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Triweekly Patent Update – 2025-09-02 – Free Version

  • Lithium-ion batteries – electrolytes – solid & semi-solid

  • Sulfide-based solid electrolyte and manufacturing method thereof
    Applicant: SOLIVIS / KR 20250109169 A

    A sulfide-based solid electrolyte with argyrodite structure was prepared through boron-based element substitution. Precursors Li2S, P2S5, LiCl, and LiBr were mixed with B2S3 (1.1 mol% based on total precursor mass). The precursors were subjected to ball-milling with 3 mm balls in heptane, followed by vacuum drying (80°C).

    The precursor powder was heat-treated (500°C, 6 h, Ar atmosphere) to form the argyrodite-type solid electrolyte. X-ray diffraction (XRD) analysis confirms the formation of argyrodite structure with characteristic peaks matching those of the undoped comparative material (see Figure).

    The resulting solid electrolyte exhibits an ionic conductivity of 7.34 × 10-3 S/cm and a compressed density of 1.80 g/cm3. Electrochemical testing with NCM811-based positive electrodes reveals a discharge capacity of 182 mAh/g and a coulombic efficiency of 78.4% (0.05 C charge / discharge), as compared to 169 mAh/g and 79.0% for the undoped comparative material.

    The boron substitution forms [B]S3 triangle structures within the argyrodite crystal lattice, which strengthens the structural stability and suppresses hydrogen sulfide gas evolution when exposed to moisture (no corresponding experimental data was identified).

    실시예1: Example 1
    실시예2: Example 2
    실시예3: Example 3
    실시예4: Example 4
    비교예: Comparative example

    Patent Image, Solivis

    This work suggests that B-doped sulfide electrolytes exhibit increased ionic conductivities and reduced moisture sensitivity.

    Further optimization of surface characteristics could contribute to further improved moisture stability while maintaining a favorable ionic conductivity.

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  • Lithium-ion batteries – negative electrode (excluding Li metal electrodes)

  • ANODE, METHOD FOR MANUFACTURING SAME, AND ELECTROCHEMICAL DEVICE COMPRISING SAME
    Applicant: LG ENERGY SOLUTION / WO 2025165168 A1

    Granules were prepared by mixing SiO (D50: 17 μm, 91 mass%), single-walled carbon nanotubes (SWCNT, 1.6 mass%), polyvinylpyrrolidone dispersant (PVP, 2.4 mass%), styrene-butadiene rubber (SBR, 2 mass%), acrylamide-acrylate copolymer (acrylamide : acrylic acid : acrylonitrile = 60 : 30 : 10 molar ratio, 2 mass%), and carboxymethyl cellulose (CMC, 1 mass%) in water.

    The slurry was spray-dried (250°C inlet temperature, 105°C outlet temperature), followed by sieving to obtain granules (D90: 35 μm). The granules exhibit a higher binder concentration near the surface, while SiO and SWCNT are more highly concentrated in particle cores.

    A negative electrode mixture was manufactured by mixing the granules (3.2 mass%) with artificial graphite (46.5 mass%), natural graphite (46.5 mass%), carbon black (1.0 mass%), polyethylene (PE, 0.3 mass%), polyvinylidene fluoride (PVDF, 2.0 mass%), and polytetrafluoroethylene (PTFE, 0.5 mass%). The mixture was kneaded at 140°C under 50 atm pressure for 20 min at 10 rpm.

    The resulting mixture lump was pulverized and calendered using rolls at 130°C to form a negative electrode film (see Figure). Two films were laminated on both sides of a copper current collector (12 μm) coated with a conductive primer layer (carbon black : acrylic binder = 5 : 5 mass ratio).

    In half-cells, these electrodes exhibit a capacity retention of 89.8% after 100 cycles (0.33 C charge / discharge), as compared to 87.0% for comparative electrodes without pre-formed granules.

    100: manufacturing process
    110: raw materials
    120: mixed powder
    130: final electrode film

    Patent Image, LG Energy Solution

    This work illustrates a dry negative electrode manufacturing process for which process efficiency / costs and performance were optimized. The granular SiO-containing component is a minor negative electrode component (3.2 mass%), which reduces the cost impact of the spray-drying step that contributes significantly to cycling stability.

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  • Lithium-ion batteries – positive electrode

  • PELLETIZATION FOR ALL-DRY SYNTHESIS OF LITHIUM TRANSITION METAL OXIDE MATERIALS
    Applicant: NOVONIX BATTERY TECHNOLOGY SOLUTIONS / NOVONIX ANODE MATERIALS / WO 2025165784 A1

    A precursor mixture was prepared by mixing Ni powder, Co powder, Mn3O4 powder, Zr(OH)4 powder, and 20% excess Li2CO3 powder in a stoichiometric ratio for Li[Ni0.83Mn0.06Co0.11]0.9975Zr0.0025O2 (NMC83) in a high-speed mixer.

    The mixed precursor was pelletized using a hydraulic press with applied forces ranging from hand-pressed to 4 tons (19.4 MPa). The pellets were transferred to a ceramic saggar. Sintering was carried out at 900°C under an oxygen atmosphere in a box furnace. The sintered materials were then jet-milled to de-agglomerate secondary particles.

    In comparison trials, more agglomeration was observed for non-pelletized materials, while pelletized samples exhibit single-crystal morphologies with uniform particle sizes. The cation mixing values determined from Rietveld refinement are 2.65% for non-pelletized and 1.08% for pelletized samples.

    In half-cell tests, the pelletized material exhibits a reversible discharge capacity of 194.7 mAh/g with a first cycle irreversible capacity of 12.7%, compared to 188.6 mAh/g and 14.2% for the non-pelletized material. After 25 cycles, the pelletized sample exhibits ≈95% capacity retention at C/5, while the non-pelletized sample exhibits ≈85% retention.

    (a): non-pelletized precursor mixture
    (b): pelletized precursor mixture arranged on saggar

    Patent Image, Novonix

    This work illustrates promising performance upon sintering pressed NMC precursor pellets (dry process, no use of solvent), as compared to powder sintering. Pellet sintering might offer substantial benefits in terms of process efficiency, process consistency upon up-scaling, and sustainability.

  • The premium version includes another two patent discussions, plus an Excel list with 50-100 commercially relevant recent patent families.
  • Fuel cells (PEMFC / SOFC / PAFC / AEMFC) – electrochemically active materials

  • ELECTRODE CATALYST
    Applicant: PANASONIC / WO 2025158822 A1

    A mesoporous carbon-supported Pt1.94Co0.65Ni0.35 electrode catalyst was prepared with optimized nickel composition for enhanced oxygen reduction reaction (ORR) activity.

    Mesoporous carbon (CNovel, Toyo Carbon, pore diameter: 10 nm) was dispersed in water / ethanol (1 : 1 mass ratio) and processed using a bead mill (20 min).

    The carbon support was subjected to a water vapor adsorption treatment (30°C, 90% relative humidity, 12 h) to enhance surface properties. A 14 mass% dinitrodiamineplatinum nitric acid solution was added to achieve 50 mass% Pt loading, followed by heating (80°C, 6 h) and a reduction treatment (220°C, 2 h, nitrogen / hydrogen atmosphere 85 : 15).

    Cobalt chloride hexahydrate and nickel chloride hexahydrate were dissolved in pure water (50 mL) at predetermined ratios to achieve the target composition. The solution was added to the Pt-supported carbon, followed by dropwise addition of 1 mass% sodium borohydride solution (50 mL) and stirring (10 min).

    Heat treatment was performed in a tube furnace under reducing atmosphere (nitrogen / hydrogen 97 : 3, 1 L/min flow rate). Temperature profile: heating to 120°C (10 min), ramping to 1,000°C (150°C/h), holding (30 min), further heating to 1,100°C (100°C/h), and maintaining (2 h).

    The resulting material was stirred in 0.2 mol/L sulfuric acid (80°C, 2 h) and 0.2 mol/L nitric acid (70°C, 2 h) to remove excess cobalt and nickel from the surface. A secondary heat treatment was conducted (400°C, 2 h, hydrogen atmosphere) for surface densification.

    X-ray diffraction analysis confirms the formation of an L10 ordered structure with a ratio of 0.44. The catalyst exhibits a mass activity of 1,420 A/g-Pt at 0.9 V, representing a 2.58-fold improvement compared to the Pt-Co binary alloy catalyst (see Figure).

    The optimized nickel composition ratio (y = 0.35) in the PtxCo1-yNiy formula demonstrates superior catalytic performance due to synergistic effects between the mesoporous support and the ternary alloy composition.

    ● Mesoporous carbon support
    □ Carbon black support (comparative examples)
    規格化触媒活性: Normalized catalytic activity
    ニッケルの組成比率: Nickel composition ratio

    Patent Image, Panasonic

    This work illustrates favorable catalytic PEMFC performance upon simultaneously optimizing the carbon support, the Pt / Ni ratio and process characteristics that affect the catalyst nanostructure.

  • The premium version includes another two patent discussions, plus an Excel list with 50-100 commercially relevant recent patent families.
  • Triweekly patent lists for other categories (Excel files are included for premium users)

  • - Lithium metal batteries (excluding Li-S, Li-Air): XLSX
  • - Lithium-air batteries: XLSX
  • - Lithium-ion batteries – electrolytes – liquid: XLSX
  • - Lithium-ion batteries – separators: XLSX
  • - Lithium-sulfur batteries: XLSX
  • - Na-ion batteries: XLSX
  • Prior patent updates

  • 2025-08-12
  • 2025-07-22
  • 2025-07-01
  • 2025-06-10
  • 2025-05-20

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