Fang Dai
53Patents
10h-index
61Co-inventors
77Inventor score
Filing activity: Feb 8, 2011 → Mar 9, 2022
Most-cited inventions
| Patent | Title | Area | Cited by | Status |
|---|---|---|---|---|
| US9929435B2 | Electrolyte structure for metal batteries | Emerging Cross-Sectional Technologies | 34 | Active |
| US9979008B2 | Methods for making a solid electrolyte interface layer on a surface of an electrode | Emerging Cross-Sectional Technologies | 32 | Active |
| US10084204B2 | Electrolyte solution and sulfur-based or selenium-based batteries including the electrolyte solution | Emerging Cross-Sectional Technologies | 31 | Active |
| US10312501B2 | Electrolyte and negative electrode structure | Emerging Cross-Sectional Technologies | 26 | Active |
| US10629941B2 | Making a pouch format cell and attaching a tab to an electrode | Emerging Cross-Sectional Technologies | 24 | Active |
| US10381170B2 | Microporous and hierarchical porous carbon | Emerging Cross-Sectional Technologies | 22 | Active |
| US11101501B2 | Electrolyte and negative electrode structure | Emerging Cross-Sectional Technologies | 12 | Active |
| US10566652B2 | Lithium metal battery with hybrid electrolyte system | Emerging Cross-Sectional Technologies | 11 | Active |
| US10446884B2 | Three-electrode test cell | Emerging Cross-Sectional Technologies | 10 | Active |
| US9627716B2 | Electrolyte and lithium based batteries | Emerging Cross-Sectional Technologies | 10 | Active |
| US10714756B2 | Metal deposition methods for forming bimetallic structures, batteries incorporating bipolar current collectors made therefrom, and applications thereof | Emerging Cross-Sectional Technologies | 6 | Active |
| US9859554B2 | Negative electrode material for lithium-based batteries | Emerging Cross-Sectional Technologies | 5 | Active |
| US10224571B2 | Fluorinated ether as electrolyte co-solvent for lithium metal based anode | Emerging Cross-Sectional Technologies | 5 | Active |
| US10155547B1 | Vascular structures and methods for heat management | Performing Operations; Transporting | 5 | Active |
| US10797301B2 | Method of manufacturing an electrochemical cell | Emerging Cross-Sectional Technologies | 4 | Active |
| US11328878B2 | Microporous and hierarchical porous carbon | Emerging Cross-Sectional Technologies | 4 | Active |
| US10797353B2 | Method of manufacturing an electrochemical cell | Electricity | 3 | Active |
| US11183714B2 | Hybrid metal-organic framework separators for electrochemical cells | Emerging Cross-Sectional Technologies | 3 | Active |
| US10593931B2 | Electrochemical cell and method of manufacturing | Emerging Cross-Sectional Technologies | 3 | Active |
| US10556482B2 | Vascular structures and methods for thermal control | Performing Operations; Transporting | 2 | Active |
| US10608241B2 | Methods of preparing lithium metal anodes | Emerging Cross-Sectional Technologies | 2 | Active |
| US10707530B2 | Carbonate-based electrolyte system improving or supporting efficiency of electrochemical cells having lithium-containing anodes | Emerging Cross-Sectional Technologies | 2 | Active |
| US10944096B2 | Method of manufacturing a lithium metal negative electrode | Electricity | 2 | Active |
| US10751694B2 | Metal organic framework (MOF) structured object and method | Emerging Cross-Sectional Technologies | 2 | Active |
| US11031586B2 | Methods for manufacturing sulfur electrodes | Emerging Cross-Sectional Technologies | 2 | Active |
Source: USPTO / EPO open patent data. Inventor disambiguation is heuristic; counts are objective bibliographic measures.