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Aluminum oxide protected lithium metal tunable 3D silicon batteries

US12406980B2 · US · B2

Patent metadata
FieldValue
Publication numberUS-12406980-B2
Application numberUS-202016908145-A
CountryUS
Kind codeB2
Filing dateJun 22, 2020
Priority dateJun 22, 2020
Publication dateSep 2, 2025
Grant dateSep 2, 2025

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  1. Title

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  2. Abstract

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  3. Assignees and inventors

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  4. Key dates

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  5. First independent claim

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  6. CPC / IPC classifications

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  7. Citations and related patents

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Abstract

Official abstract text for this publication.

One or more trenches in a silicon substrate have an electrically active surface at a trench base and metal layer disposed on the electrically active surface. Precursor materials are disposed and/or formed on the metal layer in the trench. An anode is patterned either exclusively in the 3D trench or in the 3D trench, sidewalls and field of the substrate, where the anode patterning transforms and/or moves the precursor materials in the trench into some novel compositions of matter and other final operational structures for the device, e.g. layers of metallic Lithium for energy storage and different concentrations of Lithium-silicon species in the substrate. A multi-faceted mechanism is disclosed for Al2O3 silicon interfacial additives. When the anode is patterned both in and outside the 3D wells, Al2O3 provides an for electron-conductive Li-metal interface that enables homogenous plating on both the insulated substrate field as well as active silicon trench base where Al2O3 acts as a barrier to Li—Si diffusion. When the anode is patterned only in the 3D trench, Al2O3 additive creates a robust, flexible, Li-permeable interface upon charge cycling, which preserves the 3D textured structure of the porous silicon anode. Additionally, the Al2O3 additive is mobilized deeper into the bulk silicon in parallel with Li+ and a conductive plasticizer upon progressive cycling—where the lithiated Al2O3 particles nucleate at defect sites and prevent mechanical degradation of the silicon anode through a combined bridge and spacer mechanism. By selecting different defined anode patterns to deposit on the 3D substrate, final operational characteristics, properties, structures, and charge storage performance for the device can be predictably designed and manufactured.

First claim

Opening claim text (preview).

We claim: 1. An energy storage device comprising: a silicon substrate with one or more trenches, each of the one or more trenches having a trench base, one or more trench sidewalls, and a field region; an active silicon surface at the trench base, the active silicon surface being part of the silicon substrate and having a 3D surface texture and a porosity; one or more insulating layers covering the one or more trench sidewalls but not disposed on the active silicon surface; an agglomerate layer disposed directly on the active silicon surface and at least partially covering the one or more insulating layers and the agglomerate layer being made of one or more particles of aluminum oxide encapsulated by a lithium metal; a lithium metal anode layer disposed on the agglomerate layer at the trench base, wherein the lithium metal anode layer is confined to the one or more trenches and the lithium metal anode layer contacts the agglomerate layer covering the one or more trench sidewalls; and a conductive polymer adhesive layer chemically and electrically adhered to a top surface of the lithium metal anode layer, wherein the conductive polymer adhesive layer is confined to the one or more trenches and the conductive polymer adhesive layer contacts the agglomerate layer covering the one or more trench sidewalls. 2. The energy storage device of claim 1 , further comprising: the lithium metal anode layer made of lithium metal and having a lithium metal anode layer thickness. 3. The energy storage device of claim 1 , wherein the agglomerate layer is disposed on the entirety of the one or more insulating layers and also is disposed on the field region. 4. The energy storage device of claim 1 , wherein the silicon substrate below the active silicon surface contains a lithium-silicon species. 5. The energy storage device of claim 4 , wherein the lithium-silicon species forms a layer of lithiated silicon directly beneath the active silicon surface. 6. The energy storage device of claim 1 , further comprising a lithium metal field layer made of lithium metal with a lithium metal field layer thickness, the lithium metal field layer disposed on a part of the agglomerate layer which is disposed on the one or more insulating layers on the or more trench sidewalls. 7. The energy storage device of claim 6 , wherein the lithium metal anode layer and the lithium metal field layer are chemically and electrically connected to one another. 8. The energy storage device of claim 1 , wherein the one or more particles have an average diameter, prior to electrochemical cycling, less than or equal to 15 nm. 9. The energy storage device of claim 1 , wherein the one or more particles mobilize deeper into the silicon substrate upon progressive charge and discharge cycling.

Assignees

Inventors

Classifications

  • H01M50/116

    characterised by the material · CPC title

  • H01M10/0436

    Small-sized flat cells or batteries for portable equipment · CPC title

  • H01M10/0525

    Rocking-chair batteries, i.e. batteries with lithium insertion or intercalation in both electrodes; Lithium-ion batteries · CPC title

  • Y02P70/50

    Manufacturing or production processes characterised by the final manufactured product · CPC title

  • Y02E60/10

    Energy storage using batteries · CPC title

Patent family

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View patent family 79021990

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Frequently asked questions

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What does patent US12406980B2 cover?
One or more trenches in a silicon substrate have an electrically active surface at a trench base and metal layer disposed on the electrically active surface. Precursor materials are disposed and/or formed on the metal layer in the trench. An anode is patterned either exclusively in the 3D trench or in the 3D trench, sidewalls and field of the substrate, where the anode patterning transforms and…
Who is the assignee on this patent?
IBM
What technology area does this patent fall under?
Primary CPC classification H01M4/131. Mapped technology areas include Electricity.
When was this patent published?
Publication date Tue Sep 02 2025 00:00:00 GMT+0000 (Coordinated Universal Time) (B2). Legal status and post-grant events are not shown on this page.
What related patents are in patentsdb?
We list 12 related publications on this page (citations in our corpus or others sharing the same primary CPC).