Operating High‐Energy Lithium‐Metal Pouch Cells with Reduced Stack Pressure Through a Rational Lithium‐Host Design

Ren, Yuxun; Shin, Woochul; Manthiram, Arumugam

doi:10.1002/aenm.202200190

Cited by 11 publications

(6 citation statements)

References 79 publications

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“…110,111 To maintain dense contact in traditional ASSBs, an extremely high stacking pressure is usually employed in the cell fabrication and cycling process. 105,112 However, for Li-based ASSBs, it is pivotal to search for reasonable stack pressure values that determine whether the battery can work efficiently. Low bulk pressure is not sufficient to achieve tight contact between interfaces while too high stack pressure might cause severe creeping of Li metal.…”

Section: Interface Issuesmentioning

confidence: 99%

Insights into interfacial physiochemistry in sulfide solid-state batteries: a review

Zheng¹,

Zhu²,

Wang³

et al. 2023

Mater. Chem. Front.

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Section: Interface Issuesmentioning

confidence: 99%

Insights into interfacial physiochemistry in sulfide solid-state batteries: a review

Zheng¹,

Zhu²,

Wang³

et al. 2023

Mater. Chem. Front.

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“…The high-energy pouch-type LMBs can be operated with a reduced stack pressure through rational host design. [171] A pressure self-adaptable Li composite anode is able to regulate the Li plating/stripping behaviors inside the anodes. [25] The adaptive pressure generated from the elastic polymer filled inside the conductive host renders continuous electronic pathways inside the anodes and restricts the growth of Li dendrites.…”

Section: Tailoring Host Structuresmentioning

confidence: 99%

Working Principles of Lithium Metal Anode in Pouch Cells

Sun

Cheng

et al. 2022

Advanced Energy Materials

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Advanced energy storage technology represented by lithium (Li)-ion batteries (LIBs) has revolutionized human life in recent years. The energy density of LIBs based on intercalation chemistry is approaching its theoretical limit after unremitting efforts for the past three decades. The state-of-the-art LIBs with graphite anode can only achieve an energy density lower than 300 Wh kg −1 . [1] This cannot satisfy the increasing demands for portable electronic devices, electric vehicles, and stationary energy storage systems. [2] Therefore, it is urgently called for next-generation batteries with a high energy density, long lifespan, and high safety performance. [3,4] Electrode material is of great importance in determining the energy density of batteries. [5] As the holy grail anode, Li metal possesses the ultrahigh theoretical specific capacity (3860 mAh g −1 ) and low potential (−3.04 V vs the standard hydrogen electrode). The promising feature renders Li metal anode to be an indispensable candidate for constructing next-generation high-energy-density batteries. [6] A high energy density of 400 or even 500 Wh kg −1 can be achieved with Li metal batteries (LMBs) matching Ni-rich LiNi x Co y Mn (1−x−y) O 2 (0 < x, y <1), oxygen, or sulfur cathodes, etc. [7][8][9] However, the conversion chemistry and high reactivity of Li metal also bring great challenges to the design of robust LMBs with long lifespan and high safety. [10,11] Specifically, Li dendrite growth and infinite volume variation lead to unstable solid electrolyte interphase (SEI) on Li metal anodes, resulting in low Li utilization, capacity decline, and even safety risk, [12] severely hindering the practical applications of LMBs. [13][14][15] Recently, extensive strategies have been exploited to control the dendrite growth of Li metal anodes, including engineering electrolytes and additives, [16] designing 3D host structures, [17][18][19] constructing artificial SEI, [20,21] applying solid-state electrolyte (SSE), [22][23][24] and adjusting operation conditions. [25] A high Coulombic efficiency (>99.9%) and long lifespan (>1000 cycles) have been reported in the materials-level coin cells. [26][27][28] Notably, Li dendrite growth is primarily driven by the kinetical limitation of Li-ion diffusion near the electrolyte/electrode interface. Serious dendrite issues can be encountered under harsh operating conditions in pouch cells, considering the accelerated consumption of Li ions at large currents and high Lithium metal battery has been considered as one of the potential candidates for next-generation energy storage systems. However, the dendrite growth issue in Li anodes results in low practical energy density, short lifespan, and poor safety performance. The strategies in suppressing Li dendrite growth are mostly conducted in materials-level coin cells, while their validity in device-level pouch cells is still under debate. It is imperative to address dendrite issues in pouch cells to realize the practical application of Li metal batteries. This review prese...

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“…[8] Additionally, the infinite volume expansion that occurs during cycling stimulates the creation of fissures in the SEI, exposing fresh Li to a lower energy barrier for Li-ion transport and exacerbating non-uniform deposition of Li. [9] Although the use of hosts [10][11][12][13] and mechanically resistant films [14][15][16] can inhibit dendrite formation, the unstable SEI remains a major barrier for LMA materials. In recent years, great efforts have been devoted to improving the stability of the LMA interface.…”

Section: Introductionmentioning

confidence: 99%

“…Although the use of hosts [ 10‐13 ] and mechanically resistant films [ 14‐16 ] can inhibit dendrite formation, the unstable SEI remains a major barrier for LMA materials. In recent years, great efforts have been devoted to improving the stability of the LMA interface.…”

Section: Introductionmentioning

confidence: 99%

Adaptive Multi‐Site Gradient Adsorption of Siloxane‐Based Protective Layers Enable High Performance Lithium‐Metal Batteries

Fang,

Wu,

Zhao

et al. 2023

Advanced Energy Materials

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Low Coulombic efficiency and significant capacity decay resulting from an unstable solid electrolyte interphase (SEI) and dendritic growth pose challenges to the practical application of lithium‐metal batteries. In this study, a highly efficient protection layer induced by octaphenylsilsesquioxane (OPS) with LiFSI salt is investigated. The OPS exhibits a strong adsorption energy with lithium, its multi‐site gradient adsorption ability enables the simultaneous capture of 8 Li+ and the uniform regulation of Li ion flux. Moreover, the mechanical strength and electronic insulation of the OPS layer induces Li deposition under the protection layer and effectively inhibits lithium dendrite growth. Such a protection layer contributes to the stable and dendrite‐free performance of a lithium‐metal battery employing LiNi0.8Co0.1Mn0.1O2 (NCM811) as a cathode and an ultrathin OPS‐protected lithium foil (20 µm) as the anode. A remarkable capacity retention of 91.4% is achieved after 300 cycles at 1C. The OPS‐protected Li anodes and NCM811 are also tested in combination with a Li1.5Al0.5Ge1.5(PO4)3 solid electrolyte, showing extended cyclability up to 300 cycles with an average Coulombic efficiency of 99.58% and capacity retention of 85.7%.

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Operating High‐Energy Lithium‐Metal Pouch Cells with Reduced Stack Pressure Through a Rational Lithium‐Host Design

Cited by 11 publications

References 79 publications

Insights into interfacial physiochemistry in sulfide solid-state batteries: a review

Insights into interfacial physiochemistry in sulfide solid-state batteries: a review

Working Principles of Lithium Metal Anode in Pouch Cells

Adaptive Multi‐Site Gradient Adsorption of Siloxane‐Based Protective Layers Enable High Performance Lithium‐Metal Batteries

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