Prantik Mazumder
68Patents
7h-index
94Co-inventors
75Inventor score
Filing activity: Sep 21, 2001 → Nov 17, 2022
Most-cited inventions
| Patent | Title | Area | Cited by | Status |
|---|---|---|---|---|
| US9023457B2 | Textured surfaces and methods of making and using same | Emerging Cross-Sectional Technologies | 32 | Active |
| US10046542B2 | Articles and methods for controlled bonding of thin sheets with carriers | Chemistry; Metallurgy | 23 | Active |
| US10086584B2 | Glass articles and methods for controlled bonding of glass sheets with carriers | Emerging Cross-Sectional Technologies | 16 | Active |
| US9889635B2 | Facilitated processing for controlling bonding between sheet and carrier | Emerging Cross-Sectional Technologies | 14 | Active |
| US10543662B2 | Device modified substrate article and methods for making | Electricity | 13 | Active |
| US7584632B2 | Method of increasing the effectiveness of a fining agent in a glass melt | Chemistry; Metallurgy | 11 | Active |
| US9586858B2 | Laminate articles with moderate adhesion and retained strength | Emerging Cross-Sectional Technologies | 10 | Active |
| US7933114B2 | Composite carbon electrodes useful in electric double layer capacitors and capacitive deionization and methods of making the same | Emerging Cross-Sectional Technologies | 6 | Active |
| US8300385B2 | Composite carbon electrodes useful in electric double layer capacitors and capacitive deionization and methods of making the same | Emerging Cross-Sectional Technologies | 5 | Active |
| US9340443B2 | Bulk annealing of glass sheets | Physics | 4 | Active |
| US6862900B2 | Method and apparatus for reducing stress between depositions within a substrate tube | Chemistry; Metallurgy | 4 | Expired |
| US7771643B1 | Methods of making an unsupported article of semiconducting material by controlled undercooling | Chemistry; Metallurgy | 3 | Active |
| US10328372B2 | Anti-microbial air filter | Performing Operations; Transporting | 3 | Active |
| US7285420B2 | System and method for self-referencing a sensor in a micron-sized deep flow chamber | Emerging Cross-Sectional Technologies | 3 | Expired |
| US8795812B2 | Oleophobic glass substrates | Emerging Cross-Sectional Technologies | 2 | Active |
| US11629096B2 | Temporary bonding of glass pairs using cationic surfactants and/or organic salts | Emerging Cross-Sectional Technologies | 2 | Active |
| US6901775B2 | Method and apparatus for providing a uniform coating thickness along an axial direction within a substrate tube | Chemistry; Metallurgy | 2 | Expired |
| US9725357B2 | Glass articles having films with moderate adhesion and retained strength | Emerging Cross-Sectional Technologies | 2 | Active |
| US9828285B2 | Transfer of monolayer graphene onto flexible glass substrates | Chemistry; Metallurgy | 2 | Active |
| US11097509B2 | Siloxane plasma polymers for sheet bonding | Chemistry; Metallurgy | 2 | Active |
| US8445364B2 | Methods of treating semiconducting materials including melting and cooling | Electricity | 2 | Active |
| US9296183B2 | Metal dewetting methods and articles produced thereby | Emerging Cross-Sectional Technologies | 2 | Active |
| US10014177B2 | Methods for processing electronic devices | Emerging Cross-Sectional Technologies | 1 | Active |
| US11152294B2 | Hermetic metallized via with improved reliability | Emerging Cross-Sectional Technologies | 1 | Active |
| US11225434B2 | Silicon and silica nanostructures and method of making silicon and silica nanostructures | Chemistry; Metallurgy | 1 | Active |
Source: USPTO / EPO open patent data. Inventor disambiguation is heuristic; counts are objective bibliographic measures.