Nanophotonic Modeling - 2016

Nanophotonic Modeling - 2016

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nanoHUB-U Nanophotonic Modeling L1.15: Methods for Solving the Photonic Bandstructure

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nanoHUB-U Nanophotonic Modeling L1.15: Methods for Solving the Photonic Bandstructure

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Nanophotonic Modeling - 2016

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  1. 1 nanoHUB-U Nanophotonic Modeling L1.1: Introduction
  2. 2 nanoHUB-U Nanophotonic Modeling L1.2: Bloch Theorem
  3. 3 nanoHUB-U Nanophotonic Modeling L1.3: 1D Bandstructures
  4. 4 nanoHUB-U Nanophotonic Modeling L1.4: Reciprocal Lattice Vectors
  5. 5 nanoHUB-U Nanophotonic Modeling L1.5: 2D Bandstructures
  6. 6 nanoHUB-U Nanophotonic Modeling L1.6: 2D Photonic Crystal Bandgaps
  7. 7 nanoHUB-U Nanophotonic Modeling L1.7: Sysmmetries in 2D Photonic Crystals
  8. 8 nanoHUB-U Nanophotonic Modeling L1.8: Defects in 2D Photonic Crystals
  9. 9 nanoHUB-U Nanophotonic Modeling L1.9: Photonic Crystals 1D Periodic Waveguides
  10. 10 nanoHUB-U Nanophotonic Modeling L1.10: Photonic Crystal Slabs
  11. 11 nanoHUB-U Nanophotonic Modeling L1.11: Other 2D Photonic Structures
  12. 12 nanoHUB-U Nanophotonic Modeling L1.12: 3D Photonic Crystals
  13. 13 nanoHUB-U Nanophotonic Modeling L1.13: Rod-Hole 3D Photonic Crystals
  14. 14 nanoHUB-U Nanophotonic Modeling L1.14: Formulating the Photonic Bandstructure Calculation
  15. 15 nanoHUB-U Nanophotonic Modeling L1.15: Methods for Solving the Photonic Bandstructure
  16. 16 nanoHUB-U Nanophotonic Modeling L1.16: Eigensolvers for Bandstructure Calculations
  17. 17 nanoHUB-U Nanophotonic Modeling L1.17: Targeted Eigensolvers
  18. 18 nanoHUB-U Nanophotonic Modeling L1.18: Running MIT Photonic Bands
  19. 19 nanoHUB-U Nanophotonic Modeling L1.19: MPB for Triangular Lattices
  20. 20 nanoHUB-U Nanophotonic Modeling L1.20: MPB for 3D Lattices and Bandgap Maximization
  21. 21 nanoHUB-U Nanophotonic Modeling L1.21: Finding Point Defects in MPB
  22. 22 nanoHUB-U Nanophotonic Modeling L1.22: Summary of Unit 1
  23. 23 nanoHUB-U Nanophotonic Modeling L2.1: Introduction
  24. 24 nanoHUB-U Nanophotonic Modeling L2.2: Connecting Ray Optical Matrices
  25. 25 nanoHUB-U Nanophotonic Modeling L2.3: Wave Optical Matrices
  26. 26 nanoHUB-U Nanophotonic Modeling L2.4: T-Matrices
  27. 27 nanoHUB-U Nanophotonic Modeling L2.5: S-Matrices
  28. 28 nanoHUB-U Nanophotonic Modeling L2.6: S-Matrices with Periodicity
  29. 29 nanoHUB-U Nanophotonic Modeling L2.7: S-Matrices with Periodicity II
  30. 30 nanoHUB-U Nanophotonic Modeling L2.8: Comparison of S-Matrices with Other Approaches
  31. 31 nanoHUB-U Nanophotonic Modeling L2.9: Photonic Simulations with S4
  32. 32 nanoHUB-U Nanophotonic Modeling L2.10: S4 GUI Input
  33. 33 nanoHUB-U Nanophotonic Modeling L2.11: S4 GUI Output
  34. 34 nanoHUB-U Nanophotonic Modeling L2.12: CAMFR Rationale
  35. 35 nanoHUB-U Nanophotonic Modeling L2.13: CAMFR Boundary Conditions
  36. 36 nanoHUB-U Nanophotonic Modeling L2.14: CAMFR Usage I
  37. 37 nanoHUB-U Nanophotonic Modeling L2.15: CAMFR Usage II
  38. 38 nanoHUB-U Nanophotonic Modeling L2.16: CAMFR Usage III
  39. 39 nanoHUB-U Nanophotonic Modeling L2.17: Metasurface S-Matrix Calculations
  40. 40 nanoHUB-U Nanophotonic Modeling L2.18: Light Trapping with Metasurfaces
  41. 41 nanoHUB-U Nanophotonic Modeling L2.19: Unit 2 Summary & Conclusions
  42. 42 nanoHUB-U Nanophotonic Modeling L3.01: Unit 3 Introduction
  43. 43 nanoHUB-U Nanophotonic Modeling L3.02: Finite Difference Time Domain Method
  44. 44 nanoHUB-U Nanophotonic Modeling L3.03: 3D FDTD
  45. 45 nanoHUB-U Nanophotonic Modeling L3.4: MEEP - An FDTD Solver
  46. 46 nanoHUB-U Nanophotonic Modeling L3.5: Light Trapping in Photovoltaics
  47. 47 nanoHUB-U Nanophotonic Modeling L3.6: FDTD Dispersion Modeling with QCRF
  48. 48 nanoHUB-U Nanophotonic Modeling L3.7: Tandem Photovoltaic Modeling in FDTD
  49. 49 nanoHUB-U Nanophotonic Modeling L3.8: Characterizing Perovskite Silicon Tandem Photovoltaic Cells
  50. 50 nanoHUB-U Nanophotonic Modeling L3.9: MEEP - Basic Usage
  51. 51 nanoHUB-U Nanophotonic Modeling L3.10: MEEP - Index Guided Waveguides
  52. 52 nanoHUB-U Nanophotonic Modeling L3.11: MEEP - Bent Waveguides
  53. 53 nanoHUB-U Nanophotonic Modeling L3.12: MEEP - Ring Resonators I
  54. 54 nanoHUB-U Nanophotonic Modeling L3.13: MEEP - Ring Resonators II
  55. 55 nanoHUB-U Nanophotonic Modeling L3.14: MEEP - Kerr Nonlinearities
  56. 56 nanoHUB-U Nanophotonic Modeling L3.15: MEEP - Photonic Bandstructures
  57. 57 nanoHUB-U Nanophotonic Modeling L3.16: MEEP - Defect Resonant Modes
  58. 58 nanoHUB-U Nanophotonic Modeling L3.17: MEEP - Waveguide Transmission
  59. 59 nanoHUB-U Nanophotonic Modeling L3.18: FDTD Validation Against Experiment
  60. 60 nanoHUB-U Nanophotonic Modeling L3.19: Plasmonic Nanoparticle Light Trapping
  61. 61 nanoHUB-U Nanophotonic Modeling L3.20: Local Density of States
  62. 62 nanoHUB-U Nanophotonic Modeling L3.21: Local Density of States in Omniguide Fibers
  63. 63 nanoHUB-U Nanophotonic Modeling L3.22: Unit 3 Summary and Conclusions
  64. 64 nanoHUB-U Nanophotonic Modeling L4.1: Unit 4 Introduction
  65. 65 nanoHUB-U Nanophotonic Modeling L4.2: Time-Domain Laser Simulation
  66. 66 nanoHUB-U Nanophotonic Modeling L4.3: Photonic Crystal Lasers
  67. 67 nanoHUB-U Nanophotonic Modeling L4.4: Omniguide Fiber Lasers
  68. 68 nanoHUB-U Nanophotonic Modeling L4.5: Beam Propagation Method
  69. 69 nanoHUB-U Nanophotonic Modeling L4.6: Basis Choices for Beam Propagation Method
  70. 70 nanoHUB-U Nanophotonic Modeling L4.7: Introduction to Finite Element Method (FEM)
  71. 71 nanoHUB-U Nanophotonic Modeling L4.8: Galerkin Method for Finite Element Problems
  72. 72 nanoHUB-U Nanophotonic Modeling L4.9: Improving FEM Accuracy
  73. 73 nanoHUB-U Nanophotonic Modeling L4.10: An FEM Waveguide Mode Solver
  74. 74 nanoHUB-U Nanophotonic Modeling L4.11: Evaluating FEM Waveguide Solvers
  75. 75 nanoHUB-U Nanophotonic Modeling L4.12: Mode Solutions for Photonic Crystal Fibers
  76. 76 nanoHUB-U Nanophotonic Modeling L4.13: Introduction to Thermal Transport
  77. 77 nanoHUB-U Nanophotonic Modeling L4.14: Thermal Transport Modeling
  78. 78 nanoHUB-U Nanophotonic Modeling L4.15: FAESOR: A MATLAB Toolbox for FEM Modeling
  79. 79 nanoHUB-U Nanophotonic Modeling L4.16: FEM Modeling Examples
  80. 80 nanoHUB-U Nanophotonic Modeling L4.17: Evaluating the Accuracy of Thermal FEM
  81. 81 nanoHUB-U Nanophotonic Modeling L4.18: Blackbody Radiation
  82. 82 nanoHUB-U Nanophotonic Modeling L4.19: Thermophotovoltaic Concepts
  83. 83 nanoHUB-U Nanophotonic Modeling L4.20: Thermophotovoltaic Model Validation
  84. 84 nanoHUB-U Nanophotonic Modeling L4.21: Future Research in Thermophotovoltaics
  85. 85 nanoHUB-U Nanophotonic Modeling L4.22: Summary & Conclusions

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