Quantum and nanocomputing

MICRO-435

Media

This file is part of the content downloaded from Quantum and nanocomputing.

General Information

Welcome to the Quantum and Nanocomputing course. 

Classes will be held on Tuesdays from 16:15 to 19:00 in AAC132 and on Wednesdays from 13:15 to 14:00 in AAC132. Exercise sessions will be on Wednesdays from 14:15 to 16:00  in AAC132.

No Zoom link is provided.


Week 1 - Fundamentals of Quantum Computing (1)

The Bloch Sphere by Ian Glendinning


Week 2 - Fundamentals of Quantum Computing (2)

Shor's  algorithm

Qiskit introduction


Week 3 - Qubit realization & control: superconducting qubits

Qiskit Bootcamp




Week 4 - Qubit realization & control (2)

Paper on the derivation of specifications, discussed in class.

Paper and Supplementary Material on 3x3 QD array accessible using FDMA and TDMA, discussed in class.

Paper on readout of QDs using classical interface, discussed in class.



Week 5 - Cryo-CMOS components

LTspice download link.

Presentation on SPADs at sSpace link


Week 6 - Cryo-CMOS components (2)


Exercise material (zip file) and solutions (zip file).


27 October - 31 October

Week 7 - Cryo-CMOS Components (3)

               IQ Demodulation for the Measurement of Quantum States (Kadir Akin, ETH)

               Exercise (.zip)




3 November - 7 November

Introdoction to Nanocomputing part.

General view, Fabrication (Slides below).

Lecture notes - part 1

Lecture notes - part 2

Lecture notes - part 3


10 November 14 November

Molecular Transistor Conduction Basic Model

Molecular Transistor Molecules

Molecular Transistor Behavior part 1

Molecular Transistor Behavior part 2 

Molecular Transistor Behavior part 3

Molecular Transistor Behavior part 4

MT Exercises

Homework MT W9




17 November - 21 November

Molecular Transistor Modeling and simulation

Molecular Transistor circuits

Molecular Transistor circuits optional

Molecular Transistor EEBESD theory recap ans simulation

Exercises

Source files for EEBESD and dataset

Exercises in class



November 24 - November 28

Field Coupling Nanocomputing: QDot and Molecular based

Exercises W11




1 December - 5 December

Week 12 -      Field Coupling Nanocomputing: This set of slides is optional Molecular implementation  part3

                      Locgic in Memory: Nanomagnetic Field Coupling Nanocomputing - In Plane NML - part1

                       Field Coupling Nanocomputing: Molecular Implementation Circuits Example  and SCERPA dynamic simulation of FCN XOR gate (please do not disclose)                     

Exercises in the lecture of Wednesday and SCERPA for simulations


8 December - 12 December

Week 13 -    NanoMagneticLogic - part1

                      NanoMagneticLogic - part1.2

                      NanoMagneticLogic - part2

                      NanoMagneticLogic - part3-DML

                      NanoMagneticLogic - part3-PNML

In preparation of the exercise set on Wed. see the  instructions for simulator installation (OOMMF)

Exercises and files for OOMMF simulations.

Recording of the lecture of Wed 

Lecture Notes: these notes are based on a course that includes some of the contents of the Nanocomputing part of MICRO435. This document is a draft and can be considered as an integration of the course slides, but it is not to be considered an exhaustive book.  Please use these documents as an integration to better understand the lessons, not as an addition.

Part 5: Chapters 12-13-14-15-16 on Manomagnetic computing: NML, DML, PNML, Racetrack, Skyrmions




15 December - 19 December

Week 14 -      NanoMagneticLogic DomainWall - PNML - Racetracks - Skyrmions

OPTIONAL:

Exercises in the lecture of Wednesday and instructions for design and simulation CAD installing (MagCAD and Modelsim) and files



8 December - 12 December

Week 13 -      NanoMagneticLogic - part1.2

                      NanoMagneticLogic - part2

                      NanoMagneticLogic - part3-DML

                      NanoMagneticLogic - part3-PNML

In preparation of the exercise set on Wed. see the  instructions for simulator installation (OOMMF)

Exercises and files for OOMMF simulations.