Zhongyi Liu
42Patents
6h-index
72Co-inventors
68Inventor score
Filing activity: Oct 24, 2008 → Aug 16, 2024
Most-cited inventions
| Patent | Title | Area | Cited by | Status |
|---|---|---|---|---|
| US10435773B2 | Rapidly solidified high-temperature aluminum iron silicon alloys | Emerging Cross-Sectional Technologies | 113 | Active |
| US10294552B2 | Rapidly solidified high-temperature aluminum iron silicon alloys | Emerging Cross-Sectional Technologies | 109 | Active |
| US9302914B2 | Methods for making hollow carbon materials and active materials for electrodes | Emerging Cross-Sectional Technologies | 64 | Active |
| US9379374B2 | Methods for forming negative electrode active materials for lithium-based batteries | Emerging Cross-Sectional Technologies | 42 | Active |
| US9034519B2 | Ultrathin surface coating on negative electrodes to prevent transition metal deposition and methods for making and use thereof | Emerging Cross-Sectional Technologies | 38 | Active |
| US10128481B2 | Lithium-based battery separator and method for making the same | Emerging Cross-Sectional Technologies | 27 | Active |
| US10519531B2 | Lightweight dual-phase alloys | Chemistry; Metallurgy | 3 | Active |
| US10626834B2 | Fuel injector for an internal combustion engine | Mechanical Engineering; Lighting; Heating | 3 | Active |
| US11424442B2 | Methods of forming prelithiated silicon alloy electroactive materials | Emerging Cross-Sectional Technologies | 2 | Active |
| US8058204B2 | Method for generating a shell of noble metal overlaid on a core of non-noble metal, and catalysts made thereby | Emerging Cross-Sectional Technologies | 2 | Active |
| US10260131B2 | Forming high-strength, lightweight alloys | Performing Operations; Transporting | 1 | Active |
| US10326142B2 | Positive electrode including discrete aluminum oxide nanomaterials and method for forming aluminum oxide nanomaterials | Emerging Cross-Sectional Technologies | 1 | Active |
| US11848440B2 | Prelithiated negative electrodes including composite Li—Si alloy particles and methods of manufacturing the same | Emerging Cross-Sectional Technologies | 1 | Active |
| US11927231B2 | Composite brake rotor | Mechanical Engineering; Lighting; Heating | 0 | Active |
| US10247157B2 | Diamond like carbon (DLC) coating for ethanol-blended fuel injector applications | Mechanical Engineering; Lighting; Heating | 0 | Active |
| US12404824B2 | Reinforced bulging tank of launch vehicle and manufacturing method therefor | Emerging Cross-Sectional Technologies | 0 | Active |
| US11465227B2 | System and method for manufacturing high-strength bonded metal sheets for a battery cell | Emerging Cross-Sectional Technologies | 0 | Active |
| US10298705B2 | Recommendation method and device | Electricity | 0 | Active |
| US11085109B2 | Method of manufacturing a crystalline aluminum-iron-silicon alloy | Performing Operations; Transporting | 0 | Active |
| US11824186B2 | Prelithiated negative electrodes including Li—Si alloy particles and methods of manufacturing the same | Emerging Cross-Sectional Technologies | 0 | Active |
| US12366273B2 | Composite brake drum | Mechanical Engineering; Lighting; Heating | 0 | Active |
| US11769872B2 | Pre-lithiated silicon particles and methods of forming the same | Emerging Cross-Sectional Technologies | 0 | Active |
| US10141564B2 | Lithium titanate structures for lithium ion batteries formed using element selective sputtering | Emerging Cross-Sectional Technologies | 0 | Active |
| US11554417B2 | Article for producing ultra-fine powders and method of manufacture thereof | Emerging Cross-Sectional Technologies | 0 | Active |
| US10913992B2 | Method of manufacturing a crystalline aluminum-iron-silicon alloy | Chemistry; Metallurgy | 0 | Active |
Source: USPTO / EPO open patent data. Inventor disambiguation is heuristic; counts are objective bibliographic measures.