scholarly journals The Role of Areal Capacity in Determining Short Circuiting of Sulfide-Based Solid-State Batteries

2021 ◽  
Author(s):  
John Lewis ◽  
Chanhee Lee ◽  
Yuhgene Liu ◽  
Sang Yun Han ◽  
Dhruv Prakash ◽  
...  
Keyword(s):  
Solid State ◽  
Current Density ◽  
Specific Energy ◽  
Research Effort ◽  
Short Circuit ◽  
Lithium Ion ◽  
Solid State Batteries ◽  
Current Densities ◽  
High Specific Energy ◽  
Areal Capacity

Solid-state batteries (SSBs) with lithium metal anodes offer higher specific energy than conventional lithium-ion batteries, but they must utilize areal capacities >3 mAh cm-2 and cycle at current densities >3 mA cm-2 to achieve commercial viability. Substantial research effort has focused on increasing rate capabilities of SSBs by mitigating detrimental processes such as lithium filament penetration. Less attention has been paid to understanding how areal capacity impacts plating/stripping behavior, despite the importance of areal capacity for achieving high specific energy. Here, we investigate and quantify the relationships among areal capacity, current density, and plating/stripping stability using both symmetric and full-cell configurations with a sulfide solid-state electrolyte (Li6PS5Cl). We show that unstable deposition and short circuiting readily occur at rates much lower than the measured critical current density when a sufficient areal capacity is passed. A systematic study of continuous plating under different electrochemical conditions reveals average “threshold capacity” values at different current densities, beyond which short circuiting occurs. Cycling cells below this threshold capacity significantly enhances cell lifetime, enabling stable symmetric cell cycling at 2.2 mA cm-2 without short circuiting. Finally, we show that full cells also exhibit threshold capacity behavior, but they tend to short circuit at lower current densities and areal capacities. Our results quantify the effects of transferred capacity and demonstrate the importance of using realistic areal capacities in experiments to develop viable solid-state batteries.

Recent advances in the sulfide electrolytes toward high specific energy solid-state lithium batteries

2021 ◽  
Author(s):  
Tao Yu ◽  
Bingyu Ke ◽  
Haoyu Li ◽  
Shaohua Guo ◽  
Haoshen Zhou
Keyword(s):  
Solid State ◽  
Energy Density ◽  
Specific Energy ◽  
Lithium Batteries ◽  
Lithium Ion ◽  
Liquid Lithium ◽  
Specific Energy Density ◽  
Solid State Batteries ◽  
All Solid State Batteries ◽  
High Specific Energy

All solid-state batteries (ASSBs) have gained extensive attention due to the improved safety, and high specific energy density compared with conventional liquid lithium-ion batteries. As the key component of ASSBs,...

scholarly journals Chemical Tuning of NaSICON Surfaces for Fast-Charging Na Metal Solid-State Batteries

2021 ◽  
Author(s):  
Edouard Querel ◽  
Ieuan Seymour ◽  
Andrea Cavallaro ◽  
Qianli Ma ◽  
Frank Tietz ◽  
...  
Keyword(s):  
Solid State ◽  
Great Promise ◽  
Interface Engineering ◽  
Additional Advantage ◽  
Fast Charging ◽  
Thermodynamic Stabilization ◽  
Solid State Batteries ◽  
Current Densities ◽  
Li Ion ◽  
Areal Capacity

<p>Solid-state batteries (SSBs) with alkali metal anodes hold great promise as energetically dense and safe alternatives to conventional Li-ion cells. Whilst, in principle, SSBs have the additional advantage of offering virtually unlimited plating current densities, fast charges have so far only been achieved through sophisticated interface engineering strategies. Here, we reveal that such interface engineering can be easily achieved by tuning the chemistry of NaSICON solid electrolytes (Na<sub>3.4</sub>Zr<sub>2</sub>Si<sub>2.4</sub>P<sub>0.6</sub>O<sub>12</sub>) and taking advantage of the thermodynamic stabilization of a Na<sub>3</sub>PO<sub>4</sub> layer on their surface upon thermal activation. The optimized planar Na|NZSP interfaces are characterized by their exceptionally low interface resistances (down to 0.1 Ω cm<sup>2 </sup>at room temperature) and, more importantly, by their tolerance to large plating current densities (up to 10 mA cm<sup>-2</sup>) even for extended cycling periods of 30 minutes (corresponding to an areal capacity 5 mAh cm<sup>-2</sup>).</p>

scholarly journals On the Feasibility of All-solid-state Batteries with LLZO as a Single Electrolyte

2021 ◽  
Author(s):  
Kostiantyn V. Kravchyk ◽  
Dogan Tarik Karabay ◽  
Maksym V. Kovalenko
Keyword(s):  
Solid State ◽  
Electronic Conductivity ◽  
Lithium Ion ◽  
Metal Anode ◽  
Solid State Batteries ◽  
Li Ion ◽  
All Solid State Batteries ◽  
Battery Discharge ◽  
Power Densities ◽  
Areal Capacity

Abstract Replacement of Li-ion liquid-state electrolytes by solid-state counterparts in a Li-ion battery (LIB) is a major research objective as well as an urgent priority for the industry, as it enables the use of a Li metal anode and provides new opportunities to realize safe, non-flammable, and temperature-resilient batteries. Among the plethora of solid-state electrolytes (SSEs) investigated, garnet-type Li-ion electrolytes based on cubic Li7La3Zr2O12 (LLZO) are considered the most appealing candidates for the development of future solid-state batteries because of their low electronic conductivity of ca. 10−8 S cm−1 (RT) and a wide electrochemical operation window of 0 ‒ 6 V vs. Li+/Li. However, high LLZO density (5.1 g cm-3) and its lower level of Li-ion conductivity (up to 1 mS cm−1 at RT) compared to liquid electrolytes (1.28 g cm-3; ca. 10 mS cm−1 at RT) still raise the question as to the feasibility of using solely LLZO as an electrolyte for achieving competitive energy and power densities. In this work, we analyzed the energy densities of Li-garnet all-solid-state batteries based solely on LLZO SSE by modeling their Ragone plots using LiCoO2 as the model cathode material. This assessment allowed us to identify values of the LLZO thickness, cathode areal capacity, and LLZO content in the solid-state cathode required to match the energy density of conventional lithium-ion batteries (ca. 180 Wh kg-1 and 497 Wh L-1) at the power densities of 200 W kg-1 and 600 W L-1, corresponding to ca. 1h of battery discharge time (1C). We then discuss key challenges in the practical deployment of LLZO SSE in the fabrication of Li-garnet all-solid-state batteries.

Experimental Assessment of the Practical Oxidative Stability of Lithium Thiophosphate Solid Electrolytes

2019 ◽  
Author(s):  
Georg Dewald ◽  
Saneyuki Ohno ◽  
Marvin Kraft ◽  
Raimund Koerver ◽  
Paul Till ◽  
...  
Keyword(s):  
Cyclic Voltammetry ◽  
Solid State ◽  
Oxidative Stability ◽  
Photoelectron Spectroscopy ◽  
Solid Electrolytes ◽  
Stability Limit ◽  
Lithium Ion ◽  
High Energy ◽  
Redox Activity ◽  
Solid State Batteries

<p>All-solid-state batteries are often expected to replace conventional lithium-ion batteries in the future. However, the practical electrochemical and cycling stability of the best-conducting solid electrolytes, i.e. lithium thiophosphates, are still critical issues that prevent long-term stable high-energy cells. In this study, we use <i>stepwise</i><i>cyclic voltammetry </i>to obtain information on the practical oxidative stability limit of Li<sub>10</sub>GeP<sub>2</sub>S<sub>12</sub>, a Li<sub>2</sub>S‑P<sub>2</sub>S<sub>5</sub>glass, as well as the argyrodite Li<sub>6</sub>PS<sub>5</sub>Cl solid electrolytes. We employ indium metal and carbon black as the counter and working electrode, respectively, the latter to increase the interfacial contact area to the electrolyte as compared to the commonly used planar steel electrodes. Using a stepwise increase in the reversal potentials, the onset potential at 25 °C of oxidative decomposition at the electrode-electrolyte interface is identified. X‑ray photoelectron spectroscopy is used to investigate the oxidation of sulfur(-II) in the thiophosphate polyanions to sulfur(0) as the dominant redox process in all electrolytes tested. Our results suggest that after the formation of these decomposition products, significant redox behavior is observed. This explains previously reported redox activity of thiophosphate solid electrolytes, which contributes to the overall cell performance in solid-state batteries. The <i>stepwise cyclic voltammetry</i>approach presented here shows that the practical oxidative stability at 25 °C of thiophosphate solid electrolytes against carbon is kinetically higher than predicted by thermodynamic calculations. The method serves as an efficient guideline for the determination of practical, kinetic stability limits of solid electrolytes. </p>

Experimental Assessment of the Practical Oxidative Stability of Lithium Thiophosphate Solid Electrolytes

2019 ◽  
Author(s):  
Georg Dewald ◽  
Saneyuki Ohno ◽  
Marvin Kraft ◽  
Raimund Koerver ◽  
Paul Till ◽  
...  
Keyword(s):  
Cyclic Voltammetry ◽  
Solid State ◽  
Oxidative Stability ◽  
Photoelectron Spectroscopy ◽  
Solid Electrolytes ◽  
Stability Limit ◽  
Lithium Ion ◽  
High Energy ◽  
Redox Activity ◽  
Solid State Batteries

<p>All-solid-state batteries are often expected to replace conventional lithium-ion batteries in the future. However, the practical electrochemical and cycling stability of the best-conducting solid electrolytes, i.e. lithium thiophosphates, are still critical issues that prevent long-term stable high-energy cells. In this study, we use <i>stepwise</i><i>cyclic voltammetry </i>to obtain information on the practical oxidative stability limit of Li<sub>10</sub>GeP<sub>2</sub>S<sub>12</sub>, a Li<sub>2</sub>S‑P<sub>2</sub>S<sub>5</sub>glass, as well as the argyrodite Li<sub>6</sub>PS<sub>5</sub>Cl solid electrolytes. We employ indium metal and carbon black as the counter and working electrode, respectively, the latter to increase the interfacial contact area to the electrolyte as compared to the commonly used planar steel electrodes. Using a stepwise increase in the reversal potentials, the onset potential at 25 °C of oxidative decomposition at the electrode-electrolyte interface is identified. X‑ray photoelectron spectroscopy is used to investigate the oxidation of sulfur(-II) in the thiophosphate polyanions to sulfur(0) as the dominant redox process in all electrolytes tested. Our results suggest that after the formation of these decomposition products, significant redox behavior is observed. This explains previously reported redox activity of thiophosphate solid electrolytes, which contributes to the overall cell performance in solid-state batteries. The <i>stepwise cyclic voltammetry</i>approach presented here shows that the practical oxidative stability at 25 °C of thiophosphate solid electrolytes against carbon is kinetically higher than predicted by thermodynamic calculations. The method serves as an efficient guideline for the determination of practical, kinetic stability limits of solid electrolytes. </p>

scholarly journals Insights into interfacial effect and local lithium-ion transport in polycrystalline cathodes of solid-state batteries

2020 ◽  
Vol 11 (1) ◽  
Author(s):  
Shuaifeng Lou ◽  
Qianwen Liu ◽  
Fang Zhang ◽  
Qingsong Liu ◽  
Zhenjiang Yu ◽  
...  
Keyword(s):  
Solid State ◽  
Ion Transport ◽  
Chemical Potential ◽  
Lithium Ion ◽  
Local Environment ◽  
Underlying Mechanism ◽  
Transport Kinetics ◽  
Potential Force ◽  
Interfacial Contact ◽  
Solid State Batteries

Abstract Interfacial issues commonly exist in solid-state batteries, and the microstructural complexity combines with the chemical heterogeneity to govern the local interfacial chemistry. The conventional wisdom suggests that “point-to-point” ion diffusion at the interface determines the ion transport kinetics. Here, we show that solid-solid ion transport kinetics are not only impacted by the physical interfacial contact but are also closely associated with the interior local environments within polycrystalline particles. In spite of the initial discrete interfacial contact, solid-state batteries may still display homogeneous lithium-ion transportation owing to the chemical potential force to achieve an ionic-electronic equilibrium. Nevertheless, once the interior local environment within secondary particle is disrupted upon cycling, it triggers charge distribution from homogeneity to heterogeneity and leads to fast capacity fading. Our work highlights the importance of interior local environment within polycrystalline particles for electrochemical reactions in solid-state batteries and provides crucial insights into underlying mechanism in interfacial transport.

scholarly journals Modification and regulation of electrode/electrolyte interface for high specific energy and long life lithium ion batteries

2021 ◽  
Vol 66 (10) ◽  
pp. 1170-1186
Author(s):  
Xuerui Yang ◽  
Ningbo Xu ◽  
Gaopan Liu ◽  
Yue Zou ◽  
Zhongru Zhang ◽  
...  
Keyword(s):  
Lithium Ion Batteries ◽  
Specific Energy ◽  
Lithium Ion ◽  
Electrolyte Interface ◽  
Long Life ◽  
High Specific Energy
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