Electrical and mechanical properties of glass and glass-ceramic electrolytes in the system Li₃BO₃–Li₂SO₄

Abstract: Low-melting oxide glasses are promising as electrolytes for all-solid-state lithium rechargeable batteries. Glasses in the pseudobinary system Li 3 BO 3 Li 2 SO 4 were prepared by a mechanochemical technique. Raman spectra revealed that the glasses contained no macroanions which form networks but consisted only of Li + ions and two discrete ortho-oxoanions, BO 3 3¹ and SO 4 2¹. The density and molar volume increased and elastic moduli decreased with an increase in the Li 2 SO 4 content in the glasses. The heat… Show more

“…[11][12][13]38] The ionic conductivity obtained in this study almost matches with these reported values; therefore, the higher ionic conductivity was probably attributed to the amorphous NMC-Li 2 SO 4 matrix. Owing to the decrease in grain boundary area, the electronic conductivity increased even when the insulating Li 2 SO 4 component was added.…”

“…[18] In addition, there are advantages in the use of amorphous materials to achieve higher capacities and better cycle characteristics owing to the open and random structures. [12,13] All-solid-state cells using this amorphous active material operated as secondary batteries at 100 °C. [22][23][24] The obtained amorphous LiCoO 2 -Li 2 SO 4 positive electrode material exhibited the best charge-discharge performance.…”

“…[8] Therefore, high-temperature sintering is required to achieve a good contact. [12,13] A good contact with electrode active materials was successfully achieved simply by pressing at room temperature, which was enabled by the excellent formability of the electrolyte.Crystalline materials such as layered, [14,15] spinel, [16] and olivine [17] structures have been utilized as positive electrode materials in typical lithium-ion and all-solid-state batteries. [9,10] Therefore, formation of an excellent electrode/ electrolyte interface without high-temperature sintering is important for the operation of all-oxide solid-state batteries.…”

Amorphous Ni‐Rich Li(Ni_1−x−yMn_xCo_y)O₂–Li₂SO₄ Positive Electrode Materials for Bulk‐Type All‐Oxide Solid‐State Batteries

“…[11][12][13]38] The ionic conductivity obtained in this study almost matches with these reported values; therefore, the higher ionic conductivity was probably attributed to the amorphous NMC-Li 2 SO 4 matrix. Owing to the decrease in grain boundary area, the electronic conductivity increased even when the insulating Li 2 SO 4 component was added.…”

“…[18] In addition, there are advantages in the use of amorphous materials to achieve higher capacities and better cycle characteristics owing to the open and random structures. [12,13] All-solid-state cells using this amorphous active material operated as secondary batteries at 100 °C. [22][23][24] The obtained amorphous LiCoO 2 -Li 2 SO 4 positive electrode material exhibited the best charge-discharge performance.…”

“…[8] Therefore, high-temperature sintering is required to achieve a good contact. [12,13] A good contact with electrode active materials was successfully achieved simply by pressing at room temperature, which was enabled by the excellent formability of the electrolyte.Crystalline materials such as layered, [14,15] spinel, [16] and olivine [17] structures have been utilized as positive electrode materials in typical lithium-ion and all-solid-state batteries. [9,10] Therefore, formation of an excellent electrode/ electrolyte interface without high-temperature sintering is important for the operation of all-oxide solid-state batteries.…”

Amorphous Ni‐Rich Li(Ni_1−x−yMn_xCo_y)O₂–Li₂SO₄ Positive Electrode Materials for Bulk‐Type All‐Oxide Solid‐State Batteries

“…The thin film was deposited at 200°C on a Si substrate and a 90Li 3 BO 3 ·10-Li 2 SO 4 (mol%) electrolyte pellet. 15,16 The substrate temperature was chosen for improving characteristics of electrode-electrolyte interfaces based on a previous report. 17 To avoid exposure of the deposited film to the atmosphere, a PLD vacuum chamber connected to an Ar-filled grove box was used.…”

Preparation of an Amorphous 80LiCoO₂·20Li₂SO₄ Thin Film Electrode by Pulsed Laser Deposition

“…So far, there are numerous studies based on glass and glass-ceramic-based materials as electrolytes for batteries, with limited studies as electrodes where the present work falls into action. 7,8 2 | METHODS…”

High energy density of multivalent glass‐ceramic cathodes for Li‐ion rechargeable cells and as an efficient photocatalyst for organic degradation