Liquid‐Phase Synthesis of Halide Solid Electrolytes for All‐Solid‐State Batteries Using Organic Solvents Article Swipe

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Hirotada Gamo , Mitsunori Kitta , Nobuhiko Takeichi ·

YOU? · · 2025 · Open Access · · DOI: https://doi.org/10.1002/eem2.70184

Halide solid electrolytes (SEs) show high ionic conductivity and good compatibility with cathode active materials, providing long‐life all‐solid‐state lithium‐ion batteries (ASSLIBs). Liquid‐phase synthesis technology is a feasible option for the large‐scale manufacturing of halide SEs. However, no leading liquid‐phase synthesis method for halide SEs has been developed because of a limited understanding of the solvent effect on the formation of halide SEs. Herein, a scalable and universal liquid‐phase synthesis method for halide SEs using organic solvents is reported. The Li 3− x YCl 6− x SEs synthesized via pyridine transform trigonal structure to metastable orthorhombic structure as the Li concentration decreases, forming a highly pure orthorhombic phase with an ionic conductivity of 1.3 × 10 −4 S cm −1 at 25 °C in the composition of x = 1. Spectroscopic analysis indicates that pyridine acts as a reducing ligand, stabilizing the orthorhombic Li 2 YCl 5 by modulating the valence state of yttrium ions. Additionally, the developed synthesis method is extended to the synthesis of bromide SEs with high ionic conductivity. ASSLIBs using LiNi 0.8 Co 0.1 Mn 0.1 O 2 ‐Li 2 YCl 5 cathode composites demonstrate good cycling stability for 100 cycles. The liquid‐phase synthesis technology reported here opens opportunities for the practical manufacturing of halide‐based ASSLIBs.

Related Topics

Dissociation (Chemistry)

Concepts

Halide Orthorhombic crystal system Ionic conductivity Inorganic chemistry Electrolyte Materials science Pyridine Bromide Cathode Ionic bonding Chemical engineering Fast ion conductor Solvent Conductivity Yttrium Ionic liquid Chemistry Iodide Trifluoromethanesulfonate Anode Tin Dissociation (chemistry)

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Type: article
Language: en
Landing Page: https://doi.org/10.1002/eem2.70184
OA Status: hybrid
References: 41
OpenAlex ID: https://openalex.org/W7105664106

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DOI: https://doi.org/10.1002/eem2.70184

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Title: Liquid‐Phase Synthesis of Halide Solid Electrolytes for All‐Solid‐State Batteries Using Organic Solvents

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Language: en

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Publication year: 2025

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Publication date: 2025-11-14

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Authors: Hirotada Gamo, Mitsunori Kitta, Nobuhiko Takeichi

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Landing page: https://doi.org/10.1002/eem2.70184

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Concepts: Halide, Orthorhombic crystal system, Ionic conductivity, Inorganic chemistry, Electrolyte, Materials science, Pyridine, Bromide, Cathode, Ionic bonding, Chemical engineering, Fast ion conductor, Solvent, Conductivity, Yttrium, Ionic liquid, Chemistry, Iodide, Trifluoromethanesulfonate, Anode, Tin, Dissociation (chemistry)

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abstract_inverted_index.ions.	153
abstract_inverted_index.opens	200
abstract_inverted_index.phase	106
abstract_inverted_index.solid	1
abstract_inverted_index.state	150
abstract_inverted_index.using	73, 172
abstract_inverted_index.‐Li	181
abstract_inverted_index.Halide	0
abstract_inverted_index.active	13
abstract_inverted_index.effect	55
abstract_inverted_index.halide	33, 42, 60, 71
abstract_inverted_index.highly	103
abstract_inverted_index.method	40, 69, 158
abstract_inverted_index.option	27
abstract_inverted_index.ASSLIBs	171
abstract_inverted_index.Herein,	62
abstract_inverted_index.because	47
abstract_inverted_index.bromide	165
abstract_inverted_index.cathode	12, 185
abstract_inverted_index.cycles.	193
abstract_inverted_index.cycling	189
abstract_inverted_index.forming	101
abstract_inverted_index.leading	37
abstract_inverted_index.ligand,	138
abstract_inverted_index.limited	50
abstract_inverted_index.organic	74
abstract_inverted_index.solvent	54
abstract_inverted_index.valence	149
abstract_inverted_index.yttrium	152
abstract_inverted_index.ASSLIBs.	208
abstract_inverted_index.However,	35
abstract_inverted_index.analysis	130
abstract_inverted_index.extended	160
abstract_inverted_index.feasible	26
abstract_inverted_index.pyridine	88, 133
abstract_inverted_index.reducing	137
abstract_inverted_index.reported	198
abstract_inverted_index.scalable	64
abstract_inverted_index.solvents	75
abstract_inverted_index.trigonal	90
abstract_inverted_index.batteries	19
abstract_inverted_index.developed	46, 156
abstract_inverted_index.formation	58
abstract_inverted_index.indicates	131
abstract_inverted_index.practical	204
abstract_inverted_index.providing	15
abstract_inverted_index.reported.	77
abstract_inverted_index.stability	190
abstract_inverted_index.structure	91, 95
abstract_inverted_index.synthesis	22, 39, 68, 157, 163, 196
abstract_inverted_index.transform	89
abstract_inverted_index.universal	66
abstract_inverted_index.(ASSLIBs).	20
abstract_inverted_index.composites	186
abstract_inverted_index.decreases,	100
abstract_inverted_index.materials,	14
abstract_inverted_index.metastable	93
abstract_inverted_index.modulating	147
abstract_inverted_index.technology	23, 197
abstract_inverted_index.composition	124
abstract_inverted_index.demonstrate	187
abstract_inverted_index.long‐life	16
abstract_inverted_index.stabilizing	139
abstract_inverted_index.synthesized	86
abstract_inverted_index.conductivity	7, 110
abstract_inverted_index.electrolytes	2
abstract_inverted_index.orthorhombic	94, 105, 141
abstract_inverted_index.Additionally,	154
abstract_inverted_index.Spectroscopic	129
abstract_inverted_index.compatibility	10
abstract_inverted_index.concentration	99
abstract_inverted_index.conductivity.	170
abstract_inverted_index.large‐scale	30
abstract_inverted_index.lithium‐ion	18
abstract_inverted_index.manufacturing	31, 205
abstract_inverted_index.opportunities	201
abstract_inverted_index.understanding	51
abstract_inverted_index.Liquid‐phase	21
abstract_inverted_index.halide‐based	207
abstract_inverted_index.liquid‐phase	38, 67, 195
abstract_inverted_index.all‐solid‐state	17
cited_by_percentile_year
countries_distinct_count	1
institutions_distinct_count	3
citation_normalized_percentile.value	0.74831919
citation_normalized_percentile.is_in_top_1_percent	False
citation_normalized_percentile.is_in_top_10_percent	False