Transport Properties and Local Ions Dynamics in LATP‐Based Hybrid Solid Electrolytes

Boaretto, Nicola; Ghorbanzade, Pedram; Perez‐Furundarena, Haritz; Meabe, Leire; López del Amo, Juan Miguel; Gunathilaka, Isuru E.; Forsyth, Maria; Schuhmacher, Jörg; Roters, Andreas; Krachkovskiy, Sergey; Guerfi, Abdelbast; Armand, Michel; Martinez‐Ibañez, María

doi:10.1002/smll.202305769

Small

2023

DOI: 10.1002/smll.202305769

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Transport Properties and Local Ions Dynamics in LATP‐Based Hybrid Solid Electrolytes

Nicola Boaretto,

Pedram Ghorbanzade,

Haritz Perez‐Furundarena

et al.

Abstract: Hybrid solid electrolytes (HSEs), namely mixtures of polymer and inorganic electrolytes, have supposedly improved properties with respect to inorganic and polymer electrolytes. In practice, HSEs often show ionic conductivity below expectations, as the high interface resistance limits the contribution of inorganic electrolyte particles to the charge transport process. In this study, the transport properties of a series of HSEs containing Li(1+x)AlxTi(2–x)(PO4)3 (LATP) as Li+‐conducting filler are analyzed. The … Show more

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2024

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Cited by 5 publications

(2 citation statements)

References 64 publications

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“…Thus, we attribute the medium-frequency process R2 to Li + transporting through the particle/liquid interface, and we attribute the high-frequency process R1 to ion transport in the bulk of both the liquid phase and LATP particles. Note that, if we assume the conductivity of the liquid phase does not change after addition of the particles, the drastic decrease of R1 with increasing LATP-T-L content is beyond the prediction of the Maxwell effective medium theory. , …”

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confidence: 88%

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Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Yu,

Tronstad,

McCloskey

2024

ACS Energy Lett.

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Understanding Li + transport in organic−inorganic hybrid electrolytes, where Li + has to lose its organic solvation shell to enter and transport through the inorganic phase, is crucial to the design of high-performance batteries. As a model system, we investigate a range of Li + -conducting particles suspended in a concentrated electrolyte. We show that large Li 1.3 Al 0.3 Ti 1.7 P 3 O 12 and Li 6 PS 5 Cl particles can enhance the overall conductivity of the electrolyte. When studying impedance using a cell with a large cell constant, the Nyquist plot shows two semicircles: a high-frequency semicircle related to ion transport in the bulk of both phases and a medium-frequency semicircle attributed to Li + transporting through the particle/liquid interfaces. Contrary to the high-frequency resistance, the medium-frequency resistance increases with particle content and shows a higher activation energy. Furthermore, we show that small particles, requiring Li + to overcome particle/liquid interfaces more frequently, are less effective in facilitating Li + transport. Overall, this study provides a straightforward approach to study the Li + transport behavior in hybrid electrolytes.

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confidence: 88%

“…Note that, if we assume the conductivity of the liquid phase does not change after addition of the particles, the drastic decrease of R1 with increasing LATP-T-L content is beyond the prediction of the Maxwell effective medium theory. 33 , 49 …”

mentioning

confidence: 99%

Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Yu,

Tronstad,

McCloskey

2024

ACS Energy Lett.

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Hybrid Ceramic Polymer Electrolytes Enabling Long Cycling in Practical 1 Ah‐Class High‐Voltage Solid‐State Batteries with Li Metal Anode

Boaretto,

Meabe,

Lindberg

et al. 2024

Adv Funct Materials

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Solid polymer electrolytes offer a safer alternative to organic liquid electrolytes in high‐voltage lithium metal batteries, yet challenges remain in achieving adequate cyclability, energy density, scalability, and safety. This study presents the cycling performance of 1 Ah high‐voltage lithium polymer batteries featuring a hybrid ceramic polymer electrolyte (HCPE), a lithium metal anode, and a LiNi0.8Mn0.1Co0.1O2 (NMC‐811)‐based positive electrode. The HCPE stands out for its remarkable mechanical properties, with a Young's modulus exceeding 200 MPa at room temperature, providing robust resistance against dendrite formation. The Li||Li symmetric cells exhibited outstanding performance, cycling for over 1000 hours at a capacity of 2 mAh cm−2, highlighting the exceptional attributes of HCPE. Full cell testing is conducted under practical conditions, utilizing various cell configurations, from coin cells to large pouch cells with a 1 Ah capacity, achieving an energy density of nearly 250 Wh kg−1 and promising cyclability with 80% capacity retention after 110 cycles. The study also investigated thermal runaway characteristics, showing comparability with commercial lithium‐ion batteries. This research underscores the scalability and performance of high‐voltage lithium metal polymer batteries, advancing their potential for commercial viability.

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Solid electrolyte manufacturing methods and its effect on SSB performance

Sasieta-Barrutia,

Blanco,

Liendo

et al. 2024

Chemical Engineering Journal

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Transport Properties and Local Ions Dynamics in LATP‐Based Hybrid Solid Electrolytes

Cited by 5 publications

References 64 publications

Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Hybrid Ceramic Polymer Electrolytes Enabling Long Cycling in Practical 1 Ah‐Class High‐Voltage Solid‐State Batteries with Li Metal Anode

Solid electrolyte manufacturing methods and its effect on SSB performance

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