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| Author | : Ruben Heimböckel |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2019 |
| Genre | : |
| ISBN | : |
| Author | : Francesca Borghi |
| Publisher | : Springer Nature |
| Total Pages | : 187 |
| Release | : 2022-01-12 |
| Genre | : Technology & Engineering |
| ISBN | : 3030818276 |
This book provides an interesting snapshot of new research within the fields of flexible and soft devices which use porous carbon-based materials. The increase in demand for soft and flexible electronics, electrochemical energy storage/conversion systems, piezoresistive pressure sensors has promoted the development of new strategies for the synthesis and integration of nanoporous carbon (NPC) into flexible and soft polymers and inorganic textures. The structural properties of such NPC materials combined with their mechanical, conductive and catalytic properties, show promising results for the technology they are designed for, which can be useful solutions in many other disciplines. An in-depth discussion of the use of NPC materials in different energy devices is provided in every chapter, while at the same time the knowledge of the reader on the various applications where these materials can be used will be broadened. This book sheds new light on nanoporous carbon-based materials and will be of great interest to graduate students and professionals working in this field.
| Author | : Feiyu Kang |
| Publisher | : Elsevier |
| Total Pages | : 874 |
| Release | : 2021-11-04 |
| Genre | : Technology & Engineering |
| ISBN | : 0128221534 |
Carbon materials form pores ranging in size and morphology, from micropores of less than 1nm, to macropores of more than 50nm, and from channel-like spaces with homogenous diameters in carbon nanotubes, to round spaces in various fullerene cages, including irregularly-shaped pores in polycrystalline carbon materials. The large quantity and rapid rate of absorption of various molecules made possible by these attributes of carbon materials are now used in the storage of foreign atoms and ions for energy storage, conversion and adsorption, and for environmental remediation. Porous Carbons: Syntheses and Applications focuses on the fabrication and application of porous carbons. It considers fabrication at three scales: micropores, mesopores, and macropores. Carbon foams, sponges, and 3D-structured carbons are detailed. The title presents applications in four key areas: energy storage, energy conversion, energy adsorption, including batteries, supercapacitors, and fuel cells and environmental remediation, emphasizing the importance of pore structures at the three scales, and the diffusion and storage of various ions and molecules. The book presents a short history of each technique and material, and assesses advantages and disadvantages. This focused book provides researchers with a comprehensive understanding of both pioneering and current synthesis techniques for porous carbons, and their modern applications. Presents modern porous carbon synthesis techniques and modern applications of porous carbons Presents current research on porous carbons in energy storage, conversion and adsorption, and in environmental remediation Provides a history and assessment of both pioneering and current cutting-edge synthesis techniques and materials Covers a significant range of precursor materials, preparation techniques, and characteristics Considers the future development of porous carbons and their various potential applications
| Author | : Christian Mbaya Mani |
| Publisher | : |
| Total Pages | : |
| Release | : 2017 |
| Genre | : |
| ISBN | : |
Nanoporous carbon based materials are of particular interest for both science and industry due to their exceptional properties such as a large surface area, high pore volume, high electroconductivity as well as high chemical and thermal stability. Benefiting from these advantageous properties, nanoporous carbons proved to be useful in various energy and environment related applications including energy storage and conversion, catalysis, gas sorption and separation technologies. The synthesis of nanoporous carbons classically involves thermal carbonization of the carbon precursors (e.g. phenolic resins, polyacrylonitrile, poly(vinyl alcohol) etc.) followed by an activation step and/or it makes use of classical hard or soft templates to obtain well-defined porous structures. However, these synthesis strategies are complicated and costly; and make use of hazardous chemicals, hindering their application for large-scale production. Furthermore, control over the carbon materials properties is challenging owing to the relatively...
| Author | : Qiang Xu |
| Publisher | : CRC Press |
| Total Pages | : 384 |
| Release | : 2013-01-04 |
| Genre | : Science |
| ISBN | : 1439892075 |
In the past two decades, the field of nanoporous materials has undergone significant developments. As these materials possess high specific surface areas, well-defined pore sizes, and functional sites, they show a great diversity of applications such as molecular adsorption/storage and separation, sensing, catalysis, energy storage and conversion,
| Author | : Ram K. Gupta |
| Publisher | : Springer Nature |
| Total Pages | : 389 |
| Release | : |
| Genre | : |
| ISBN | : 9819999316 |
| Author | : Meng Zhou |
| Publisher | : |
| Total Pages | : 306 |
| Release | : 2016 |
| Genre | : |
| ISBN | : |
Electrical energy storage (EES) plays an important role in people's daily lives, with devices such as rechargeable batteries for cell phones, computers, and electric cars. Electrochemical, thermal, and mechanical storage systems are just a few of the many types of energy storage systems. In all these systems, a supercapacitor is critical for energy storage. Due to a supercapacitor's high power density, outstanding cycle stability, and long life span, it is widely used in memory backup, hybrid cars, electric vehicles and emergency systems; it plays an essential role to replace tradition fossil fuels in the car markets. Unlike lithium-ion batteries (Libs), the energy density of supercapacitor is very low (about 1/10 of Libs) which limits its applications greatly. How to increase the energy density of a super capacitor without altering beneficial properties is an essential topic in the energy community and attracts numerous attentions for decades. Energy density E= 1⁄2 CV2, C here is the specific capacitances, it mainly relies on the materials of the electrodes. Many types of electrode materials have been investigated for their ability to increase energy density, among these materials, carbonaceous materials (activated carbon, carbon nanotube, carbon cloth, graphene, graphite, reduces graphene oxide (rGO), carbon monolith and et al.) are used most commonly as electrodes or as a supporting matrix for metal compounds in electrodes. Due to the easy synthesis process, low cost, large surface area, easily controllable porosity and thermal and chemical stability, activated carbon (AC) is the most popular form of carbon electrode material. Besides, the source to get AC is very rich, it mainly can be derived from biomass and bio-waste. The nano-structures of carbon sources are inherited in the AC, such as layered structure, sponge-like structure and diamond structure. The reviews of different carbon as the electrode materials were given in Chapter 1. The carbon sources used in this research are algae and oil tea shells separately, with ZbCL2 as the activation agent. For algae-derived-carbon (ADC), a high capacitance (325 F/g @ 0.5A/g) and a large surface (>1500m2/g) were obtained. However, the rate capability is poor; we further study the storage mechanism by dividing the surface areas into micropore (2nm), mesopore (2 to 50nm) and macropores ( 50nm) areas. Generally, The contributions of micropores, mesopores and macropores to the capacitances are different, using the specific capacitances measured from the electrochemical tests, combing the data of surface areas and pore volumes obtained from the N2 adsorption and desorption data at 77K; the capacitance of each single nanopore is calculated, assuming the cylindrical structures of all the nanopores; the results are identical to the published works. Metal compounds especially for the transition metal oxides are other types of common electrode materials due to the high theoretical capacitances, revisable redox reactions happen during the charge and discharge cycles, which help to transfer/store more electrons than the carbon materials. However, the electrical conductivities and efficient active surface areas for redox reactions of metal oxides themselves are low, which reduce their performances in specific capacitance, rate capability and cycle stability. Normally, metal oxides need to combine with carbon materials, such as activated carbon, carbon nanotubes, graphene and et al. to improve the conductivities and expand the active surface areas. The ADC shows a sponge-like structure which is ideal to be used a scaffold to support the metal oxides. The activated carbon supported CoO was synthesized by treating algae with Co (OH)2, the assessed as an electrode material. It was observed that the capacitance, rate stability, and cycle stability were enhanced significantly, as compared to the pure CoO as the electrode materials applying this simple method, it is easy to scale up the productions from laboratory level to industry level. In chapter 2, we used ADCs to study the pore size and depth effects on capacitances, and further increased the capacitance significantly by the composite of CoO/ADC. AC is also obtained from the bio-waste oil tea shells, the characterizations show that a certain amount of graphitic structure carbons exist, and the BET surface area is up to 2800 m2/g, using the large surface; Mno2 particles in the solution were adsorbed to form a film-like coating on the surface, a specific capacitance of 1600F/g @ 0.5A/g is achieved. An asymmetric capacitor cell is set up (MnO2/AC//AC), an energy density 24Wh/kg @275W/kg was reached, which shows great enhancement according to the published works; the details were given in Chapter 3. Carbon nanotube (CNT) is another important material for application. It possesses high electron conductivity, high thermal conductivity, large tensile strength, huge current tolerance and flexibility. All these merits are based on the growth of CNTs; in Chapter 4, we discussed about the CNT growth by 26 factorial designs; the main factor was found. The obtained CNT arrays were further pulled in yarns and doped with Au particles, which enhance the electron conductivity greatly.
| Author | : Kuan Yew Cheong |
| Publisher | : Elsevier |
| Total Pages | : 506 |
| Release | : 2021-10-01 |
| Genre | : Technology & Engineering |
| ISBN | : 0128230703 |
Sustainable Materials and Green Processing for Energy Conversion provides a concise reference on green processing and synthesis of materials required for the next generation of devices used in renewable energy conversion and storage. The book covers the processing of bio-organic materials, environmentally-friendly organic and inorganic sources of materials, synthetic green chemistry, bioresorbable and transient properties of functional materials, and the concept of sustainable material design. The book features chapters by worldwide experts and is an important reference for students, researchers, and engineers interested in gaining extensive knowledge concerning green processing of sustainable, green functional materials for next generation energy devices. Additionally, functional materials used in energy devices must also be able to degrade and decompose with minimum energy after being disposed of at their end-of-life. Environmental pollution is one of the global crises that endangers the life cycles of living things. There are multiple root causes of this pollution, including industrialization that demands a huge supply of raw materials for the production of products related to meeting the demands of the Internet-of-Things. As a result, improvement of material and product life cycles by incorporation of green, sustainable principles is essential to address this challenging issue. Offers a resourceful reference for readers interested in green processing of environmentally-friendly and sustainable materials for energy conversion and storage devices Focuses on designing of materials through green-processing concepts Highlights challenges and opportunities in green processing of renewable materials for energy devices
| Author | : Saravanan Rajendran |
| Publisher | : Springer |
| Total Pages | : 297 |
| Release | : 2019-02-11 |
| Genre | : Science |
| ISBN | : 3030045005 |
This book describes the role and fundamental aspects of the diverse ranges of nanostructured materials for energy applications in a comprehensive manner. Advanced nanomaterial is an important and interdisciplinary field which includes science and technology. This work thus gives the reader an in depth analysis focussed on particular nanomaterials and systems applicable for technologies such as clean fuel, hydrogen generation, absorption and storage, supercapacitors, battery applications and more. Furthermore, it not only aims to exploit certain nanomaterials for technology transfer, but also exploits a wide knowledge on avenues such as biomass-derived nanomaterials, carbon dioxide conversions into renewable fuel chemicals using nanomaterials. These are the areas with lacunae that demand more research and application.
| Author | : O. Glatter |
| Publisher | : |
| Total Pages | : 540 |
| Release | : 1982 |
| Genre | : Science |
| ISBN | : |
