logo-polimi
Loading...
Bibliographic resources
Bibliography mandatory
Bibliography not mandatory
Summary Teaching Assignment
Academic Year 2015/2016
School School of Industrial and Information Engineering
Course 096061 - MICRO- AND NANO-OPTICS [C.I.]
  • 096060 - MICRO AND NANOOPTICS [2]
Cfu 5.00 Type of Course Module
Lecturers: Titolare (Co-titolari) Della Valle Giuseppe

Programme Track From (included) To (excluded) Course
Ing Ind - Inf (Mag.)(ord. 270) - MI (486) ENGINEERING PHYSICS - INGEGNERIA FISICA*AZZZZ096510 - NANO OPTICS
096061 - MICRO AND NANOOPTICS [C.I.]

Detailed program and learning outcomes

Micro and nanooptics [2]

Objectives:

Aim of the course is the study of the theoretical foundations and of the main applications of Microoptics and Nanooptics.

Syllabus:

Theoretical Foundations.
 Electromagnetism as an Eigenvalue Problem: Electromagnetic Harmonic Modes, Symmetries and Classification of Harmonic Modes, Variational Principle in Electromagnetism, Scaling Properties of Maxwell's Equations. Wave propagation in homogeneous and inhomogeneous media: Angular Spectrum Representation, Scalar Diffraction Theories, TE-TM Decomposition, Evanescent waves.

Microoptical Elements.
 Optical functions and their implementation. Classification of Microoptical Elements. Refractive Microoptics: Profiled microlenses and their applications, Gradient-index (GRIN) microoptical elements (fiber/rod microlenses), Paraxial approximation (the optical Schrodinger equation), Applications of parabolic GRIN fiber/rod microlenses. Introduction to diffractive microoptical elements: microprisms, microlenses.



Photonic Crystals.
 Generalities on periodic lattices. Bloch Electromagnetic Theorem. Photonic Band Structure.
 One-dimensional PCs: Periodic Layered Media, Band States and Gap States, Surface States and Bulk Defect States, Applications to Bragg Reflectors and Filters, Omnidirectional Dielectric Mirrors, Photonic Bragg Fibers. Two-dimensional PCs: A polarization-indepenendent band-gap, Point and Line Defects and application to PC cavities and waveguides, Out-of-plane propagation, PC fibers. PC Interfaces: Negative Refraction, Superlens and Superprism Effects.



Near-field Optics and Plasmonics.
 The diffraction limit to optical imaging. From the far-field to the near-field. The near-field microscope and its applications.
 Aims and methods of Plasmonics. Optical properties of noble metals. Surface Plasmon Polaritons (SPPs): Derivation of the SPPs dispersion equation, Optical properties of SPPs, Excitation and detection of SPPs, Plasmon-Polaritons in thin metallic films (SR/LR-SPPs), Introduction to plasmonic waveguides. Localized plasmons (LPs): Quasistatic theory of localized plasmonic resonances in noble metal nanospheres, Optical properties of metallic nanoparticles (resonant polarizability, absorption and scattering cross-sections, field-enhancement, resonance tuning), Introduction to plasmonic nanosensing (SPR and SERS).

 

 


Notes on methods of assessing

Exam:

Written examination, optionally followed by oral examination.


Bibliography

Software used
No software required

Didactic forms
Type of didactic form Teaching hours
lesson
35.0
training
10.0
computer laboratory
0.0
experimental laboratory
0.0
project
0.0
project laboratory
0.0

Information in English to support internationalization
Course offered in English
Study material/slides available in English
Textbook/Bibliography available in English
It is possible to take the examination in English
schedaincarico v. 1.10.0 / 1.10.0
Area Servizi ICT
15/07/2024