Affiliation: Stanford University
- Nanophotonic computational designJesse Lu
Ginzton Laboratory, Stanford University, Stanford, California, USA
Opt Express 21:13351-67. 2013..Instead, we are able to design devices solely based on the user's desired performance specification for the device...
- Objective-first design of high-efficiency, small-footprint couplers between arbitrary nanophotonic waveguide modesJesse Lu
Stanford University, Stanford, California, USA
Opt Express 20:7221-36. 2012..We demonstrate designs for various coupling problems which suggest that our method allows for the design of any single-mode, linear optical device...
- Inverse design of nanophotonic structures using complementary convex optimizationJesse Lu
E L Ginzton Laboratory, Stanford University, Stanford, CA 94305 4085, USA
Opt Express 18:3793-804. 2010..The design of one- and two-dimensional nanophotonic resonators is demonstrated and is shown to require minimal computational resources...
- Inverse design of a three-dimensional nanophotonic resonatorJesse Lu
Stanford University, Stanford, California 94305, USA
Opt Express 19:10563-70. 2011..5-dimensional approximation of the full three-dimensional structure. As an example, we employ the proposed method to design a resonator which exhibits a mode volume of 0.32(λ/n)3 and a quality factor of 7063...
- Coupled fiber taper extraction of 1.53 microm photoluminescence from erbium doped silicon nitride photonic crystal cavitiesGary Shambat
Department of Electrical Engineering, Stanford University, Stanford, CA 94305, USA
Opt Express 18:5964-73. 2010..This material system combined with fiber taper collection is promising for building on-chip optical amplifiers...
- Tunable-wavelength second harmonic generation from GaP photonic crystal cavities coupled to fiber tapersGary Shambat
Department of Electrical Engineering, Stanford University, Stanford 94305, USA
Opt Express 18:12176-84. 2010..By scaling cavity parameters, the signal could easily be shifted into other parts of the visible spectrum...
- Room temperature 1.6 microm electroluminescence from Ge light emitting diode on Si substrateSzu Lin Cheng
Department of Materials Science and Engineering, Stanford University, Stanford, CA 94305, USA
Opt Express 17:10019-24. 2009..These detailed studies show that Ge can be a good candidate for a Si compatible light emitting device...
- Inverse design and implementation of a wavelength demultiplexing grating couplerAlexander Y Piggott
Ginzton Laboratory, Stanford University, Stanford, CA, 94305
Sci Rep 4:7210. 2014..This inverse design concept is simple and extendable to a broad class of highly compact devices including frequency filters, mode converters, and spatial mode multiplexers. ..