Battery ion conductor

Li ion conductor discovery unlocks new direction for

Such lithium electrolytes are essential components in the rechargeable batteries that power electric vehicles and many electronic devices. Consisting of non-toxic earth-abundant elements, the new material has high

Layered sodium titanate with a matched lattice: a

Na metal batteries using solid-state electrolytes (SSEs) have attracted intensive attention due to their superior safety and high energy density. However, the interfacial issue is one of the biggest challenges to their working

基于无机钠离子导体的固态钠电池研究进展

Research progress of solid-state sodium batteries using inorganic sodium ion conductors[J]. Energy Storage Science and Technology, 2020, 9(5): 1370-1382. 使用本文

Solid-state battery electrolyte makes a fast lithium-ion

Researchers at the University of Liverpool, UK have developed a new solid-state battery electrolyte that conducts lithium ions so rapidly, it could compete with the liquid electrolytes found in today''s ubiquitous lithium-ion

First-principles study on a new chloride solid lithium

Both the exploration of novel structures and the investigation of ion-transport mechanisms are essential in the development of solid-state electrolytes (SEs). We performed high-throughput calculations to screen the

A New (Trifluoromethane)Sulfonylimide Single-Ion Conductor

Revisiting polymeric single lithium-ion conductors as an organic route for all-solid-state lithium ion and metal batteries Jeong, Kihun; Park, Sodam; Lee, Sang-Young Journal of Materials Chemistry A: Materials for Energy and Sustainability ( 2019 ), 7 ( 5 ), 1917-1935 CODEN: JMCAET ; ISSN: 2050-7496 .

A prototype of dual-ion conductor for all-solid-state lithium batteries

Fig. 1. Reaction mechanism of the ASSBs enabled by Cu+ and Li+ dual-ion conductor. (A) Schematic diagram of the ion highway connecting cathode active materials and electrolytes enabled by the Cu+ and Li +dual-ion conductor. Cu and Li can rapidly migrate along the anion framework simultaneously with a similar ionic con-

Design principles for sodium superionic conductors

Motivated by the high-performance solid-state lithium batteries enabled by lithium superionic conductors, sodium superionic conductor materials have great potential to

Understanding fast-ion conduction in solid

1. Introduction. Fast-ion–conducting solids are a intriguing class of materials that exhibit notably high ionic conductivities. This unusual property makes fast-ion conductors useful for applications such as all–solid

Na5YSi4O12 fast ion conductor protection layer

Aqueous zinc-ion batteries (AZIBs) are promising for future large-scale energy storage systems, however, suffer from inferior cycling life due to the dendrites growth and side reaction on Zn metal anode. Herein, a fast

Anion‐modulated Ion Conductor with Chain Conformational

Herein, we constructed an anion-modulated ionic conductor (AMIC) that enables in situ construction of electrolyte/electrode interphases for high-voltage SSLMBs by exploiting

Layered sodium titanate with a matched lattice: a

1 Introduction Lithium ion batteries (LIBs) have been widely used in portable electronic devices, electric vehicles and smart grids. However, the safety hazard of traditional liquid LIBs is gradually being taken into

Design principles for sodium superionic conductors

Motivated by the high-performance solid-state lithium batteries enabled by lithium superionic conductors, sodium superionic conductor materials have great potential to empower sodium batteries

Single-ion conductor gel polymer electrolytes

Single-ion conductor gel polymer electrolytes enabling an anionic polymer-induced solid electrolyte interphase for dendrite-free lithium-metal batteries Lithium-metal batteries (LMBs) are considered some of the

A prototype of dual-ion conductor for all

(A) Schematic diagram of the ion highway connecting cathode active materials and electrolytes enabled by the Cu + and Li + dual-ion conductor. Cu + and Li + can

Exploring Ionic Transport Mechanisms in Solid Conductors: A Dual

Solid Li-ion conductors require high ionic conductivity to ensure rapid Li+ transport within solid-state batteries, necessitating a thorough examination of the relationship

Li ion conductor discovery unlocks new direction for

In a paper published in the journal Science, researchers at the University of Liverpool have discovered a solid material that rapidly conducts lithium ions. Such lithium electrolytes are essential components in the

Fast-ion conductor

OverviewExamplesMechanismClassificationHistorySee also

A common solid electrolyte is yttria-stabilized zirconia, YSZ. This material is prepared by doping Y2O3 into ZrO2. Oxide ions typically migrate only slowly in solid Y2O3 and in ZrO2, but in YSZ, the conductivity of oxide increases dramatically. These materials are used to allow oxygen to move through the solid in certain kinds of fuel cells. Zirconium dioxide can also be doped with calcium oxide to give an oxide conductor that is used in oxygen sensors in automobile controls. U

An All-Solid-State Rechargeable Chloride

One possible solution to dissolve the problems concerning electrode dissolution and side reactions between electrode material and solvent/liquid electrolyte is the use of

A prototype of dual-ion conductor for all-solid-state lithium batteries

(A) Schematic diagram of the ion highway connecting cathode active materials and electrolytes enabled by the Cu + and Li + dual-ion conductor. Cu + and Li + can rapidly migrate along the anion framework simultaneously with a similar ionic conductivity of 1.19 and 4.07 mS/cm, respectively (fig. S9). (B) Schematic diagram of S 2− /S 0 redox in the ASSB Cu

Mixed ion-electron conductive materials: A path to higher energy

Lithium-ion batteries simply consist of high electropositive anode, a stable cathode, a lithium-ion-permeable separator that prevents short-circuit, an electrolyte that conducts lithium ions, and current collectors. Zhang et al. [107] pursued different strategy to analyze the effect of mixed-ion conductors to alleviate the capacity decay of

Single-Ion versus Dual-Ion Conducting

Lithium batteries with solid polymer electrolytes (SPEs) and mobile ions are prone to mass transport limitations, that is, concentration polarization, creating a concentration

Solid state lithium ion conductors for lithium batteries

Lithium ion batteries will play a significant role in the future of energy generation. The need for polymer electrolytes will be critical as such batteries are developed and implemented. The use of inorganic solid electrolytes likewise will be critical in the development of this emerging technology.

A prototype of dual-ion conductor for all

Here, we demonstrated a superionic conductor of simultaneously transporting Cu ion and Li ion (Fig. 1A) to increase the concentration of charge carriers and bridge an

Single-ion conductor gel polymer electrolytes

Single-ion conductor gel polymer electrolytes enabling an anionic polymer-induced solid electrolyte interphase for dendrite-free lithium-metal batteries Lithium-metal batteries (LMBs) are considered some of the most promising

Dual-ion conductors: from liquid to solid

Accordingly, it is necessary to develop dual-ion conductors to enable the migration of multiple working ions. This focus article starts by introducing traditional dual-ion batteries based on liquid electrolytes and their

Interfacial behaviours between lithium ion

In general, ideal Li-ion conductors used in any battery system should have the attributes of (1) high ionic conductivity enabling the solid-state batteries to work at high rates and wide

Lithium-Ion Battery with Single-Ion Conducting

This example demonstrates the Lithium-Ion Battery, Single-Ion Conductor interface for studying the discharge of a lithium-ion battery with solid electrolyte. The geometry is in one dimension and the model is isothermal. The behavior

Li ion conductor discovery unlocks new direction for sustainable batteries

Li ion conductor discovery unlocks new direction for sustainable batteries. Published on 15 February 2024. One of the grand challenges for materials science is the design and discovery of new materials that address global priorities such as Net Zero.

Diffusion mechanisms of fast lithium-ion conductors

This Review highlights structural and chemical strategies to enhance ionic conductivity and maps a strategic approach to discover, design and optimize fast lithium-ion

Unlocking the secrets of ideal fast ion conductors for all-solid

All-solid-state batteries (ASSBs) are promising alternatives to conventional lithium-ion batteries. ASSBs consist of solid-fast-ion-conducting electrolytes and electrodes that offer improved energy density, battery safety, specific power, and fast-charging capability.

Materials design of ionic conductors for solid state batteries

All-solid-state batteries, employing inorganic ion conductors as electrolytes, can surpass the current Li-ion technology in terms of energy density, battery safety, specific power, as well as a fast-charging capability; however, a highly conductive solid electrolyte is essential. While recent extensive explorations of solid ion conductors have

Area 3 – Ion-Conductors | Electrochemical Energy

Although they have been studied since the early 1980''s, polymer electrolytes have not realized wide spread adoption due to their sub-par ion transport properties. 1 Polymer electrolytes suffer from low ionic conductivity and low

Layered sodium titanate with a matched lattice: a single ion conductor

The NTO sheet behaves like a single ion conductor with a low ion migration activation energy of ∼0.159 eV and a high ion transference number (t Na+) of 0.91, which is due to the weak interactions between the lamellar Na+ ions and unmoved anionic Ti–O–Ti layers in NTO. An

Unlocking the secrets of ideal fast ion conductors for

ASSBs consist of solid-fast-ion-conducting electrolytes and electrodes that offer improved energy density, battery safety, specific power, and fast-charging capability.

Inorganic lithium-ion conductors for fast-charging lithium

Inorganic lithium-ion conductors (ILCs) are considered as the promising candidates in batteries, semiconductors, and other fields. Herein, we review the main role of

Design principles for NASICON super-ionic conductors

A chemical map of NaSICON electrode materials for sodium-ion batteries. J. Mater. Chem. A 9, 281–292 S. et al. Tuning mobility and stability of lithium ion conductors based on lattice

A novel inorganic solid state ion conductor for

The conduction of the bivalent magnesium cation, Mg2+, in an inorganic solid state material, Mg(BH4)(NH2), has been demonstrated. This material exhibited a high ionic conductivity of 10−6 S cm−1 at 150 °C, and its