Microelectronics

CAD submicron elements and integrated circuits?

And straight to the point:
Recommend video tutorials/demonstrations showing how similar applications and systems work. The more topical the better, you can in English!
A bit of verbiage
There was a need to pass the course "Design and Technology of Electronic Component Base" ahead of schedule, but there is no opportunity to look at a variety of CAD systems. NIIIS uses TCAD Sentaurus and it appears in all issues. I found one article in the Electronics magazine, where this software is advertised using the example of Omega FinFET, but I want to watch some videos, maybe I can create something myself.
Total:
1. I'm looking for educational videos on how TCAD Sentaurus works. On off. The synopsis website is very boringly written and there is very little on the physical basis.
2. I'm looking for similar software where I can dig around for free and look at the calculation of photolithography, annealing and ion implantation within one tech. process.
Here is a list of course questions, who may be interested
. 32 questions 1. Hierarchy of modeling and design of micro- and nanostructures of electronic component base products. The concept of end-to-end design of microelectronics products on the example of CAD "TCAD Sentaurus".
2. Hierarchy of modeling and design of micro- and nanostructures of products of electronic component base. The concept of the physical and technological level of design.
3. Hierarchy of modeling and design of micro- and nanostructures of products of electronic component base. The concept of the physical-topological level of design.
4. Hierarchy of modeling and design of micro- and nanostructures of products of electronic component base. The concept of circuit design level.
5. Hierarchy of modeling and design of micro- and nanostructures of products of electronic component base. The concept of the functional-logical level of design.
6. Relationship between the processes of technology development and design of microelectronic products. Moore's law.
7. Physical and technological limitations of microelectronics production technology.
8. Modeling of the main stages of the technological process of manufacturing microelectronic products. Implementation of modeling of technological processes in CAD "TCAD Sentaurus" (epitaxy, ion implantation, diffusion, oxidation)
9. Simulation of the process of ion doping. TRIM algorithm.
10. Interaction of ions with an amorphous target. crystal targets. channeling effect.
11. Interaction of ions with a crystalline target. The concept of dielectric formalism.
12. Features of simulation of diffusion processes, processes of epitaxy and oxidation.
13. Hierarchy of mathematical models of charge carrier transport in semiconductor structures. Implementation of charge carrier transport models in CAD "TCAD Sentaurus".
14. Transfer of charge carriers in nanostructures. Longitudinal and transverse quantization.
15. Transfer of charge carriers in submicron structures. Limits of applicability of the Boltzmann kinetic equation. Particle method based on the Monte Carlo procedure for solving the Boltzmann kinetic equation.
16. Transfer of charge carriers in submicron structures. System of equations of quasi-hydrodynamic approximation. Limits of applicability of the quasi-hydrodynamic approximation.
17. Transfer of charge carriers in micron structures. System of equations of diffusion-drift approximation. Limits of applicability of the diffusion-drift approximation.
18. Methods for the numerical solution of systems of equations for diffusion-drift and quasi-hydrodynamic approximations. Splitting method according to physical processes (Hummel method).
19. Methods for the numerical solution of systems of equations for diffusion-drift and quasi-hydrodynamic approximations. The method of direct reduction of the system of transfer equations to the system of differential-algebraic equations and features of its solution.
20. Methods for describing a linear quadripole. Impulse and amplitude-frequency characteristics of a linear quadripole. S-, Y-, Z-, H- and G-parameters of a quadripole.
21. Features of the description of a nonlinear quadripole.
22. Equivalent circuit of a semiconductor diode.
23. Equivalent circuit of a bipolar transistor.
24. Equivalent circuit of a field effect transistor.
25. Macro modeling of analog integrated circuits. Design of microwave monolithic integrated circuits in the program Microwave Office.
26. Basic logic elements and their circuit implementation.
27. Trigger devices and their circuit implementation.
28. Asynchronous counter and its circuit implementation.
29. Synchronous counter and its circuit implementation.
30. Static memory cell and its circuit implementation.
31. Fundamentals of microprocessor architecture.
32. The concepts of accuracy and reliability of the results of modeling the electronic component base.