Electromagnetism and material physics, including basic elements of quantum mechanics. 

• face to face delivery
• class discussions
• visits to labs and presentation of experimental practices

1. 1. Generalities on the topic

   Aims and motivations for spectroscopy of nanomaterials, specific properties of nanostructures including biomimetics, size limits of the nanoworld, technological issues. The main problem of optics in the nanoworld: interference and diffraction in optics. Electron microscopy as a benchmark and a reference for nanoscopy: general instrumental configurations of SEM and TEM, main contrast mechanisms, secondary and backscattered electrons. Spectroscopies with electrons/X-rays: AES, EDS/EDAX, XPS. 

    

   2. Optical microscopy/spectroscopy and nanomaterials

   Ray optics, lenses and magnification in a microscope, Gaussian beams and focusing, diffraction and interference. Few words on Fourier optics: PSF and resolving power according to Rayleigh, Abbe, and Sparrow criteria. Conventional optical microscopy and some variants: polarization, differential interference, white light profilometry. Fluorescence microscopy, organic chromophores, reminders of molecular levels and transitions, biophysical applications: epi-fluorescence, illuminations issues, dark field microscopy. Confocal configurations of optical microscopy/spectroscopy, examples. MicroRaman, coherent Raman (CRS/CARS) and other advanced spectroscopies at the micro-scale, examples and measurement of various material properties at the micro- and nanoscale.

    

   3. Super-resolution optical microscopies

   Stimulated emission in a multi-level system, pumping and saturation. Spiral phase plates, optical vortices, doughnut modes. STED, resolving power, examples of applications. Other super-resolved microscopies (PALM, STORM, 4Pi, light-sheet, double beam, etc.)

    

   4. Quantum confinement and optical properties of semiconductor nanostructures

   Reminders of bulk semiconductor properties, direct and indirect transitions. Reminders of quantum mechanics and the problem of the potential well (infinite and finite). Confinement and 2-D (quantum wells), 1-D (quantum wires), 0-D (quantum dots) nanostructures: quasi-discrete levels, interband and intraband transitions, sub- and mini-bands, excitons in confined systems, density of states and dimensionality. Absorption and emission properties in quantum dots, including core-shell systems, related technologies and some applications, in particular in optical nanoscopy and nano-photonics.

    

    

   5. Plasmonics at a surface 

   Introduction to plasmonics: plasma frequency in metals and bulk plasmons, interband transitions and their role, complex dielectric constant and refractive index, Drude model. Surface plasmon polaritons at plane interfaces: solution of the electromagnetic problem leading to longitudinal e.m. waves stemming from surface charge oscillations, evanescent behavior and dispersion relation. Excitation of plasmon modes: through evanescent waves, including near-fields, gratings, high aperture objectives (TIRF microscopy). Visualization of plasmon modes via leakage microscopy (Fourier plane imaging) and collection-mode near-field microscopy. Surface plasmon spectroscopy and applications. Main optical properties of graphene and plasmonics in graphene: examples with apertureless near-field microscopy.

    

   6. Plasmonics at a nanoparticle

   Emission of radiation in the far-field from oscillating dipoles according to the Maxwell equations, Larmor’s formula. Scattering from nanostructures: dipole and multipole contributions (Rayleigh and Mie); Clausius-Mossotti expression of dielectric constant. Localized surface plasmon resonances, optical extinction, dispersion relation, a few words on geometrical issues (beads, wires and other shapes): role of localized plasmon resonances in optics and photonics, plasmonic nanostructures as markers in microscopy, sensing applications, a few words on plasmon-based therapeutics, local field enhancement and the concept of nano-antennas, transfer of e.m. energy through plasmonic waveguides. SERS-active substrates for enhanced Raman spectropcopies: examples.  

    

   7. Photonic band-gap structures and metamaterials

   Bragg interference in planar and non-planar structures, transmission and reflection, occurrence of a photonic band-gap: similarities with the electron wavefunctions in solid-state materials and with the energy gap in crystalline semiconductors. Survey of photonic band-gap nanostructures in one and two dimensions, including fabrication. Examples of applications: photonic crystal fibers and super-continuum generation, waveguides and photonic components, optical spectroscopies, laser cavities. Basics of metamaterials: tuning the e.m. properties of a system through structural engineering, control of the magnetic permeability, single and double negative materials, negative refractive index; open possibilities and perspective applications of metamaterials in different fields.

    

   8. Scanning probe microscopies for the spectroscopy of nanomaterials: STM

   Concepts and basic elements of SPMs: piezoelectric scanners and probes, the invention of STM and the role of feedback. Reminders of tunnel effect including semi-classical approximations for trapezoidal barriers, role of material properties (work function) and related spectroscopies, examples. Advanced quantum pictures of tunneling: role of local density of states and bias-based spectroscopies, s- and p-wave tunneling and functionalized probes, observation of “molecular orbitals” in isolated molecules, examples including UHV and low-temperature STM.

    

   9. AFM and some variants 

   Measurement of small forces through a cantilever and optical lever, technology of AFM probes. Forces between a tip and a surface: general considerations, Hertzian contact, Hamaker attraction. Operating modes of an AFM: contact vs tapping mode, modulation/demodulation (amplitude, phase, frequency), phase maps and their physical interpretation (in intermittent contact), constant amplitude and multi-modal AFM. Examples, including in liquid operation, and related force spectroscopies. Lateral forces and nanotribology, electric and piezoelectric force microscopy with examples, nanoindentation and spectroscopies for the investigation of mechanical properties at the nanoscale.

    

   10. Optical near-fields and SNOM

   General concepts of near-field, calculation of the near-field produced by an oscillating dipole, ideal problems (Bethe-Bouwkamp), evanescent character and practical implementations. Basics of near-field microscopy in the emission mode: probes and related technologies, the shear-force method, range of spectroscopies accessible by SNOM, including collection mode of operation. Examples of fluorescence and label-free spectroscopy with biological materials, applications to surface and localized plasmons. Polarization-modulated spectroscopies and applications in the near-field. Apertureless (scattering) SNOM: pros and cons, single molecule fluorescence, IR spectroscopy in the near-field, a few words on THz SNOM. Tip-enhanced Raman spectroscopy and examples of TERS.

The relevant and specific bibliography for every topic of the course, including also a wide collection of research papers available in the e-learning site, is communicated to the students at the end of the lectures.

 Keep preliminarly in touch with the lecturer and visit the relevant web pages of the e-learning site for the didactical materials.

Oral final exam, partly fulfilled through a short presentation on a topic chosen in agreement with the lecturers.