Manufacturing scalability implications of materials choice in inorganic solid-state batteries

Huang, Kevin; Ceder, Gerbrand; Olivetti, Elsa

doi:10.1016/j.joule.2020.12.001

Cited by 38 publications

(24 citation statements)

References 106 publications

(129 reference statements)

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“…Other factors that have been identified as pivotal for the manufacturing scalability of inorganic solid‐state cells are: i) the materials availability and price, ii) the required manufacturing processes due to materials selected, and iii) the expected performances of those materials. [ 34 ] The higher the cell energy density, the lower the production cost for each kWh, identifying the cell design as a crucial trade‐off. The examined examples of solid‐state cells including common solid electrolytes such as Li 7 La 3 Zr 2 O 12 (LLZO), Li 10 GeP 2 S 12 (LGPS), and Li 6 PS 5 Cl, and the analyses carried out on cost and performances have highlighted that the scaling of low‐cost, high performance cells can fail if the materials supply chain is strongly constrained.…”

Section: Post Li‐ion Cell Technologiesmentioning

confidence: 99%

“…Moreover, in the hypothesis that materials are readily available, the scaling might fail if those materials require costly and cumbersome manufacturing procedures during cell integration. [ 34 ] Large‐scale production of polymer‐based cells has been proven similar to conventional LIBs [ 20 ] therefore mostly compatible in terms of cell production infrastructure. On the other hand, the industrialization of solid‐state batteries containing sulfides or moisture sensitive oxides as electrolytes may present technical challenges requiring new manufacturing machinery.…”

Section: Post Li‐ion Cell Technologiesmentioning

confidence: 99%

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Solid‐State Post Li Metal Ion Batteries: A Sustainable Forthcoming Reality?

Ferrari

Falco

Muñoz‐García

et al. 2021

Advanced Energy Materials

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In the quest for a sustainable society, energy storage technology is destined to play a central role in the future energy landscape. Breakthroughs in materials and methods involving sustainable resources are crucial to protect humankind from the most serious consequences of climate change. Rechargeable batteries of all forms will be required to follow the path. Elements that are eligible to harmonically contribute to the development of a sustainable ecosystem and fulfil the demands of high energy density batteries include Na, K, Ca, Mg, Zn, and Al. Numerous research efforts are underway to explore new battery chemistries based on these elements and, depending on the field of application, different elements inherit different advantages and challenges. Full sustainability implies that the environmental friendliness of these systems must be characterized by a “cradle‐to‐grave” approach. In this context, the pursuit of global environmental and economical sustainability from mass production, raw materials, and technical challenges is discussed herein for the most recent battery concepts based on monovalent and multivalent metal anodes. A perspective on strategies and opportunities particularly around the development of all‐solid‐state system configurations is provided, and the most important obstacles to overcome in search of a more sustainable future for electrochemical energy storage are addressed.

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Section: Post Li‐ion Cell Technologiesmentioning

confidence: 99%

Section: Post Li‐ion Cell Technologiesmentioning

confidence: 99%

Solid‐State Post Li Metal Ion Batteries: A Sustainable Forthcoming Reality?

Ferrari

Falco

Muñoz‐García

et al. 2021

Advanced Energy Materials

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show abstract

“…Although the presence of Na‐vacancies may provide a significant “add‐on” to the enhancement of ionic conductivity, its implication on the activation energy is not straightforward. This is evidenced by the measured activation energies, 0.21 and 0.18 eV, of the cubic Na 2.88 W 0.12 Sb 0.88 S 4 and Na 2.9 W 0.1 Sb 0.9 S 4 , respectively, [6, 7] which are much larger than that (≤0.08 eV) of the cubic phase of Na 3 SbS 4 [53, 67] . The activation energy, corresponding to the energy barrier of individual diffusion steps, should be largely determined by the local Na‐Na and Na‐S interactions in the system.…”

Section: Introductionmentioning

confidence: 95%

“…Here, we tune the structure and the resultant ionic conductivity/activation energy of W‐doped Na 3 SbS 4 by greatly extending the W content, going far beyond the 10–12 % reported in the previous studies [6, 7] . A heavily W‐doped system Na 2.7 W 0.3 Sb 0.7 S 4 , is successfully synthesized, and is demonstrated to display an orthorhombic structure.…”

Section: Introductionmentioning

confidence: 99%

“…Employing solid‐state electrolytes (SSEs) rather than liquid organic electrolytes is a possible path towards greater battery safety since most inorganic SSEs are non‐flammable [1–19] . Recently, there has been significant progress related to a number of successful solid‐state battery chemistries showing reasonable cycle‐life and capacity retention using traditional cathodes of Li‐ion battery (LIB) and metal anodes [20, 21] .…”

Section: Introductionmentioning

confidence: 99%

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Heavily Tungsten‐Doped Sodium Thioantimonate Solid‐State Electrolytes with Exceptionally Low Activation Energy for Ionic Diffusion

et al. 2021

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A strategy for modifying the structure of solid‐state electrolytes (SSEs) to reduce the cation diffusion activation energy is presented. Two heavily W‐doped sodium thioantimonate SSEs, Na2.895W0.3Sb0.7S4 and Na2.7W0.3Sb0.7S4 are designed, both exhibiting exceptionally low activation energy and enhanced room temperature (RT) ionic conductivity; 0.09 eV, 24.2 mS/cm and 0.12 eV, 14.5 mS/cm. At −15 °C the Na2.895W0.3Sb0.7S4 displays a total ionic conductivity of 5.5 mS/cm. The 30 % W content goes far beyond the 10–12 % reported in the prior studies, and results in novel pseudo‐cubic or orthorhombic structures. Calculations reveal that these properties result from a combination of multiple diffusion mechanisms, including vacancy defects, strongly correlated modes and excessive Na‐ions. An all‐solid‐state battery (ASSB) using Na2.895W0.3Sb0.7S4 as the primary SSE and a sodium sulfide (Na2S) cathode achieves a reversible capacity of 400 mAh g−1.

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Sodium Solid‐state Batteries

Quérel¹,

Aguadero²

2022

Sodium‐Ion Batteries

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Manufacturing scalability implications of materials choice in inorganic solid-state batteries

Cited by 38 publications

References 106 publications

Solid‐State Post Li Metal Ion Batteries: A Sustainable Forthcoming Reality?

Solid‐State Post Li Metal Ion Batteries: A Sustainable Forthcoming Reality?

Heavily Tungsten‐Doped Sodium Thioantimonate Solid‐State Electrolytes with Exceptionally Low Activation Energy for Ionic Diffusion

Sodium Solid‐state Batteries

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