Koby, D. (2026). Next Generation Lithographic Nanofabrication Achieving sub- 10 nm resolution and true volumetric control. Computer-generated holograms (CGHs), multi-beam interference lithography, and their convergence with two-photon poly- merization and stimulated emission depletion (STED) microscopy-inspired methods. Cross- disciplinary innovations in metamaterials, quantum photonics, and biomedical scaffolds are a forward-looking roadmap for atomic-precision manufacturing next-generation nanofabrication. Zenodo.
Chicago Style (17th ed.) CitationKoby, Davis. Next Generation Lithographic Nanofabrication Achieving Sub- 10 Nm Resolution and True Volumetric Control. Computer-generated Holograms (CGHs), Multi-beam Interference Lithography, and Their Convergence with Two-photon Poly- Merization and Stimulated Emission Depletion (STED) Microscopy-inspired Methods. Cross- Disciplinary Innovations in Metamaterials, Quantum Photonics, and Biomedical Scaffolds Are a Forward-looking Roadmap for Atomic-precision Manufacturing Next-generation Nanofabrication. Zenodo, 2026.
MLA (9th ed.) CitationKoby, Davis. Next Generation Lithographic Nanofabrication Achieving Sub- 10 Nm Resolution and True Volumetric Control. Computer-generated Holograms (CGHs), Multi-beam Interference Lithography, and Their Convergence with Two-photon Poly- Merization and Stimulated Emission Depletion (STED) Microscopy-inspired Methods. Cross- Disciplinary Innovations in Metamaterials, Quantum Photonics, and Biomedical Scaffolds Are a Forward-looking Roadmap for Atomic-precision Manufacturing Next-generation Nanofabrication. Zenodo, 2026.