Dylan J. Boday
257Patents
11h-index
68Co-inventors
79Inventor score
Filing activity: Aug 14, 2008 → Dec 22, 2020
Most-cited inventions
| Patent | Title | Area | Cited by | Status |
|---|---|---|---|---|
| US8797059B2 | Implementing carbon nanotube based sensors for cryptographic applications | Electricity | 78 | Active |
| US8741804B2 | Microcapsules adapted to rupture in a magnetic field | Chemistry; Metallurgy | 32 | Active |
| US9120897B1 | Preparation of thioether polymers | Chemistry; Metallurgy | 22 | Active |
| US9034660B2 | Detection of analytes via nanoparticle-labeled substances with electromagnetic read-write heads | Physics | 19 | Active |
| US9245202B2 | Tamper detection with microcaspule rupture | Physics | 17 | Active |
| US8917510B2 | Reversibly adhesive thermal interface material | Emerging Cross-Sectional Technologies | 16 | Active |
| US9307692B2 | Microcapsules adapted to rupture in a magnetic field | Chemistry; Metallurgy | 16 | Active |
| US9187597B1 | Flame-retardant polylactic acid (PLA) by grafting through of phosphorus-containing polymers directly to PLA backbone | Chemistry; Metallurgy | 15 | Active |
| US9186641B2 | Microcapsules adapted to rupture in a magnetic field to enable easy removal of one substrate from another for enhanced reworkability | Emerging Cross-Sectional Technologies | 15 | Active |
| US9434133B2 | Microcapsules adapted to rupture in a magnetic field to enable easy removal of one substrate from another for enhanced reworkability | Emerging Cross-Sectional Technologies | 14 | Active |
| US9228044B2 | Versatile, facile and scalable route to polylactic acid-backbone graft and bottlebrush copolymers | Chemistry; Metallurgy | 11 | Active |
| US9694337B2 | Microcapsules adapted to rupture in a magnetic field to enable easy removal of one substrate from another for enhanced reworkability | Emerging Cross-Sectional Technologies | 10 | Active |
| US8796642B2 | Carbon nanotubes with fluorescent surfactant | Emerging Cross-Sectional Technologies | 10 | Active |
| US9193818B1 | Toughened polylactic acid (PLA) by grafting through of impact-modifying polymers directly to PLA backbone | Chemistry; Metallurgy | 10 | Active |
| US9332673B2 | Surface modification of hoses to reduce depletion of corrosion inhibitor | Mechanical Engineering; Lighting; Heating | 9 | Active |
| US8694280B2 | Servo control circuit for detecting analytes via nanoparticle-labeled substances with electromagnetic read-write heads | Physics | 9 | Active |
| US9120899B1 | Preparation of functional polysulfones | Chemistry; Metallurgy | 9 | Active |
| US8829082B2 | Self-healing material with orthogonally functional capsules | Chemistry; Metallurgy | 9 | Active |
| US9228059B2 | Preparation of thioether polymers | Chemistry; Metallurgy | 8 | Active |
| US8491083B2 | Inkjet printing of microfluidic channels | Performing Operations; Transporting | 8 | Active |
| US9534084B1 | High molecular weight polythioaminals from a single monomer | Chemistry; Metallurgy | 8 | Active |
| US9260550B1 | Lactide-based acrylate polymers | Chemistry; Metallurgy | 7 | Active |
| US10006936B2 | Poly(thioaminal) probe based lithography | Physics | 7 | Active |
| US9081004B2 | Circuit for detecting analytes via nanoparticle-labeled substances with electromagnetic read-write heads | Physics | 7 | Active |
| US10160072B2 | Liquid-cooled, composite heat sink assemblies | Mechanical Engineering; Lighting; Heating | 7 | Active |
Source: USPTO / EPO open patent data. Inventor disambiguation is heuristic; counts are objective bibliographic measures.