High-energy and dendrite-free solid-state zinc metal battery
In this work, a lignin-containing cellulose nanofibers (LCNF)-polyacrylamide hydrogel (LPH) electrolyte with a unique dual-network structure and excellent water-retaining
Using Stress to Control Dendrite Growth in Solid-state
Using Stress to Control Dendrite Growth in Solid-state Batteries Massachusetts Institute of Technology (MIT) engineers are paving the road toward a new rechargeable lithium-ion battery that is more lightweight,
Controlling dendrite propagation in solid-state batteries with
We propose a stress-based approach to mitigating metal-dendrite-induced failure in solid-state batteries. Using experiments and a fracture mechanics model, we show
Constructing stable Li-solid electrolyte interphase to achieve
Solid-state batteries based on Li and nonflammable solid-state electrolytes (SSEs) have aroused the attention of numerous researchers because of their absolute safety
Manipulation of lithium dendrites based on electric field relaxation
Dendrite growth harms the safety and longevity of Li-ion batteries. Here, authors find that short-term relaxation after lithium plating boosts capacity retention by forming a
Phase-field investigation of dendrite suppression strategies for all
All-solid-state Li metal batteries are widely considered as the most promising technologies to realize the increasing safety and capacity requirements for the next generation
Dynamic control of lithium dendrite growth with sequential
The comprehensive analysis further reveals that the designed bilayer SSE effectively harnesses the interface-generated pressure during battery cycling, achieving
Controlling Dendrite Growth in Solid-State Electrolytes
Solid-state electrolytes (SSEs) are widely considered as an "enabler" to inhibit dendrite growth of lithium-metal anodes for high-energy and highly safe next-generation batteries. However, recent studies demonstrated
Understanding the evolution of lithium dendrites at Li6.25Al0
The growth of lithium dendrites in inorganic solid electrolytes is an essential drawback that hinders the development of reliable all-solid-state lithium metal batteries.
Dendrite formation in solid-state batteries arising from lithium
Overall, this work deepens our understanding of dendrite formation in solid-state Li batteries and provides comprehensive insight that might be valuable for mitigating dendrite
Lithium dendrites in all‐solid‐state batteries: From formation
As illustrated in Figure 2, contrary to expectations, Li dendrites not only persist in their growth within SSE but can penetrate even the rigid ceramic SSE, resulting in short circuits in SSB.17
Dendrites in Solid‐State Batteries: Ion Transport Behavior,
Solid-state electrolytes (SSEs) are attracting growing interest for next-generation Li-metal batteries with theoretically high energy density, but they currently suffer from safety
Dendrite-Free All-Solid-State Lithium Metal Batteries
The accelerated formation of lithium dendrites has considerably impeded the advancement and practical deployment of all-solid-state lithium metal batteries (ASSLMBs). In this study, a soft carbon (SC)–Li3N interface
Controlling dendrite propagation in solid-state batteries with
Summary Metal-dendrite penetration is a mode of electrolyte failure that threatens the viability of metal-anode-based solid-state batteries. Whether dendrites are driven
Latest Developments in Solid-State Battery
Significant strides in materials science are overcoming long-standing obstacles in solid-state battery design. A primary focus is the development of solid electrolytes capable of enabling lithium metal anodes
Lithium Dendrite in All-Solid-State Batteries: Growth Mechanisms
In this review, a systematic discussion of dendrite growth mechanisms, the corresponding Li dendrite suppression strategies, and advanced characterization techniques in
Controlling Dendrite Growth in Solid-State Electrolytes
In this Review, dendrite growth behaviors in SSEs, including polymer and inorganic electrolytes, are comprehensively summarized. The observed dendrite morphology in these SSEs, possible formation mechanisms,
Recent Advances in Dendrite Suppression Strategies for Solid-State
Solid-state lithium batteries (SSLBs) have emerged as a promising alternative to conventional lithium-ion systems due to their superior safety profile, higher energy density, and
Growth of lithium-indium dendrites in all-solid-state lithium-based
Li-In alloys are widely used as reference materials in the research field of solid-state lithium-based batteries. Here, the authors report and discuss the instability of Li-In
Lithium Dendrite in All-Solid-State Batteries: Growth
Li metal has been receiving increasing attention as an anode in all-solid-state batteries because of its lowest electrochemical potential and high capacity, although the safety problem caused by dendritic growth of Li impedes its
Nature Materials:ALD改善固态电解质和锂金属的界面浸润以及化学稳定性
Bruce Dunn教授认为 "The work by [the University of Maryland research team] effectively solves the lithium metal-solid electrolyte interface resistance problem, which has
Lithium dendrites in all-solid-state batteries: From formation to
The strategies to reveal the complicated deposition mechanism and to control the dendrite growth of metal Li in solid-state batteries, as well as the advanced characterization
Atomic mechanism of lithium dendrite penetration in solid
Here, authors employ MD simulations to enable atomic-scale investigation in the process of dendrite penetration and the concurrent development of cracks during solid state
National High Magnetic Field Laboratory researchers
A specialized MRI coil and sample holder designed for imaging solid-state lithium-ion batteries. (Courtesy of National High Magnetic Field Laboratory.) A team at the Florida State University-headquartered National
Engineers solve a mystery on the path to smaller, lighter batteries
Researchers solved a problem facing solid-state lithium batteries, which can be shorted out by metal filaments called dendrites that cross the gap between metal electrodes.
Nature Materials:ALD改善固态电解质和锂金属的界
Bruce Dunn教授认为 "The work by [the University of Maryland research team] effectively solves the lithium metal-solid electrolyte interface resistance problem, which has been a major barrier to the development of a
Scientists Found Out What Kills Solid-State Batteries
All lithium-ion batteries suffer from dendrite formation, but this happens very quickly in solid-state batteries. Dendrites are branch-like formations that can spread between batteries
Solid state battery design charges in minutes, lasts for thousands
"Our research is an important step toward more practical solid state batteries for industrial and commercial applications." One of the biggest challenges in the design of these
Lithium dendrites in all-solid-state batteries: From
The strategies to reveal the complicated deposition mechanism and to control the dendrite growth of metal Li in solid-state batteries, as well as the advanced characterization methods of metal Li, provide suggestions for the
Lithium dendrites in all-solid-state batteries: From
All-solid-state batteries have attracted great attention from academia and industry, however, many challenges remain regarding practical applications. This review focuses on systematic discussions classifying the