for many applications. Carbon fibers with graphitic structure are inherently conductive and thereby attract charged molecules in a solution. Diffusion and capacity serve as major factors in these types of systems. With the aforementioned control of the carbon fibers a diffusion study was conducted with charged pollution ions. Owing to the conductive nature, a voltage supply was attached to the fibers, which would adsorb ions electrostatically, termed "electrosorption". The electrosorption performance within the carbon fibers elucidated the interconnected porous structure and how ions orientate themselves along the surface of the fibers. In addition, with the development of ion orientation along the surface of the fibers, a greater than 1:1 ratio of carbon weight to ion weight adsorbed developed owing to the diffusion and ion stacking capabilities. Additionally, the study provides deeper investigation into movement of ions within confined nano-porous material. The ever-growing need for renewable resources such as fresh water has pressured development into more efficient material. Solar desalination has attractive qualities which makes it a focus for micro-scale studies. One of the major limitations lies in the high energy input change liquid water into vapor. At 100 °C for boiling, desalination lacks sufficient efficiency for large-scale applications in evaporation. However, by utilizing nano-scale material, the fundamental properties of water can be altered. The carbon fibers were then created with various nano-pore sizes which revealed nano-confinement effects when subject to solar heating. With the shrinking of pore sizes, the density of water also decreased. A lower density means less energy was required to convert water from a liquid to a vapor state. The carbon fibers helped reveal real applications into confinement effects on water based on pore size. Apart from just desalination, this means future environmental application can utilize this knowledge for more effective and smart designs. The carbon fibers outstanding electrical and mechanical properties have spurred research and development since the mid-1900s. Since then, carbon fiber technologies have grown from facile and efficient productions means, to high end, high performance smart design. The work presented here furthers two major components: first, the high-performance design of porous carbon fiber; second, the fundamental principles in nano-material properties and their applications. By first constructing a design of polymer synthesis and then subsequent studies, development of nano-porous carbon energy progresses knowledge on smart and efficient designs. These materials provide a platform for future energy and environmental sciences.

Porous carbon

block copolymer

electrospinning

RAFT polymerization

supercapacitors

deionization

solar desalination

flexible electronics

Polynuclear complexes as precursor templates for hierarchical microporous graphitic carbon: An unusual approach

Kobielska, Paulina A., Telford, Richard, Rowlandson, J., Tian, M., Shahin, Z., Demessence, A., Ting, V.P., Nayak, Sanjit

17 July 2018

Yes / A highly porous carbon was synthesized using a coordination complex as an unusual precursor. During controlled pyrolysis, a trinuclear copper complex, [CuII3Cl4(H2L)2]·CH3OH, undergoes phase changes with melt and expulsion of different gases to produce a unique morphology of copper-doped carbon which, upon acid treatment, produces highly porous graphitic carbon with a surface area of 857 m2 g–1 and a gravimetric hydrogen uptake of 1.1 wt % at 0.5 bar pressure at 77 K. / EPSRC (EP/R01650X/1 for VPT, and EP/E040071/1 for MT) and the University of Bristol

Complex-derived carbon

Coordination complex

Graphitic carbon

Hydrogen storage

Polynuclear complex

Porous carbon

Template precursor

Synthese von porösen Kohlenstoffmaterialien aus Polysilsesquioxanen für die Anwendung in elektrochemischen Doppelschichtkondensatoren

Meier, Andreas

18 February 2015

Elektrochemische Doppelschichtkondensatoren (engl. Electrochemical Double-Layer Capacitors, EDLCs) stellen eine zunehmend wichtige Technologie auf dem Markt der elektrischen Energiespeicher dar. Sie zeichnen sich durch die Aufnahmefähigkeit großer Energiemengen, eine hohe Langzeitstabilität und ein schnelles Ansprechverhalten aus. Diese Eigenschaften sind Gründe, weshalb EDLCs als Speicherbausteine für Energierück-gewinnungssysteme oder zur Stabilisierung der Stromversorgung in diversen elektronischen Bauelementen eingesetzt werden. Die Aufnahme der Energie erfolgt über Ladungsseparation von Elektrolytionen an der Elektrodenoberfläche. Die Kapazität der Speicherfähigkeit wird dabei maßgeblich vom Betrag der Elektrodenoberfläche und dem Abstand der Elektrolytionen zur Oberfläche der Elektrode bestimmt (bei gleichbleibendem Elektrolyten). In der gegenwärtigen Forschung werden neue Elektrodenmaterialien entwickelt, um über deren Systemeigenschaften, wie Leitfähigkeit und Porosität, die Leistungsfähigkeit der Doppelschichtkondensatoren weiter zu optimieren. Gängige Komponenten für Elektroden in diesen Bauelementen stellen Kohlenstoffmaterialien dar, da diese chemisch inert und zumeist kostengünstig in der Produktion sind. In der vorliegenden Arbeit sollte die Eignung der Materialklasse der Siliziumoxykarbid-abgeleiteten Kohlenstoffe (engl. Silicon Oxycarbide-Derived Carbons, SiOCDCs) für die Anwendung in elektrochemischen Doppelschichtkondensatoren untersucht werden. Die SiOCDCs wurden über die Pyrolyse (700 – 1500 °C) und Chlorierung (700 – 1000 °C) eines kohlenstoffreichen Polysilsesquioxans mit der theoretischen Zusammensetzung C6H5SiO3/2 erzeugt. Dabei zeigte sich, dass sowohl die porösen Eigenschaften als auch die Leitfähigkeit innerhalb der erhaltenen Kohlenstoffmaterialien stark von der Synthesetemperatur abhängen. Somit konnten reine Kohlenstoffe mit spezifischen Oberflächen bis zu 2400 m2 g-1 und Porenvolumina von 1,9 cm3 g-1 synthetisiert werden. Im Verlauf der Arbeit wurde eine geeignete Methode zur Verarbeitung der erzeugten Oxykarbid-abgeleiteten Kohlenstoffe zu Elektroden evaluiert, um eine elektrochemische Charakterisierung vorzunehmen. Ein vielversprechender Ansatz stellt die vollkommen trockene Umsetzung der SiOCDCs zu freistehenden Elektrodenschichten dar. Dieses Verfahren nutzt die Verreibung der Aktivkomponente mit einem geringen Anteil (5 Gew.-%) eines Bindemittels (Polytetrafluorethylen, PTFE) aus, um flexible und selbsttragende Elektrodenfolien zu erzeugen. Die Vorteile dieses Prozesses gegenüber anderen Verarbeitungsarten liegen darin, dass aufwendige Trocknungsverfahren während der Elektrodenherstellung entfallen und die Schichtdicken der resultierenden Folien unmittelbar eingestellt werden können. Während der Untersuchung der unterschiedlichen Elektrodensysteme im organischen Elektrolyten (1 M Tetraethylammoniumtetrafluoroborat-Lösung in Acetonitril) konnten spezifische Kapazitäten von bis zu 120 F g-1 gemessen werden. Des Weiteren zeigte sich der Einfluss der Kohlenstoffstruktur innerhalb der Aktivmaterialien auf die elektrochemischen Resultate. So konnte festgestellt werden, dass eine zunehmende Graphitisierung im Kohlenstoff, welche mit einer steigenden Mesoporosität im SiOCDC einherging, zu einer verbesserten Leitfähigkeit innerhalb der EDLC-Elektroden führte, aber auch eine Verringerung der spezifischen Kapazität bedeutete. Die Verringerung der Widerstände im System weitete erheblich den Bereich der nutzbaren Arbeitsfrequenzen und die Strombelastbarkeit des Elektrodenmaterials aus. So bestand die Möglichkeit ein mesoporöses Kohlenstoffmaterial zu synthetisieren, welches mit einer maximalen Arbeitsfrequenz von 8 Hz einen Wert zeigte, der zwei Größenordnungen über der Arbeitsfrequenz eines kommerziell erhältlichen Standards (Aktivkohle YP-50F) lag. Dieses exzellente Ansprechverhalten bildet die Grundlage für den Einsatz in Hochleistungsspeichersystemen. Des Weiteren offenbarte sich, dass die trocken prozessierten Elektroden das Potential für eine hohe Langzeitstabilität besitzen, da je nach Elektrodensystem ein Erhalt von 94% der Ursprungskapazität über 10.000 Lade-/Entladezyklen beobachtet werden konnte. Die Modifikation der Elektrodenmaterialien mittels CO2-Aktivierung und eine damit verbundene Erhöhung der spezifischen Oberfläche führten zu einer Verbesserung der spezifischen Kapazität der Aktivkomponenten um bis zu 33%. Zusammenfassend bleibt zu erwähnen, dass poröse Oxykarbid-abgeleitete Kohlenstoffe erfolgreich über die Chlorierung von keramischen Vorläuferverbindungen synthetisiert werden konnten. Die Kohlenstoffmaterialien zeigten nach der Prozessierung zu freistehenden und flexiblen Elektrodenfilmen vielversprechende Eigenschaften bei der Nutzung in elektrochemischen Doppelschichtkondensatoren, wie hohe spezifische Kapazitäten, gute Langzeitstabilitäten und hohe Arbeitsfrequenzen bei Lade- und Entladevorgängen.

Polysilsesquioxan

Siliziumoxykarbid

poröser Kohlenstoff

electrochemical double-layer capacitor

polysilsesquioxane

silicon oxycarbide

porous carbon

ddc:540

rvk:VN 6057

Tailoring porosity in carbon materials for supercapacitor applications

Borchardt, L., Oschatz, M., Kaskel, S.

02 December 2019

Within the different available electrochemical energy storage systems, supercapacitors stand out due to their high power densities and ultra-long cycle life. Their key-components are the electrode materials where the charge accumulation takes place and therefore many different approaches for the synthesis of carbonaceous electrode structures with well-defined pore systems are available. This review focuses on different strategies for tailoring porous carbon materials from the micropore level, over mesopores to macropores and even external or inter-particular porosity. A wide range of materials such as activated carbons, templated carbons, carbide-derived carbons, carbon nanotubes, carbon aerogels, carbon onions, graphenes and carbon nanofibers are presented, always in relation to their pore structure and potential use in supercapacitor devices.

info:eu-repo/classification/ddc/540

ddc:540

Tailoring of carbon materials for their use as electrodes in electrochemical capacitors

Salinas-Torres, David

02 December 2014

No description available.

Activated carbon fibres

Polyaniline

Asymmetric hybrid capacitor

Electrochemistry

Hierarchical porous carbon

Hydrothermal carbonization

Química Inorgánica

Química Física

Resin and carbon foam production by cationic step-growth polymerization of organic carbonates

Wöckel, L., Seifert, A., Mende, C., Roth-Panke, I., Kroll, L., Spange, S.

06 March 2017

Acid induced step-growth polymerizations of bis(p-methoxybenzyl) carbonate (pMBC), bis(m-methoxybenzyl) carbonate (mMBC) and difurfuryl carbonate (DFC) have been performed to produce resin-foams, because controlled release of carbon dioxide takes place during polymerization of those organic carbonates. The monomers are polymerized in bulk using p-toluene sulfonic acid (pTS) as a catalyst. The volume development of the foams is assisted by use of an appropriate surfactant and the crosslinking agent 1,3,5-trioxane as co-components. A portion of carbon dioxide release is a function of the carbenium stability of the reactive intermediate derived from the monomer; DFC > pMBC ≫ mMBC. Resins derived from mMBC can be post-treated to release carbon dioxide after polymerization. The molecular structures of the resulting materials are investigated by solid state 13C-NMR spectroscopy and IR spectroscopy. Scanning electron microscopy was used to study foam morphology. The carbon dioxide release was monitored with TG-MS analysis. Finally, the polymer foams have been converted into carbon foams and investigated by means of mercury porosimetry. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Carbonate

Schäume

kationische Stufenwachstumspolymrisation

Anisolharze

poröse Kohlenstoffe

Carbonates

foams

cationic step-growth polymerization

anisolic resins

porous carbon

ddc:540

Carbonate

Schaum

Polymerisation

Kohlenstoff

High-defect hydrophilic carbon cuboids anchored with Co/CoO nanoparticles as highly efficient and ultra-stable lithium-ion battery anodes

Sun, Xiaolei, Hao, Guang-Ping, Lu, Xueyi, Xi, Lixia, Liu, Bo, Si, Wenping, Ma, Chuansheng, Liu, Qiming, Zhang, Qiang, Kaskel, Stefan, Schmidt, Oliver G.

06 April 2017

We propose an effective strategy to engineer a unique kind of porous carbon cuboid with tightly anchored cobalt/cobalt oxide nanoparticles (PCC–CoOx) that exhibit outstanding electrochemical performance for many key aspects of lithium-ion battery electrodes. The host carbon cuboid features an ultra-polar surface reflected by its high hydrophilicity and rich surface defects due to high heteroatom doping (N-/O-doping both higher than 10 atom%) as well as hierarchical pore systems. We loaded the porous carbon cuboid with cobalt/cobalt oxide nanoparticles through an impregnation process followed by calcination treatment. The resulting PCC–CoOx anode exhibits superior rate capability (195 mA h g−1 at 20 A g−1) and excellent cycling stability (580 mA h g−1 after 2000 cycles at 1 A g−1 with only 0.0067% capacity loss per cycle). Impressively, even after an ultra-long cycle life exceeding 10 000 cycles at 5 A g−1, the battery can recover to 1050 mA h g−1 at 0.1 A g−1, perhaps the best performance demonstrated so far for lithium storage in cobalt oxide-based electrodes. This study provides a new perspective to engineer long-life, high-power metal oxide-based electrodes for lithium-ion batteries through controlling the surface chemistry of carbon host materials.

poröser Kohlenstoff-Quader

Imprägnierungsverfahren

Kalzinierungsbehandlung

Oberflächenchemie

Chemie

porous carbon cuboid

impregnation process

calcination treatment

surface chemistry

chemistry

ddc:540

rvk:VA 1120

Synthèse directe et par nanomoulage de carbones à nanoporosité contrôlée / Obtention of carbon materials with controlled nanoporosity by direct synthesis and nanocasting technique

Boisgontier, Claire

26 November 2009

L'objectif de ce travail est de développer de nouveaux matériaux carbonés dont la structure poreuse est contrôlée en taille et en morphologie dès l'étape de synthèse. Nous nous sommes tout d'abord intéressés à la technique de nanomoulage. Nous avons, tout d'abord, cherché à optimiser les conditions de synthèse de la réplique carbonée de la zéolithe EMC-2 (EMT) qui a l'avantage de conduire à un diagramme de diffraction bien résolu. Ensuite, différentes zéolithes ont été utilisées comme moule en s'appuyant sur les conditions optimales définies par la première étude. Dans un troisième temps, nous avons étudié la capacité d'adsorption et de séparation de gaz à température ambiante de la réplique carbonée de la zéolithe Y (FAU). L'inconvénient de cette technique est qu'elle est multi-étapes et de grandes quantités ne peuvent être obtenues. Aussi, nous avons cherché à développer d'autres méthodes d'obtention de carbones poreux. Nous nous sommes alors intéressés à la synthèse basée sur l'auto-assemblage entre un tensioactif structurant et un polymère précurseur de carbone. Nous avons cherché à comprendre le mécanisme de formation de ces matériaux et l'influence des différents paramètres de synthèse. Ce type de synthèse permet également l'obtention de composites silice/carbone mésoporeux lorsqu'un précurseur silicique est ajouté au milieu de synthèse. En outre, nous avons étudié la synthèse et la caractérisation de composites obtenus par « tapissage » des pores d'un matériau silicique par une couche de carbone. Les matériaux obtenus présenteraient alors des pores de plus petits diamètres dont la surface aurait des caractéristiques proches de celles de matériaux carbonés. / The aim of this work is to develop new carbon materials with controlled pore structure and to control the size and the morphology of pore structure during the synthesis step. First we interested to the nanocasting technique and to optimise the synthesis conditions in order to obtain the carbon replica of zeolite EMC-2 (EMT). The use of this zeolite allow to obtain well resolved X-ray diffraction pattern. Then carbon replicas have been obtained by using various zeolites as mould and the optimal conditions defined during the first study. The adsorption and separation capacities of carbon replica of zeolite Y (FAU) have been studied. But this technique is multi-step and it is not possible to obtain large quantities. Also other methods in order to obtain porous carbons have been developped. We interested to the synthesis by self-assembly between surfactant as structuring agent and polymer as carbon precursor. We tried to understand the formation mechanism and the inflence of synthesis parameters. Theses types of synthesis allows to obtain mesoporous silica/carbon composite if silicic precursor is added. Moreover, we studied the synthesis and the characterization of carbon-coated porous silica. The obtained materials have pores with smaller diameters but their surfaces have the same characterics than carbon materials.

Nanomoulage

Carbone poreux

Contrôle de la porosité

Synthèse directe

Mécanisme

Composite silice/carbone

Mésostructuration

Nanocasting

Porous carbon

Porosity control

Direct synthesis

Mechanism

Silica / carbon composite

Mesostructure

An interfacial engineering approach towards two-dimensional porous carbon hybrids for high performance energy storage and conversion

Lu, Chenbao, Liu, Shaohua, Zhang, Fan, Su, Yuezeng, Zou, Xiaoxin, Shi, Zhan, Li, Guodong, Zhuang, Xiaodong

17 July 2017

In order to improve the performance and fundamental understanding of conducting polymers, development of new nanotechnologies for engineering aggregated states and morphologies is one of the central focuses for conducting polymers. In this work, we demonstrated an interfacial engineering method for the rational synthesis of a two-dimensional (2D) polyaniline (PANI) nano-array and its corresponding nitrogen-doped porous carbon nanosheets. Not only was it easy to produce a sandwich-like 2D morphology, but also the thickness, anchored ions and produced various metal phosphides were easily and rationally engineered by controlling the composition of the aqueous layer. The novel structural features of these hybrids enabled outstanding electrochemical capacitor performance. The specific capacitance of the as-produced diiron phosphide embedded nitrogen-doped porous carbon nanosheets was calculated to be as high as 1098 F g−1 at 1 A g−1 and an extremely high specific capacitance of 611 F g−1 at 10 A g−1, outperforming state-of-the-art performance among porous carbon and metal-phosphide-based supercapacitors. We believe that this interfacial approach can be extended to the controllable synthesis of various 2D material coupled sandwich-like hybrid materials with potential applications in a wide range of areas.

Leitende Polymere

neue Nanotechnologien

kontrollierbare Synthese

conducting polymers

new nanotechnologies

controllable synthesis

ddc:540

rvk:VA 1120