Download or read book Development of Electronic Structure and Kinetics Methods for the Rational Design of Electrocatalysts written by Nathan Darrell Peterson Ricke and published by . This book was released on 2019 with total page 87 pages. Available in PDF, EPUB and Kindle. Book excerpt: Computational modeling has untapped potential for novel material and chemical discovery. In this thesis, we explore ways to improve existing modeling methods, and how to apply these methods to design novel graphite-conjugated catalysts (GCCs). For improving electronic structure methods, we first present an extended study of bootstrap embedding theory (BET) and its ability to recover static correlation, as well as a proof on BET's ideal convergence properties. We then present a theoretical analysis using density functional theory (DFT) on a class of GCCs containing cationic nitrogen atoms, which are particularly active for catalyzing the oxygen reduction reaction (ORR). Using a mixture of high-throughput screening, statistical analysis, and computational exploration guided by chemical intuition, we design several novel GCCs, several of which DFT predicts would have enhanced activity above existing GCCs. Furthermore, our analysis reveals that known ORR scaling relations hold for GCCs, but hint at the possibility of breaking these relations with careful molecular engineering of the GCC active sites.

Download or read book Rational Design Strategies for Oxide Oxygen Evolution Electrocatalysts written by Wesley Terrence Hong and published by . This book was released on 2016 with total page 160 pages. Available in PDF, EPUB and Kindle. Book excerpt: Understanding and mastering the kinetics of oxygen electrocatalysis is instrumental to enabling solar fuels, fuel cells, electrolyzers, and metal-air batteries. Non-precious transition metal oxides show promise as cost-effective materials in such devices. Leveraging the wealth of solid-state physics understanding developed for this class of materials in the past few decades, new theories and strategies can be explored for designing optimal catalysts. This work presents a framework for the rational design of transition-metal perovskite oxide catalysts that can accelerate the development of highly active catalysts for more efficient energy storage and conversion systems. We describe a method for the synthesis of X-ray emission, absorption, and photoelectron spectroscopy data to experimentally determine the electronic structure of oxides on an absolute energy scale, as well as extract key electronic parameters associated with the material. Using this approach, we show that the charge-transfer energy - a parameter that captures the energy configuration of oxygen and transition-metal valence electrons - is a central descriptor capable of modifying both the oxygen evolution kinetics and mechanism. Its role in determining the absolute band energies of a catalyst can rationalize the differences in the electron-transfer and proton-transfer kinetics across oxide chemistries. Furthermore, we corroborate that the charge-transfer energy is one of the most influential parameters on the oxygen evolution reaction through a statistical analysis of a multitude of structure-activity relationships. The quantitative models generated by this analysis can then be used to rapidly screen oxide materials across a wide chemical space for highthroughput materials discovery.

Download or read book The Rational Design of Selective Electrocatalysts for Renewable Energy Devices written by Daniel F. Abbott and published by . This book was released on 2015 with total page 153 pages. Available in PDF, EPUB and Kindle. Book excerpt: The rational design of electrocatalysts is paramount to the development of electrochemical devices. In particular, modifications to the structure and electronic properties of a particular catalyst can have a strong influence on the activity and selectivity towards various electrochemical reactions or pathways. In many cases this can lead to a particular reaction pathway being opened or closed, the formation of intermediates being stabilized or inhibited, the adsorption of poisonous species being mitigated, or the removal of poisonous species being promoted. In the this dissertation the design and characterization of catalysts for electrochemical devices (fuel cells, electrolyzers, and hydrogen pumps) will be discussed with regards to tailoring the selectivity in order to promote or inhibit certain electrochemical reactions. The electrochemical reactions of primary interest will include the methanol oxidation reaction (MOR), the oxygen reduction reaction (ORR), oxygen evolution reaction (OER), and hydrogen oxidation reaction (HOR).

Download or read book Catalysis in Electrochemistry written by Elizabeth Santos and published by John Wiley & Sons. This book was released on 2011-07-26 with total page 548 pages. Available in PDF, EPUB and Kindle. Book excerpt: Catalysis in Electrochemistry: From Fundamental Aspects to Strategies for Fuel Cell Development is a modern, comprehensive reference work on catalysis in electrochemistry, including principles, methods, strategies, and applications. It points out differences between catalysis at gas/surfaces and electrochemical interfaces, along with the future possibilities and impact of electrochemical science on energy problems. This book contributes both to fundamental science; experience in the design, preparation, and characterization of electrocatalytic materials; and the industrial application of electrocatalytic materials for electrochemical reactions. This is an essential resource for scientists globally in academia, industry, and government institutions.

Download or read book Methods for Electrocatalysis written by Inamuddin and published by Springer Nature. This book was released on 2020-01-02 with total page 469 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book explores key parameters, properties and fundamental concepts of electrocatalysis. It also discusses the engineering strategies, current applications in fuel-cells, water-splitting, metal-ion batteries, and fuel generation. This book elucidates entire category viewpoints together with industrial applications. Therefore, all the sections of this book emphasize the recent advances of different types of electrocatalysts, current challenges, and state-of-the-art studies through detailed reviews. This book is the result of commitments by numerous experts in the field from various backgrounds and expertise and appeals to industrialists, researchers, scientists and in addition understudies from various teaches.

Download or read book Rational Design of Electrocatalysts with Enhanced Catalytic Performance in Energy Conversion written by Changlin Zhang and published by . This book was released on 2016 with total page 237 pages. Available in PDF, EPUB and Kindle. Book excerpt: To provide alternative electrocatalysts for energy conversion and storage applications, the catalysts development including materials design, synthesis and growth mechanism, electrochemical diagnose, and reaction mechanism have been investigated and analyzed. Based on the research results in this dissertation, 8 first-authored journal papers have been published/submitted or in preparation. The research results here demonstrate a generic solid-state chemistry method for mass production of platinum group metal/alloy nanoparticles with size/shape/composition control, which could be used in multiple applications such as ammonia electro oxidation, oxygen reduction reaction, hydrazine decomposition, and carbon monoxide preferential oxidations. A highly ordered mesoporous carbon-based nanostructures as non-noble metal catalysts were also studied for oxygen reduction reaction and water splitting. To better understand the surface and interface behavior of platinum alloy catalyst under realistic reaction conditions, in-situ transmission electron microscopy was applied to dynamically investigate the real-time structure evolutions. The findings here also provide insights for establishing realistic structures-properties-applications relationships for materials science, catalysis and electrochemistry.

Download or read book Synthesis and Electrocatalytic Properties of Structure Engineered First row Transition Metal Derivatives written by Xiaodong Yan and published by . This book was released on 2018 with total page 20 pages. Available in PDF, EPUB and Kindle. Book excerpt: Hydrogen is a green energy carrier, producing only water when combusted, and a hydrogen economy has been considered the ideal green economy for human society. Water electrolysis can produce high-purity hydrogen on a large scale, and if the electricity used in water electrolysis is obtained from renewable energy, a sustainable energy chain can be achieved. Fuel cell technology offers a highly efficient way of converting chemical energy from a fuel into electricity through an electrochemical reaction. Fuel cells are expected to be one of the mainstream energy conversion devices for many applications such as the transportation and portable electronic systems. Hydrogen fuel cell technology is, of course, the ideal choice. However, the hydrogen storage is still a big challenge due to its gaseous nature, extremely low boiling point, and high inflammability. While advanced hydrogen storage technology is under development, fuel cells using liquid fuels (e.g. hydrazine) need to be developed. The key to both water electrolysis and fuel cells is the electrocatalyst. Currently, the noble metal based materials are still the state-of-the-art electrocatalysts for water electrolysis and in fuel cells in terms of catalytic activity and catalyst durability. However, their scarcity and high price hinder their widespread commercial use. Therefore, it is imperative to develop earth-abundant, low-cost electrocatalyst materials that have high catalytic activity comparable to or even better than the noble metal based electrocatalysts. Nowadays, the research emphasis of earth-abundant electrocatalysts is thus primarily placed on enhancing the catalytic activity or lowering the overpotential that is needed to drive the electrochemical reactions. The catalytic performance of an electrocatalyst is associated with its surface area, near-surface structure, electronic structure, conductivity, crystal size, etc. Rational structural modification of the electrocatalyst materials and/or architectural design of the catalyst electrodes can help enlarge the surface area, increase the active sites, tune the electronic structure and conductivity, and so on. In this dissertation, a series of strategies (e.g. hydrogenation, solvothermal reduction, and electrochemical tuning) have been developed to fabricate structure-tuned electrocatalyst materials for electrochemical water splitting and electro-oxidation of hydrazine. Well-defined Co/Co3O4 and Co/CoO core-shell heterostructures have been found to be highly active towards hydrogen evolution reaction (HER) and hydrazine oxidation, respectively. FeNi3/NiFeOx nanohybrids have been thoroughly characterized for HER and oxygen evolution reaction (OER). Nano-on-micro Cu has been explored as a highly efficient catalyst towards electro-oxidation of hydrazine. Cobalt hydroxide carbonate with rich grain boundaries has been shown to be a highly efficient non-metallic electrocatalyst towards hydrazine oxidation.

Download or read book Computational Electrochemistry written by S. Paddison and published by The Electrochemical Society. This book was released on 2015-12-28 with total page 49 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book Rational Design of Transition Metal Nitrogen Carbon Electrocatalysts for Oxygen Reduction Reaction written by Zhuang Liu and published by . This book was released on 2018 with total page 172 pages. Available in PDF, EPUB and Kindle. Book excerpt: ABSTRACT OF THE DISSERTATION Rational Design of Transition Metal-Nitrogen-Carbon Electrocatalysts for Oxygen Reduction Reaction by Zhuang Liu Doctor of Philosophy in Chemical Engineering University of California, Los Angeles, 2018 Professor Yunfeng Lu, Chair The harvest and conversion of energy is of crucial importance for human civilization. Today, the fast growth in energy consumption, together with the environmental problems caused by fossil fuel usage, calls for renewable and clean energy supply, such as solar, wind, geothermal, and tidal energy. However, such energies are not consistent in both time and location, bringing energy storage on request. Intensive research has been focused on the development of electrochemical energy storage (EES) devices. Among these EES devices, hydrogen fuel cells and metal-air batteries have attracted the special attention because of their high theoretical energy densities. Yet, one major issue lies in the sluggish oxygen reduction reaction (ORR) that takes place at the cathodes. For example, the theoretical voltage of a hydrogen-oxygen fuel cell is 1.23 V (standard condition). However, the voltage output obtained under a meaningful current density is only about 0.7 V, where the voltage loss is primarily caused by the overpotential in the cathodes. Developing efficient electro-catalysts, which can lower the overpotential of ORR, is indispensable for achieving high performance devices. The state-of-the-art ORR electro-catalysts are generally based on platinum, which is limited by cost and scarcity. Developing electro-catalysts based on earth abundant metal elements is critical for large-scale application of fuel cells and metal-air batteries. Among the non-precious-metal catalysts (NPMCs) explored in recent decades, pyrolyzed iron-nitrogen-carbon (Fe-N-C) catalysts is widely regarded as the most promising candidate for replacing platinum due to their high activity. However, the traditional method for preparing Fe-N-C catalysts involves high-temperature pyrolysis of the precursors, which is a highly complex and unpredictable process. As-prepared Fe-N-C catalysts usually contain mixed chemical phases (e.g., Fe-based nanoparticles, Fe-N coordination site and various nitrogen species), as well as carbon scaffolds with random morphology. Such complexity makes it difficult to identify the active site and control the porous structure. Though progress has been made in improving their performance through delicate selection of precursors, such process is largely based on test-and-trial method, shedding little light on the understanding of the material. In this dissertation, we designed a novel "post iron decoration" synthetic strategy towards efficient Fe-N-C catalysts, which de-convolutes the growth of iron and nitrogen species, enables the rational design of the catalyst structure, and provides a series of effective model materials for active site probing. Specifically, liquid iron penta-carbonyl was used to wet the surface of mesoporous N-doped carbon spheres (NMC), whose porous structure is determined by the template used for preparation. The obtained Fe(CO)5/NMC complex was then pyrolyzed to generate the Fe/NMC catalysts. Through comparative study and thorough material characterization, we demonstrated that the pyridinic-N of NMC anchors the Fe atoms to form Fe-Nx active sites during pyrolysis, while the graphitic-N remains ORR active. The excessive Fe atoms were aggregated forming fine nanoparticles, which were subsequently oxidized forming amorphous-iron oxide/iron crystal core-shell structure. All the composing elements of Fe/NMC catalysts are uniformly distributed on the NMC scaffold, whose porous structure is shown to be not affected by Fe decoration, guaranteeing the effective exposure of active sites. The best performing Fe/NMC catalysts exhibited a high half-wave potential of 0.862 V, which is close to that of the benchmark 40% Pt/C catalyst. Such high activity is primarily attributed to the Fe-Nx active sites in the catalysts. While the surface oxidized Fe crystallites though not being the major active site, is revealed to catalyze the reduction of HO2-, the 2e ORR product, facilitating the 4e reduction of oxygen. Finally, such synthetic strategy is successfully extended to prepare other Me-N-C materials. Based on the established understanding of the active sites, we then complexed the active Fe(CO)5 molecules with a N-rich metal-organic framework (ZIF-8) to form a precursor, which was subsequently pyrolyzed to form Fe-NC catalysts. During the pyrolysis, Fe(CO)5 reacts homogeneously with the ZIF-8 scaffold, leading to the formation of uniform distribution of Fe-related active sites on the N-rich porous carbon derived from ZIF-8. The zinc atoms in the crystalline structure of ZIF-8 serves as thermo-sacrificial template, resulting in the formation of hierarchical pores that provide abundant easily accessible ORR active sites. In virtue of these advantageous features, the best performing Fe-NC catalyst exhibited a high half-wave potential of 0.91 V in rotating disk electrode experiment in 0.1 M NaOH. Furthermore, zinc-air battery constructed with Fe-NC-900-M as the cathode catalyst exhibited high open-circuit voltage (1.5 V) and a peak power density of 271 mW cm-2, which outperforms those made with 40% Pt/C catalyst (1.48 V, 1.19 V and 242 mW cm-2), and most noble-metal free ORR catalysts reported so far. Finally, such a synthetic method is economic and easily-scalable, offering possibility for further activity and durability improvement.

Download or read book Electrocatalysts and Polymer Electrolytes for Anion Exchange Membrane Fuel Cells written by Xinyao Lu and published by . This book was released on 2021 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: The development of fuel cells is indispensable to enable the hydrogen society. Anion exchange membrane fuel cells (AEMFCs) have triggered great interest over the past few years. In this dissertation, electrocatalysis in alkaline media and polymer electrolytes for AEMFCs have been explored from fundamental aspects to practical applications. For the oxygen reduction reaction (ORR) in alkaline media, electrochemically dealloyed Pd-M (M = Ni, Mn) nanoparticle catalysts were developed to enhance electrocatalytic activity. The electrochemical dealloying process was demonstrated to be effective in selectively leaching out the less noble metal and metal oxides on the surface. The higher atomic concentration of electrochemically active Pd exposed on the surface of the nanoparticles was found to be the reason for the enhanced ORR activity in alkaline media. These findings provide insights for the rational design of the composition and structure of electrocatalysts with enhanced electrocatalytic activity, based on post-synthesis modification methods. From a fundamental perspective, to explain and predict the electrocatalytic activity of heterogenous reactions, the energy of intermediates is usually used as an activity descriptor. However, this was recently called into questions. We developed a novel method, based on fast scan rate cyclic voltammetry, to directly measure the kinetics of the electro-adsorption processes. The Had adsorption reaction, the elementary step of the hydrogen evolution reaction (HER), on Pt(111) in acid was found to be >100x faster than in alkaline media, although the Had binding energy was the same. Together, with cation effects and isotope effects found in alkaline media, we demonstrated that the slow kinetics of the HER at high pH are not due to an unfavorable Had binding energy but to the high barrier of interfacial water reorganization. Polymer electrolytes in AEMFCs, namely anion exchange membranes and ionomers, play important roles in the transport of anions and water molecules. In situ characterization of these materials in their electrochemical environment is critical for understanding the anion transport mechanism and improving the design of them. The anion exchange and water dynamics in a perspective phosphonium-based AEM during the methanol oxidation process were studied with the electrochemical quartz crystal microbalance (EQCM). The results provide insights of the anion exchange process in the membranes during the reaction and emphasize the importance of characterizing the membranes in a hydrated electrochemical environment. The influence of ion exchange capacity (IEC) on the solubility, the ionomer viscoelasticity in water and the transport of charged and uncharged species, of a promising polyethylene piperidinium methyl (PEPM) ionomer were also investigated. The design of ionomers and membranes, with suitable IEC for their different functions in AEMFCs from the aspect of solubility, mechanical properties and mass transport, can be guided via this work.

Download or read book 3D Graphene written by Ram K. Gupta and published by Springer Nature. This book was released on 2023-07-20 with total page 434 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book provides a comprehensive overview of the synthesis, properties, and emerging applications of 3D graphene. It begins with an introduction to 3D graphene and covers the methods for synthesizing and printing 3D graphene. The book explores the characteristics of 3D graphene, including its morphology, surface area, and porosity, and the techniques used for characterizing it. Architectural and chemical aspects of 3D graphene for emerging applications are discussed, including energy storage, environmental remediation, and biosensing. The book reviews recent advancements in 3D graphene for electrochemical sensors, biosensors, and optical sensors, as well as its use in flexible sensors. It also covers the use of graphene-based materials for the remediation of hydrogen sulfide gas and the removal of inorganic pollutants and pharmaceutical residues. The book further explores the use of 3D graphene in metal-ion and metal-air batteries, flexible and wearable batteries, and high-performance supercapacitors. It also covers its use in photovoltaics, fuel cells, and as electrocatalysts and photocatalysts for water splitting. Additionally, the book discusses the use of 3D graphene in flexible electronics, capacitive de-ionization of water, and theranostic applications. Finally, the book addresses the toxicity, stability, recycling, and risk assessments of 3D graphene, providing a comprehensive understanding of the material's safety and sustainability considerations. Overall, this book is a valuable resource for researchers, engineers, and students interested in the synthesis, properties, and applications of 3D graphene.

Download or read book Structure property Relationships of Electrocatalysts for the Two electron Oxygen Reduction Reaction in Acidic and Neutral Media written by Richard Dominic Ross and published by . This book was released on 2023 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: The prospect of electrochemical synthesis of valuable industrial and household products using renewable energy is an attractive possibility to decentralize and decarbonize various chemical industries. By multi-modal characterization of the structures of crystalline electrocatalysts, rational design rules for the structural motifs that give way to high activity, selectivity, and stability of electrocatalysts for a particular synthetic pathway become possible. One particularly interesting pathway that was largely ignored, overlooked, or initially minimized (in the case of designing catalysts for fuel cells) is the two-electron reduction of oxygen (2e- ORR) to hydrogen peroxide (H2O2). In my graduate work, I have aimed to unveil design rules towards high performance for the 2e- ORR by careful interrogation of catalysts using multi-modal ex situ and in situ/operando techniques. In particular, I explored metal compound (CuCo2-xNixS4, Co3-xNixSe4, and PdSe2) catalysts and metal organic framework (Ni3(HAB)2, HAB = hexaaminobenzene) catalysts for 2e- ORR in either acidic or neutral conditions, which are most relevant for H2O2 production. I also explore unique mechanisms over these catalysts, such as how Cu leaching from CuCo2-xNixS4 catalysts impact H2O2 production and the electro-Fenton process, how redox processes on Ni3(HAB)2 lead to a potential dependent electrocatalytic mechanism, and how the unique structure type of PdSe2 enables rapid H2O2 production and high stability. Additionally, I establish a promising new direction of heterogeneous 2e- ORR catalysts in non-aqueous media. This work unveils the importance of catalyst composition, structure, and microenvironment for activity, selectivity, and stability in 2e- ORR.

Download or read book Multi scale Atomistic Modeling for Electrocatalytic Applications written by Sneha Akhade and published by . This book was released on 2016 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: With depletion of traditional fossil fuel sources of energy, electrocatalysis is expected to play an important role in the development of alternate energy electrochemical devices, including fuel cells and electrolyzers. The design of effective catalysts is necessary to increase the rate of the electrocatalytic reactions in order to improve the working efficiency of the electrochemical devices. The reactions occur at the electrode/electrolyte interface, with the reaction rates controlled by complex interactions between the redox species and electrolytic ions on the solvated electrode surface that operates under constant applied potentials. These phenomena are difficult to probe experimentally and computational modeling can provide insight on the impact of the electrode potential and electrolyte distribution on the electrocatalytic processes. This dissertation primarily employs Density Functional Theory (DFT) to investigate the effect of the electrode potential on the thermodynamics and kinetics of electrocatalytic reactions. Modeling the electrolyte distribution is not feasible with computationally intensive DFT calculations and as such, classical reactive Molecular Dynamics (MD) simulations are performed to model the structure and dynamics of the electrolyte at longer length and time scales. The electrochemical reduction of CO2 is given special emphasis although the methods and approaches adopted in this dissertation are generally applicable towards investigating any electrocatalytic reaction of interest. CO2 electroreduction (ER) offers the possibility of generating hydrocarbons from renewable energy sources, however, the process is limited by (i) the use of inefficient electrocatalysts that are not selective and active towards hydrocarbon formation, (ii) a poor understanding of the reaction mechanism and the key rate-limiting and selectivity determining steps and, (iii) limited insight on the influence of the electrolyte composition on the selectivity and production rate of key intermediates. In this dissertation, DFT-based calculations are used to probe the electrode potential-dependent activity, reactivity and selectivity of various transition metal electrocatalysts for CO2 ER. A model to estimate the potential-dependent reaction energies and activation barriers is developed and applied to examine elementary kinetics of C-H, O-H and N-H bond breaking and forming steps. The implications of DFT model choices are explored. To address the limitations in the length and time scales of the DFT models, classical reactive MD simulations using ReaxFF are performed to model the electrochemical interface and examine the interfacial distribution and dynamics of the solvent and electrolytic ions under constant applied electrode potentials. The overall objective of this dissertation is to develop computational modeling tools for electrocatalytic reactions and examine the factors that influence the rational design of electrode materials for key electrocatalytic processes.

Download or read book Nanostructured intermetallics from rational synthesis to energy electrocatalysis written by Mingcheng Zhang and published by OAE Publishing Inc.. This book was released on 2023-06-05 with total page 28 pages. Available in PDF, EPUB and Kindle. Book excerpt: Intermetallics are a large family of structurally ordered alloys that combines a metal element with other metal/metalloid elements with a clearly defined stoichiometric ratio. Intermetallics possess abundant crystal structures and atomic packing motifs, giving rise to a great variety of electronic configurations and surface adsorption properties. The wide electronic and geometric diversity makes intermetallics a highly promising population for discovering advanced materials for various catalytic applications. This review presents recent advances in the reaction synthesis of intermetallic materials at the nanoscale and their energy-related electrocatalytic applications. Initially, we introduce general principles for the formation of stable intermetallic structures. Subsequently, we elaborate on common synthetic strategies of nanostructured intermetallics, such as thermal annealing, wet-chemical methods, metallothermic reduction, and template-directed synthesis. Furthermore, we discuss the wide employment of these intermetallic nanocatalysts in many different kinds of electrocatalytic applications, as well as highlight the theoretical and experimental evidence for establishing a reasonable relationship between atomic arrangement and catalytic activity. Finally, we propose some perspectives for future developments of intermetallic preparation and catalytic applications.

Download or read book Carbon Dioxide as Chemical Feedstock written by Michele Aresta and published by John Wiley & Sons. This book was released on 2010-01-26 with total page 414 pages. Available in PDF, EPUB and Kindle. Book excerpt: Filling the need for an up-to-date handbook, this ready reference closely investigates the use of CO2 for ureas, enzymes, carbamates, and isocyanates, as well as its use as a solvent, in electrochemistry, biomass utilization and much more. Edited by an internationally renowned and experienced researcher, this is a comprehensive source for every synthetic chemist in academia and industry.

Download or read book Anion Exchange Membrane Fuel Cells written by Liang An and published by Springer. This book was released on 2018-03-21 with total page 348 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book provides a review of the latest advances in anion exchange membrane fuel cells. Starting with an introduction to the field, it then examines the chemistry and catalysis involved in this energy technology. It also includes an introduction to the mathematical modelling of these fuel cells before discussing the system design and performance of real-world systems. Anion exchange membrane fuel cells are an emerging energy technology that has the potential to overcome many of the obstacles of proton exchange membrane fuel cells in terms of the cost, stability, and durability of materials. The book is an essential reference resource for professionals, researchers, and policymakers around the globe working in academia, industry, and government.

Download or read book Advanced Electrocatalysts for Low Temperature Fuel Cells written by Francisco Javier Rodríguez-Varela and published by Springer. This book was released on 2018-10-09 with total page 318 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book introduces the reader to the state of the art in nanostructured anode and cathode electrocatalysts for low-temperature acid and alkaline fuel cells. It explores the electrocatalysis of anode (oxidation of organic molecules) and cathode (oxygen reduction) reactions. It also offers insights into metal-carbon interactions, correlating them with the catalytic activity of the electrochemical reactions. The book explores the electrocatalytic behaviour of materials based on noble metals and their alloys, as well as metal-metal oxides and metal-free nanostructures. It also discusses the surface and structural modification of carbon supports to enhance the catalytic activity of electrocatalysts for fuel-cell reactions.