Grid edge The interface where prosumers and consumers meet the intelligent grid. Technologies at the grid edge enable new opportunities for our energy systems. Digitalization, decentralization and decarbonization – as three key drivers for energy transition – allow the energy production, storage and consumption to be more sustainable, efficient and
We provide some insights on the interface structure design in high-performance liquid or solid-state lithium–sulfur batteries in the future. The lithium–sulfur battery, one of the most potential high-energy-density rechargeable batteries, has obtained significant progress in overcoming challenges from both sulfur cathode and lithium anode.
Driven by the continuous search for improving performances, understanding the phenomena at the electrode/electrolyte interfaces has become an overriding factor for the success of sustainable and efficient battery technologies for mobile and stationary applications.
In this review, we present a broad picture of the research on the importance of special wetting interfaces of electrodes for new energy devices, and summarize the influence
Advanced Energy Materials is your prime applied energy journal for research providing solutions to today''s global energy challenges. Abstract In the ongoing quest to develop lithium-ion batteries with superior capacity and enhanced safety, the focus has shifted toward all-solid-state batteries (SSBs) and nickel-rich cathode mate...
4 天之前· Elevating the charge cutoff voltage of mid-nickel (mid-Ni) LiNixCoyMnzO2 (NCM; x = 0.5–0.6) Li-ion batteries (LIBs) beyond the traditional 4.2 V generates capacities comparable
This book explores the critical role of interfaces in lithium-ion batteries, focusing on the challenges and solutions for enhancing battery performance and safety. It sheds light on the formation and impact of interfaces between electrolytes and electrodes, revealing how side reactions can diminish battery capacity. The book examines the
There are currently two major ongoing initiatives dedicated to ontologizing the battery domain: The Battery Interface Ontology (BattINFO) and the Battery Value Chain Ontology (BVCO). BattINFO describes batteries on the cell level and below, including not only components, materials, and their interfaces, but also electrochemical processes, models, and
Among the multitude of energy storage technologies (e.g., zinc-manganese battery, nickel-cadmium battery, nickel-hydrogen battery, lead-acid battery, alkali-ion battery, fuel cell, redox flow battery, etc.), the rechargeable alkali-ion battery has emerged as one of the most attractive candidates for grid and vehicular applications and the domina...
In this review, we assess solid-state interfaces with respect to a range of important factors: interphase formation, interface between cathode and inorganic electrolyte, interface between anode and inorganic electrolyte, interface between polymer electrolyte and Li metal, and interface of interparticles. This review also summarizes existing
This article highlights emerging approaches, and especially the requirements and directions these approaches need to meet, to study battery interfaces and their evolution, being chemistry-agnostic. Therefore, this review focuses on the most promising techniques for
The EU project BIG-MAP has developed the Battery Interface Ontology (BattINFO) to help address this challenge [1]. BattINFO is a domain ontology for batteries and electrochemistry
Driven by the continuous search for improving performances, understanding the phenomena at the electrode/electrolyte interfaces has become an overriding factor for the success of sustainable and efficient battery technologies for
The characteristic differences of interfaces between liquid- and solid-type Li-based batteries are presented here. Interface types, interlayer origin, physical and chemical structures, properties, time evolution, complex interrelations between various factors, and promising interfacial tailoring approaches are reviewed. Furthermore, recent
Electrochemical (batteries and fuel cells), chemical (hydrogen), electrical (ultracapacitors (UCs)), mechanical (flywheels), and hybrid systems are some examples of many types of energy-storage systems (ESSs) that can be utilized in EVs [12, 13].The ideal attributes of an ESS are high specific power, significant storage capacity, high specific energy, quick
We provide some insights on the interface structure design in high-performance liquid or solid-state lithium–sulfur batteries in the future. The lithium–sulfur battery, one of the most potential high-energy-density
Battery Management System (BMS) plays an essential role in optimizing the performance, safety, and lifespan of batteries in various applications. Selecting the appropriate BMS is essential for effective energy
This book explores the critical role of interfaces in lithium-ion batteries, focusing on the challenges and solutions for enhancing battery performance and safety. It sheds light on the formation
Li 2 (Lab Lithium & Interface) est un laboratoire commun dédié aux batteries « tout solide » créé en novembre 2022 par le LEPMI, laboratoire rassemblant des compétences dans la plupart des domaines de l''électrochimie, notamment dans la production et le stockage électrochimique de l''énergie et Blue Solutions, entreprise française filiale du Groupe Bolloré, pionnière dans les
In this review, we present a broad picture of the research on the importance of special wetting interfaces of electrodes for new energy devices, and summarize the influence of wetting behaviors among solid, liquid and gas phases on the improved performance of energy systems (Fig. 2).
The characteristic differences of interfaces between liquid- and solid-type Li-based batteries are presented here. Interface types, interlayer origin, physical and chemical structures, properties, time evolution, complex
This article highlights emerging approaches, and especially the requirements and directions these approaches need to meet, to study battery interfaces and their evolution, being chemistry-agnostic. Therefore, this review focuses on the most promising techniques for characterising all phases relevant to interfacial processes in batteries. Solid
Among the multitude of energy storage technologies (e.g., zinc-manganese battery, nickel-cadmium battery, nickel-hydrogen battery, lead-acid battery, alkali-ion battery, fuel cell, redox
4 天之前· Elevating the charge cutoff voltage of mid-nickel (mid-Ni) LiNixCoyMnzO2 (NCM; x = 0.5–0.6) Li-ion batteries (LIBs) beyond the traditional 4.2 V generates capacities comparable to those of high-Ni NCMs along with more stable performance and improved safety. Considering the critical issues associated with residual lithium on high-Ni NCMs regarding greatly increased
In this review, we assess solid-state interfaces with respect to a range of important factors: interphase formation, interface between cathode and inorganic electrolyte,
The lithium–sulfur battery, one of the most potential high-energy-density rechargeable batteries, has obtained significant progress in overcoming challenges from both sulfur cathode and lithium anode. However, the unstable multi-interfaces between electrodes and electrolytes, as well as within the electrodes
Engineers created a new type of battery that weaves two promising battery sub-fields into a single battery. The battery uses both a solid state electrolyte and an all-silicon anode, making it a
The EU project BIG-MAP has developed the Battery Interface Ontology (BattINFO) to help address this challenge [1]. BattINFO is a domain ontology for batteries and electrochemistry under the
Key Laboratory for Renewable Energy, Beijing Key Laboratory for New Energy Materials and Devices, Beijing National Laboratory for Condensed Matter Physics, Institute of Physics, Chinese Academy of Sciences, Beijing, PR China. College of Materials Sciences and Opto-Electronic Technology, University of Chinese Academy of Sciences, Beijing, PR China
In this review, typical interfaces in the lithium–sulfur battery system are classified as solid/solid and solid/liquid interfaces. Subsequently, the unique multi-interfacial issues in lithium–sulfur batteries and their impact on lithium–sulfur electrochemistry are carefully discussed.
The interfaces in an inorganic solid-electrolyte battery can feature several basic structures: the cathode-electrolyte interface, the anode-electrolyte interface, and the interparticle interface, as illustrated in Figure 1.
For batteries, there are plenty of interfaces that include the solid-liquid interface discussed above and the solid-solid interface between the electrode and the solid electrolyte or between the electrode and the current collector.
The influence of interfaces represents a critical factor affecting the use of solid-state batteries (SSBs) in a wide range of practical industrial applications. However, our current understanding of this key issue remains somewhat limited.
In conclusion, we foresee a leap forward in our understanding and control over battery interfaces through the use of approaches and techniques such as those described in this perspective, which together represents a necessary departure from our traditional way to approach such complex issues.
Such a brief overview underlines one general pitfall of the field: the solid interphase forming at the electrode/electrolyte interface is the most tangible of all the events occurring at battery interfaces and thus the most frequently investigated [8, 9] (helped by compatible time/length scales).
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