Abstract: A cathode and a battery providing the cathode is provided. The cathode comprises a lithium metal oxide. The lithium metal oxide comprises nickel, aluminum, and iron. The lithium metal oxide is substantially free of cobalt. The battery comprises an anode, the cathode, a separator, and an electrolyte.

Abstract: Provided herein are apparatus, systems, and methods of powering electrical vehicles. The apparatus can include a battery pack disposed in an electric vehicle to power the electric vehicle. The apparatus can include a battery cell arranged in the battery pack. The battery cell can have a housing that defines a cavity within the housing of the battery cell. The battery cell can have an electrolyte having a first side and a second side to transfer lithium ions between the first side and the second side. The electrolyte can be arranged within the cavity. The battery cell can have an anode disposed within the cavity along the first side of the electrolyte. The battery cell can have a composite cathode disposed within the cavity along the second side of the electrolyte. The composite cathode can include a mixture of a NCA material and a NCM material.

Abstract: A three-electrode battery cell precisely measures the anode and cathode during cell operation. The successful interpretation of 3-E cell measurements enables accurate tuning of N/P ratio, fine control of electrode potential during operations, and precise cell capacity prediction during early-stage design. The cost-intensive full cell assembly and time-consuming cell testing can be eliminated, and 3-electrode cell testing and analysis can be used to achieve reliable materials sourcing and state-of-the-art cell design with high accuracy and efficiency. The three-electrode cell can be used to analyze and test battery cell designs during pre-production to determine and optimize the capacity, N/P ratio, and voltage window information for mass production of a particular battery design.

Abstract: A lithium ion rechargeable battery having an electrode and organic electrolyte, wherein the electrolyte includes a phosphor-based material that makes up between 1-20% by weight of the electrolyte. The phosphor-based material added to the electrolyte, in the concentration disclosed herein, does not alter or affect the electrochemical performance of the battery cell, including the capacity of the battery cell. The phosphor-based material is effective, at concentrations in the electrolyte of between 1-20% by weight, of curbing thermal runaway.

Abstract: An electrode for a lithium ion rechargeable battery, wherein the electrode is made from a slurry generated from a compound graphite active material. The compound graphite active material can include graphite particles of different sizes. In some instances, fifty percent or more of the graphite particles making up the active material can have a diameter that is larger than the diameter of the remainder of the graphite materials. The compound graphite active material is applied to a current conductor to form an electrode, and provides for a discharge capacity of significantly higher than lithium ion rechargeable battery having an electrode with a slurry generated from a single sized graphite active material.

Abstract: A cathode and a battery providing the cathode is provided. The cathode comprises a lithium metal oxide. The lithium metal oxide comprises nickel, aluminum, and iron. The lithium metal oxide is substantially free of cobalt. The battery comprises an anode, the cathode, a separator, and an electrolyte.

Abstract: Systems and methods for manufacturing an electrode is provided. An example method may comprise disposing, by a blade, a slurry onto a surface of a current collector, the slurry including an active material and a solvent, applying, by an electric field source, an electric field between the blade and the current collector, and drying the slurry applied to the surface of the current collector to remove the solvent. The electric field is applied continuously while the slurry is disposed onto the surface of the current blade. The electric field affects the structure of portions of the slurry by causing a Van der Waals interaction and a polarization attraction between the active material and the current collector. The slurry may include of 95% graphite, 3% of a binder, and 5% of reduced graphene oxide. The solvent may include 4 to 1 mixture of water and isopropyl alcohol.

Abstract: External forces are applied to a slurry mixture to achieve a more organized slurry structure in the manufacturing of an electrode. A slurry is generated with paramagnetic materials that exhibit magnetic properties when a magnetic field is applied to the slurry. The slurry with the paramagnetic materials is applied to a current conductor, and then a magnetic field is applied to the slurry, for example during an electrode drying process. By applying a magnetic field, the paramagnetic material orientation can be aligned into a more organized structure. In some instances, the alignment creates a porous structure or gap between pillars that form within the dried slurry material. The dried, porous slurry structure allows for electrolyte wetting and ionic accessibility that is greatly improved over electrodes manufactured using typical techniques.