Role of Na+ Interstitials and Dopants in Enhancing the Na+ Conductivity of the Cubic Na3PS4 Superionic Conductor

Zhu, Zhuoying; Chu, Iek‐Heng; Deng, Zhi; Ong, Shyue Ping

doi:10.1021/acs.chemmater.5b03656

Cited by 236 publications

(267 citation statements)

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“…However, studies of new sulfide Na + ion conductors are few. A first-principles calculation indicates that Sn-doped cubic Na3PS4 is predicted to have a higher Na + ion conductivity of 10 −2 S cm −1 (Zhu et al, 2015). Synthesis of SEs with a favorable structure for Na + ion conduction based on calculation results is important for finding new Na + ion conducting SEs.…”

Section: Conductivitymentioning

confidence: 99%

Development of Sulfide Solid Electrolytes and Interface Formation Processes for Bulk-Type All-Solid-State Li and Na Batteries

2016

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All-solid-state batteries with inorganic solid electrolytes (SEs) are recognized as an ultimate goal of rechargeable batteries because of their high safety, versatile geometry, and good cycle life. Compared with thin-film batteries, increasing the reversible capacity of bulk-type all-solid-state batteries using electrode active material particles is difficult because contact areas at solid-solid interfaces between the electrode and electrolyte particles are limited. Sulfide SEs have several advantages of high conductivity, wide electrochemical window, and appropriate mechanical properties, such as formability, processability, and elastic modulus. Sulfide electrolyte with Li7P3S11 crystal has a high Li + ion conductivity of 1.7 × 10 −2 S cm −1 at 25°C. It is far beyond the Li + ion conductivity of conventional organic liquid electrolytes. The Na + ion conductivity of 7.4 × 10 −4 S cmis achieved for Na3.06P0.94Si0.06S4 with cubic structure. Moreover, formation of favorable solid-solid interfaces between electrode and electrolyte is important for realizing solid-state batteries. Sulfide electrolytes have better formability than oxide electrolytes. Consequently, a dense electrolyte separator and closely attached interfaces with active material particles are achieved via "room-temperature sintering" of sulfides merely by cold pressing without heat treatment. Elastic moduli for sulfide electrolytes are smaller than that of oxide electrolytes, and Na2S-P2S5 glass electrolytes have smaller Young's modulus than Li2S-P2S5 electrolytes. Cross-sectional SEM observations for a positive electrode layer reveal that sulfide electrolyte coating on active material particles increases interface areas even with a minimum volume of electrolyte, indicating that the energy density of bulk-type solid-state batteries is enhanced. Both surface coating of electrode particles and preparation of nanocomposite are effective for increasing the reversible capacity of the batteries. Our approaches to form solid-solid interfaces are demonstrated.

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Section: Conductivitymentioning

confidence: 99%

Development of Sulfide Solid Electrolytes and Interface Formation Processes for Bulk-Type All-Solid-State Li and Na Batteries

2016

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“…The values of s i for Li 4 It is possible to use molecular dynamics results in a more quantitative analysis of ionic conductivity following the approach implemented by Mo, Ong, and others. [32][33][34][35] For a molecular dynamics simulation at temperature T with resultant ion trajectories {r i (t)} as a function of time t, one can calculate the mean squared displacement and use Einstein's expression to determine the diffusion constant D trace (T ):…”

Section: Molecular Dynamics Simulationsmentioning

confidence: 99%

“…The simulation results reported here should be regarded as preliminary, due to the relatively small number of configurations sampled. Previous work of this sort [32][33][34][35] was based on simulation times 10-100 times as long as our 3-8 ps simulations. For these reasons, the least squares fit lines through the simulated results for log(T σ) versus 1000/T should be considered with large error bars.…”

Section: Molecular Dynamics Simulationsmentioning

confidence: 99%

Li₄SnS₄and Li₄SnSe₄: Simulations of Their Structure and Electrolyte Properties

Al-Qawasmeh

Howard

Holzwarth

2017

J. Electrochem. Soc.

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Recent experimental literature reports the solid state electrolyte properties of Li 4 SnS 4 and Li 4 SnSe 4 , identifying interesting questions regarding their structural details and motivating our first principles simulations. Together with Li 4 GeS 4 , these materials are all characterized by the orthorhombic space group Pnma and are found to be isostructural. They have a ground state crystal structure (denoted Li 4 SnS 0 4 ) having interstitial sites in void channels along the c-axis. They also have a meta-stable structure (denoted Li 4 SnS * 4 ) which is formed by moving one fourth of the Li ions from their central sites to the interstitial positions, resulting in a 0.5 Å contraction of the a lattice parameter. Relative to their ground states, the meta-stable structures are found to have energies 0.25 eV, 0.02 eV, and 0.07 eV for Li 4 From this literature, some interesting questions arise regarding crystal structures and mechanisms for ion mobility. In order to address these questions, we use first principles methods to examine the ideal crystal forms and defect structures of Li 4 SnS 4 and the structurally and chemically related materials Li 4 GeS 4 and Li 4 SnSe 4 . For each of these materials, we identify two closely related structures -an ideal ground state structure and an ideal meta-stable structure. The simulations show that the meta-stable structural form is most accessible to Li 4 SnS 4 of the three materials studied. The simulations are extended to study mechanisms of Li ion migration in both Li 4 SnS 4 and Li 4 SnSe 4 and are related to the experimental results reported in the literature. Computational MethodsThe computational methods used in this work are based on density functional theory (DFT), 8,9 using the projected augmented wave (PAW) 10 formalism. The PAW basis and projector functions were generated by the ATOMPAW 11 code and the crystalline materials were modeled using the QUANTUM ESPRESSO 12 and ABINIT 13 packages. Visualizations were constructed using the XCrySDEN, 14 The exchange correlation function is approximated using the localdensity approximation (LDA). 17 The choice of LDA functional was made based on previous investigations 18-20 of similar materials which showed that, provided that the lattice constants are scaled by a correction factor of 1.02, the simulations are in good agreement with experiment, especially lattice vibrational frequencies and heats of formation. The partial densities of states were calculated as described in previous work, 20,21 using weighting factors based on the charge within the augmentation spheres of each atom with radii r The calculations were well converged with plane wave expansions of the wave function including |k + G| 2 ≤ 64 bohr −2 . Calculations for the conventional unit cells were performed using a Brillouin-zone sampling grid of 4 × 8 × 8. Simulations of Li ion migration were performed at constant volume in supercells constructed from the optimized conventional cells extended by 1 × 2 × 2 and a Brillouin-zone sampling grid of 2 × 2 × 2. In ...

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“…Nevertheless, there have been recent successes in computational dopant optimizations for solid electrolyte materials. 113,130 Despite significant progress, existing computational methods for probing alkali diffusion-ab initio and classical MDs, transition state theory and kinetic Monte Carlo (KMC)-all suffer from various limitations. Ab initio methods, such as NEB and AIMD, tend to be computationally expensive, whereas methods that depend on empirical or fitted potentials, such as classical MD and KMC, while much cheaper computationally, are difficult to transfer between chemistries and structures.…”

Section: Computational Studies Of Alkali Conduction Z Deng Et Almentioning

confidence: 99%

“…[127][128][129] Using AIMD simulations, Zhu et al 130 showed that the pristine c-Na 3 PS 4 is in fact a poor alkali conductor at room temperature, and it is only with the introduction of Na + interstitials that the Na + conductivity approaches the levels observed experimentally. They further proposed Sn doping as a potential strategy to further enhance the conductivity in this material, but this prediction has yet to be verified experimentally.…”

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confidence: 99%

Computational studies of solid-state alkali conduction in rechargeable alkali-ion batteries

Deng

Ong

2016

NPG Asia Mater

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The facile conduction of alkali ions in a crystal host is of crucial importance in rechargeable alkali-ion batteries, the dominant form of energy storage today. In this review, we provide a comprehensive survey of computational approaches to study solid-state alkali diffusion. We demonstrate how these methods have provided useful insights into the design of materials that form the main components of a rechargeable alkali-ion battery, namely the electrodes, superionic conductor solid electrolytes and interfaces. We will also provide a perspective on future challenges and directions. The scope of this review includes the monovalent lithium-and sodium-ion chemistries that are currently of the most commercial interest. NPG Asia Materials (2016) 8, e254; doi:10.1038/am.2016.7; published online 25 March 2016 INTRODUCTIONThe facile conduction of alkali ions in a crystal is of critical importance in energy storage. Today, the dominant form of energy storage in consumer electronics is the rechargeable lithium-ion (Li-ion) battery, 1-5 a device that functions entirely on the basis of the reversible transport of Li + ions. With one of the highest energy densities of known energy storage technologies, Li-ion batteries are finding increasingly large-scale applications in electrified transportation and grid storage. In recent years, there has also been a resurgence of interest in rechargeable sodium-ion (Na-ion) batteries, 6-12 which function on the same basic principle but with Na + instead of Li + because of concerns regarding the abundance and cost of lithium. Figure 1 shows a representation of a rechargeable alkali-ion battery. The typical electrode in an alkali-ion battery is an intercalation compound, which, as the name implies, stores alkali ions by inserting them into its crystal structure in a topotactic manner. During discharge, A + ions are transported from the anode, through the electrolyte and into the cathode. The reverse happens during charge. Throughout this review, we will adopt the customary terminology of defining the 'cathode' as the positive electrode during discharge, even though the formal definition of the cathode changes depending on whether the charging or discharging process is being referred to. Current cathodes are typically transition metal oxides, and the insertion/removal of each A + in the cathode is accompanied by the concomitant reduction/oxidation of a transition metal ion to accommodate the compensating insertion/removal of an electron. Graphitic carbon is the most common anode.The performance of a rechargeable alkali-ion battery depends crucially on the ease with which alkali ions move in the host crystal of the cathode and anode, in the electrolyte, and in the electrodeelectrolyte interface. Poor alkali transport in any part of the battery

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Role of Na⁺ Interstitials and Dopants in Enhancing the Na⁺ Conductivity of the Cubic Na₃PS₄ Superionic Conductor

Cited by 236 publications

References 52 publications

Development of Sulfide Solid Electrolytes and Interface Formation Processes for Bulk-Type All-Solid-State Li and Na Batteries

Development of Sulfide Solid Electrolytes and Interface Formation Processes for Bulk-Type All-Solid-State Li and Na Batteries

Li₄SnS₄and Li₄SnSe₄: Simulations of Their Structure and Electrolyte Properties

Computational studies of solid-state alkali conduction in rechargeable alkali-ion batteries

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Role of Na+ Interstitials and Dopants in Enhancing the Na+ Conductivity of the Cubic Na3PS4 Superionic Conductor

Cited by 236 publications

References 52 publications

Development of Sulfide Solid Electrolytes and Interface Formation Processes for Bulk-Type All-Solid-State Li and Na Batteries

Development of Sulfide Solid Electrolytes and Interface Formation Processes for Bulk-Type All-Solid-State Li and Na Batteries

Li4SnS4and Li4SnSe4: Simulations of Their Structure and Electrolyte Properties

Computational studies of solid-state alkali conduction in rechargeable alkali-ion batteries

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Role of Na⁺ Interstitials and Dopants in Enhancing the Na⁺ Conductivity of the Cubic Na₃PS₄ Superionic Conductor

Li₄SnS₄and Li₄SnSe₄: Simulations of Their Structure and Electrolyte Properties