Abstract: Various methods and techniques for enhancing a silicon-containing anode for a battery cell are presented. The methods may include providing a silicon-containing anode having reversible electrochemical capabilities including a silicon-containing material and an anode material compatible with a lithium-ion battery chemistry having porous and conductive mechanical properties. The methods may also include enriching a surface layer of the silicon-containing anode with sodium ions to intersperse the sodium ions between silicon atoms of the silicon-containing material. The methods may also include displacing the sodium ions with potassium ions to form a compression layer in the silicon-containing anode. The potassium ions may place the silicon atoms of the silicon-containing material in a pre-compressive state to counteract internal stress exerted on the silicon-containing material.

Abstract: Various methods and techniques for enhancing a silicon-containing anode for a battery cell are presented. The methods may include providing a silicon-containing anode having reversible electrochemical capabilities including a silicon-containing material and an anode material compatible with a lithium-ion battery chemistry having porous and conductive mechanical properties. The methods may also include enriching a surface layer of the silicon-containing anode with sodium ions to intersperse the sodium ions between silicon atoms of the silicon-containing matieral. The methods may also include displacing the sodium ions with potassium ions to form a comrpession layer in the silicon-containing anode. The potassium ions may place the silicon atoms of the silicon-containing material in a pre-compressive state to counteract internal stress exerted on the silicon-containing material.

Abstract: Embodiments disclosed herein generally relate to a microporous separator with a pore geometry that creates a low or no tortuosity architecture. In one embodiment, a battery cell may comprise of an anode layer, a cathode layer, and a separator layer positioned between the cathode layer and the anode layer. The separator layer may be comprised of one or more block copolymers. The block copolymers that make up the separator layer may be materials that self-align into a vertical nanostructure. The vertical nanostructures may allow ions within the battery cell to flow in a vertical path between the cathode and anode. This vertical path my create a low or no tortuosity environment within the battery cell.

Abstract: Various methods and techniques for enhancing a silicon-containing anode for a battery cell are presented. The methods may include providing a silicon-containing anode having reversible electrochemical capabilities including a silicon-containing material and an anode material compatible with a lithium-ion battery chemistry having porous and conductive mechanical properties. The methods may also include enriching a surface layer of the silicon-containing anode with sodium ions to intersperse the sodium ions between silicon atoms of the silicon-containing matieral. The methods may also include displacing the sodium ions with potassium ions to form a comrpession layer in the silicon-containing anode. The potassium ions may place the silicon atoms of the silicon-containing material in a pre-compressive state to counteract internal stress exerted on the silicon-containing material.

Abstract: A battery cell providing a non-invasive reference lead includes a cap positioned at a top of the battery cell, where the cap includes an anode section and a cathode section separated by an insulator section. The battery cell also includes a jelly roll comprising an anode lead and a cathode lead extending from a top of the jelly roll. The anode lead of the jelly roll is electrically coupled to the anode section of the cap, and the cathode lead of the jelly roll is electrically coupled to the cathode section of the cap. The battery cell further includes a lithium sleeve providing a reference lead for the battery cell. The lithium sleeve and the cap enclose the jelly roll.

Abstract: The embodiments described herein generally relate to improving conductive pathways within a battery cell. In prior battery cells, a high degree of tortuosity may exist due to complex conductive pathways within the battery cell. Embodiments described herein describe a solution that may orient particles within an electrode so that the particles are aligned in a universal direction. The aligned particles may allow for a relatively vertical conductive pathway within a battery cell, which may decrease tortuosity within the battery cell.

Abstract: Various methods and techniques for enhancing a silicon-containing anode for a battery cell are presented. The methods may include providing a silicon-containing anode having reversible electrochemical capabilities including a silicon-containing material and an anode material compatible with a lithium-ion battery chemistry having porous and conductive mechanical properties. The methods may also include enriching a surface layer of the silicon-containing anode with sodium ions to intersperse the sodium ions between silicon atoms of the silicon-containing matieral. The methods may also include displacing the sodium ions with potassium ions to form a comrpession layer in the silicon-containing anode. The potassium ions may place the silicon atoms of the silicon-containing material in a pre-compressive state to counteract internal stress exerted on the silicon-containing material.

Abstract: Embodiments disclosed herein may be generated related to the prevention of a thermal catastrophic event within a battery cell. A thermal catastrophic event may be caused by many issues associated with a battery cell such as an internal short within the battery cell. To prevent a thermal catastrophic event an apparatus that may include a battery cell and a phase change material in contact with one or more portions of the battery cell. The phase change material may be configured to change phases at a temperature that is close to that of a thermal runaway event. The phase change material may further have a high heat of fusion such that the phase change material may absorb heat within a battery cell in the case of thermal runaway event in order to prevent a thermal catastrophic event within the battery cell.

Abstract: Embodiments disclosed herein generally relate to a microporous separator with a pore geometry that creates a low or no tortuosity architecture. In one embodiment, a battery cell may comprise of an anode layer, a cathode layer, and a separator layer positioned between the cathode layer and the anode layer. The separator layer may be comprised of one or more block copolymers. The block copolymers that make up the separator layer may be materials that self-align into a vertical nanostructure. The vertical nanostructures may allow ions within the battery cell to flow in a vertical path between the cathode and anode. This vertical path my create a low or no tortuosity environment within the battery cell.

Abstract: A battery cell includes a cathode layer and an anode layer. The anode layer includes anode particles, and a plurality of the anode particles have non-spanning cracks induced in the anode particles from cyclic tension applied to the anode layer prior to the anode layer being combined with the cathode layer in the battery cell. The battery cell also includes a case, where the cathode layer and the anode layer are housed within the case.