Your search keyword '"superionic conductors"' showing total 6 results

1. The nonexistence of a paddlewheel effect in superionic conductors

Author

Jun, KyuJung, Lee, Byungju, Kam, Ronald L, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, superionic conductors, diffusion, ab initio molecular dynamics, correlated motion, solid electrolyte

Abstract

Since the 1980s, the paddlewheel effect has been suggested as a mechanism to boost lithium-ion diffusion in inorganic materials via the rotation of rotor-like anion groups. However, it remains unclear whether the paddlewheel effect, defined as large-angle anion group rotations assisting Li hopping, indeed exists; furthermore, the physical mechanism by which the anion-group dynamics affect lithium-ion diffusion has not yet been established. In this work, we differentiate various types of rotational motions of anion groups and develop quaternion-based algorithms to detect, quantify, and relate them to lithium-ion motion in ab initio molecular dynamics simulations. Our analysis demonstrates that, in fact, the paddlewheel effect, where an anion group makes a large angle rotation to assist a lithium-ion hop, does not exist and thus is not responsible for the fast lithium-ion diffusion in superionic conductors, as historically claimed. Instead, we find that materials with topologically isolated anion groups can enhance lithium-ion diffusivity via a more classic nondynamic soft-cradle mechanism, where the anion groups tilt to provide optimal coordination to a lithium ion throughout the hopping process to lower the migration barrier. This anion-group disorder is static in nature, rather than dynamic and can explain most of the experimental observations. Our work substantiates the nonexistence of the long-debated paddlewheel effect and clarifies any correlation that may exist between anion-group rotations and fast ionic diffusion in inorganic materials.

Published

2024

2. Lithium Oxide Superionic Conductors Inspired by Garnet and NASICON Structures

Author

Xiao, Yihan, Jun, KyuJung, Wang, Yan, Miara, Lincoln J, Tu, Qingsong, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, batteries, DFT calculations, solid electrolytes, solid-state batteries, superionic conductors, Macromolecular and Materials Chemistry, Interdisciplinary Engineering, Macromolecular and materials chemistry, Materials engineering

Abstract

The key component in lithium solid-state batteries (SSBs) is the solid electrolyte composed of lithium superionic conductors (SICs). Lithium oxide SICs offer improved electrochemical and chemical stability compared with sulfides, and their recent advancements have largely been achieved using materials in the garnet- and NASICON (sodium superionic conductor)- structured families. In this work, using the ion-conduction mechanisms in garnet and NASICON as inspiration, a common pattern of an “activated diffusion network” and three structural features that are beneficial for superionic conduction: a 3D percolation Li diffusion network, short distances between occupied Li sites, and the “homogeneity” of the transport path are identified. A high-throughput computational screening is performed to search for new lithium oxide SICs that share these features. From this search, seven candidates are proposed exhibiting high room-temperature ionic conductivity evaluated using ab initio molecular dynamics simulations. Their structural frameworks including spinel, oxy-argyrodite, sodalite, and LiM(SeO3)2 present new opportunities for enriching the structural families of lithium oxide SICs.

Published

2021

3. Lithium Oxide Superionic Conductors Inspired by Garnet and NASICON Structures

Author

Xiao, Y, Jun, KJ, Wang, Y, Miara, LJ, Tu, Q, and Ceder, G

Subjects

batteries, DFT calculations, solid electrolytes, solid-state batteries, superionic conductors, Macromolecular and Materials Chemistry, Materials Engineering, Interdisciplinary Engineering

Abstract

The key component in lithium solid-state batteries (SSBs) is the solid electrolyte composed of lithium superionic conductors (SICs). Lithium oxide SICs offer improved electrochemical and chemical stability compared with sulfides, and their recent advancements have largely been achieved using materials in the garnet- and NASICON (sodium superionic conductor)- structured families. In this work, using the ion-conduction mechanisms in garnet and NASICON as inspiration, a common pattern of an “activated diffusion network” and three structural features that are beneficial for superionic conduction: a 3D percolation Li diffusion network, short distances between occupied Li sites, and the “homogeneity” of the transport path are identified. A high-throughput computational screening is performed to search for new lithium oxide SICs that share these features. From this search, seven candidates are proposed exhibiting high room-temperature ionic conductivity evaluated using ab initio molecular dynamics simulations. Their structural frameworks including spinel, oxy-argyrodite, sodalite, and LiM(SeO3)2 present new opportunities for enriching the structural families of lithium oxide SICs.

Published

2021

4. Exploring Mechanisms to Design Inorganic Lithium Superionic Conductors

Author

Jun, KyuJung

Subjects

Materials Science, Computational chemistry, Chemistry, Diffusion, First principles calculations, Machine learning potentials, Molecular dynamics, Solid electrolytes, Superionic conductors

Abstract

Energy storage technology is one of the most important technological pillars for achieving reduced carbon emissions to decelerate global warming, together with clean energy generation technologies such as solar energy. The development of a low-cost, safe, and high-energy-density energy storage technology is essential for accelerating the electrification of transportation, as well as the widespread adoption of grid energy storage systems.The search for advanced energy storage technologies has increasingly focused on all-solid-state batteries (ASSBs) due to their potential for improved safety and higher energy density. Inorganic lithium superionic conductors are crucial to this emerging technology, offering fast ion transport that rival those of liquid-based systems. However, the challenge lies in finding materials that not only provide superionic conductivity but also meet all practical requirements, underscoring the need for the discovery of novel conductors. The development and identification of new functional materials could significantly transform energy storage technology, particularly as the limitations of current leading technologies are often tied to basic material properties.Understanding the structure-property relationship is at the core of the field of materials science. By understanding how the bulk crystal structure, various defects and microstructures, or local structures within disordered or amorphous systems affect ionic conductivity, the rational design of inorganic lithium superionic conductors can be achieved. In particular, because fast ion transport through the bulk is often a necessary condition in energy storage devices that require a high current of lithium ions, it is essential to understand the structural and chemical features that lead to high bulk ionic conductivities of crystalline materials.This thesis comprehensively investigates the diverse structural and chemical factors that improve ionic conductivity, and the atomistic mechanism by which each factor affects them. Chapter 1 introduces the computational and experimental background for understanding lithium-ion diffusion in inorganic materials as well as some of the chemical factors that can be used to optimize a fast conductor that already has desirable structural features. What often plays a decisive role is the structural feature; the structural features of inorganic crystals dictate whether it can be optimized to a superionic conductor or not. In this dissertation, we decompose the crystal into the framework (i.e., non-lithium cation sites) and lithium-ion diffusion network (i.e., lithium-ion sites), with the former discussed in Chapter 2 and the latter discussed in Chapter 3. In Chapter 4, we investigate structures in which the framework is rotationally mobile and analyze whether the rotational motion of anion groups leads to faster lithium-ion diffusion, also known as the paddlewheel effect. Chapter 5 investigates a remarkable class of ultrafast lithium-ion conductors with van der Waals-bonded frameworks. This chapter demonstrates how the mechanisms of ion transport discussed in Chapters 2, 3, and 4 result in the highest ionic conductivity predicted from computational studies so far. Finally, in Chapter 6, I provide an overview of how the diverse structural and chemical mechanisms of fast lithium-ion diffusion have led to the development of various classes of state-of-the-art superionic conductors by 2024. Here, I attempt to put together a global conceptual framework of various mechanisms that may be used for superionic conductors. Finally, I end with my perspective on future research avenues that may accelerate the discovery and optimization of fast lithium-ion conductors for the accelerated deployment of safer next-generation energy storage technologies.

Published

2024

5. Spring-Like Pseudoelectroelasticity of Monocrystalline Cu2S Nanowire

Author

Zhang, Qiubo, Shi, Zhe, Yin, Kuibo, Dong, Hui, Xu, Feng, Peng, Xinxing, Yu, Kaihao, Zhang, Hongtao, Chen, Chia-Chin, Valov, Ilia, Zheng, Haimei, and Sun, Litao

Subjects

Affordable and Clean Energy, In situ TEM, pseudoelectroelasticity, Cu2S nanowires, superionic conductors, Nanoscience & Nanotechnology

Abstract

Prediction from the dual-phase nature of superionic conductors-both solid and liquid-like-is that mobile ions in the material may experience reversible extraction-reinsertion by an external electric field. However, this type of pseudoelectroelasticity has not been confirmed in situ, and no details on the microscopic mechanism are known. Here, we in situ monitor the pseudoelectroelasticity of monocrystalline Cu2S nanowires (NWs) using transmission electron microscopy (TEM). Specifically, we reveal the atomic scale details including phase transformation, migration and redox reactions of Cu+ ions, nucleation, growth, as well as spontaneous shrinking of Cu protrusion. Caterpillar-diffusion-dominated deformation is confirmed by the high-resolution transmission electron microscopy (HRTEM) observation and  ab initio calculation, which can be driven by either an external electric field or chemical potential difference. The observed spring-like behavior was creatively adopted for electric nanoactuators. Our findings are crucial to elucidate the mechanism of pseudoelectroelasticity and could potentially stimulate in-depth research into electrochemical and nanoelectromechanical systems.

Published

2018

6. Spring-Like Pseudoelectroelasticity of Monocrystalline Cu2S Nanowire.

Author

Zhang, Qiubo, Shi, Zhe, Yin, Kuibo, Dong, Hui, Xu, Feng, Peng, Xinxing, Yu, Kaihao, Zhang, Hongtao, Chen, Chia-Chin, Valov, Ilia, Zheng, Haimei, and Sun, Litao

Subjects

Cu2S nanowires, In situ TEM, pseudoelectroelasticity, superionic conductors, Nanoscience & Nanotechnology

Abstract

Prediction from the dual-phase nature of superionic conductors-both solid and liquid-like-is that mobile ions in the material may experience reversible extraction-reinsertion by an external electric field. However, this type of pseudoelectroelasticity has not been confirmed in situ, and no details on the microscopic mechanism are known. Here, we in situ monitor the pseudoelectroelasticity of monocrystalline Cu2S nanowires (NWs) using transmission electron microscopy (TEM). Specifically, we reveal the atomic scale details including phase transformation, migration and redox reactions of Cu+ ions, nucleation, growth, as well as spontaneous shrinking of Cu protrusion. Caterpillar-diffusion-dominated deformation is confirmed by the high-resolution transmission electron microscopy (HRTEM) observation and  ab initio calculation, which can be driven by either an external electric field or chemical potential difference. The observed spring-like behavior was creatively adopted for electric nanoactuators. Our findings are crucial to elucidate the mechanism of pseudoelectroelasticity and could potentially stimulate in-depth research into electrochemical and nanoelectromechanical systems.

Published

2018