Related references
Note: Only part of the references are listed.Anomalously High Ionic Conductivity of Li2SiS3-Type Conductors
Wenze Huang et al.
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (2022)
Computational insights into the ionic transport mechanism and interfacial stability of the Li2OHCl solid-state electrolyte
Bo Liu et al.
JOURNAL OF MATERIOMICS (2022)
Software for Evaluating Long-Range Electrostatic Interactions Based on the Ewald Summation and Its Application to Electrochemical Energy Storage Materials
Wei Shi et al.
JOURNAL OF PHYSICAL CHEMISTRY A (2022)
Reclaiming Neglected Compounds as Promising Solid State Electrolytes by Predicting Electrochemical Stability Window with Dynamically Determined Decomposition Pathway
Shen Lin et al.
ADVANCED ENERGY MATERIALS (2022)
A highly efficient and informative method to identify ion transport networks in fast ion conductors
Bing He et al.
ACTA MATERIALIA (2021)
Fast Li-Ion Conductivity in Superadamantanoid Lithium Thioborate Halides
Kavish Kaup et al.
ANGEWANDTE CHEMIE-INTERNATIONAL EDITION (2021)
Towards prediction of ordered phases in rechargeable battery chemistry via group-subgroup transformation
Yunbing Ran et al.
NPJ COMPUTATIONAL MATERIALS (2021)
Fast Ion-Conducting Thioboracite with a Perovskite Topology and Argyrodite-like Lithium Substructure
Kavish Kaup et al.
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (2021)
High-throughput screening platform for solid electrolytes combining hierarchical ion-transport prediction algorithms
Bing He et al.
SCIENTIFIC DATA (2020)
CAVD, towards better characterization of void space for ionic transport analysis
Bing He et al.
SCIENTIFIC DATA (2020)
Combining Superionic Conduction and Favorable Decomposition Products in the Crystalline Lithium-Boron-Sulfur System: A New Mechanism for Stabilizing Solid Li-Ion Electrolytes
Austin D. Sendek et al.
ACS APPLIED MATERIALS & INTERFACES (2020)
A Database of Ionic Transport Characteristics for Over 29 000 Inorganic Compounds
Liwen Zhang et al.
ADVANCED FUNCTIONAL MATERIALS (2020)
Ionic conduction mechanism of a lithium superionic argyrodite in the Li-Al-Si-S-O system
Wenze Huang et al.
MATERIALS ADVANCES (2020)
Superionic lithium conductor with a cubic argyrodite-type structure in the Li-Al-Si-S system
Wenze Huang et al.
JOURNAL OF SOLID STATE CHEMISTRY (2019)
Machine Learning-Assisted Discovery of Solid Li-Ion Conducting Materials
Austin D. Sendek et al.
CHEMISTRY OF MATERIALS (2019)
A theoretical study on the stability and ionic conductivity of the Na11M2PS12 (M = Sn, Ge) superionic conductors
Jiapeng Liu et al.
JOURNAL OF POWER SOURCES (2019)
Revisiting the ionic diffusion mechanism in Li3PS4 via the joint usage of geometrical analysis and bond valence method
Li Pan et al.
JOURNAL OF MATERIOMICS (2019)
Statistical variances of diffusional properties from ab initio molecular dynamics simulations
Xingfeng He et al.
NPJ COMPUTATIONAL MATERIALS (2018)
Holistic computational structure screening of more than 12 000 candidates for solid lithium-ion conductor materials
Austin D. Sendek et al.
ENERGY & ENVIRONMENTAL SCIENCE (2017)
Lithium battery chemistries enabled by solid-state electrolytes
Arumugam Manthiram et al.
NATURE REVIEWS MATERIALS (2017)
Superionic Conductors: Li10+δ[SnySi1-y]1+δP2-δS12 with a Li10GeP2S12-type Structure in the Li3PS4-Li4SnS4-Li4SiS4 Quasi-ternary System
Yulong Sun et al.
CHEMISTRY OF MATERIALS (2017)
Direct Observation of the Interfacial Instability of the Fast Ionic Conductor Li10GeP2S12 at the Lithium Metal Anode
Sebastian Wenzel et al.
CHEMISTRY OF MATERIALS (2016)
High-power all-solid-state batteries using sulfide superionic conductors
Yuki Kato et al.
NATURE ENERGY (2016)
Python Materials Genomics (pymatgen): A robust, open-source python library for materials analysis
Shyue Ping Ong et al.
COMPUTATIONAL MATERIALS SCIENCE (2013)
Materials Design and Discovery with High-Throughput Density Functional Theory: The Open Quantum Materials Database (OQMD)
James E. Saal et al.
JOM (2013)
Commentary: The Materials Project: A materials genome approach to accelerating materials innovation
Anubhav Jain et al.
APL MATERIALS (2013)
Electron structure of the equilibrium and metastable phases in superionic Li2SiS3
D. I. Bletskan et al.
SEMICONDUCTOR PHYSICS QUANTUM ELECTRONICS & OPTOELECTRONICS (2013)
First Principles Study of the Li10GeP2S12 Lithium Super Ionic Conductor Material
Yifei Mo et al.
CHEMISTRY OF MATERIALS (2012)
A lithium superionic conductor
Noriaki Kamaya et al.
NATURE MATERIALS (2011)