FYS1400 ¨C Introduction to Quantum Technology

Course content

In this course, you will be introduced to how quantum physics can be used in various quantum technologies. You will have an overview of basic concepts and principles in quantum physics, as well as differences between quantum physics and classical physics. You will be introduced to how different material platforms can be used, for example, to create a qubit. The difference between a qubit and classical technology will be described, as well as how qubits can be used to create quantum-based logical circuits and quantum computers. Examples will be given on how we can also utilize the principles of quantum physics to create advanced quantum sensors, for quantum information technology, and to perform complex calculations.

Learning outcome

After completing the course, you will be able to:

• describe the main differences between classical physics and quantum physics and explain some key concepts and principles in quantum physics.
• interpret experiments that demonstrate quantum effects.
• describe how superconductors, semiconductors, photons, and trapped ions can be used to create qubits and how they differ from classical bits. You will also be able to explain how qubits can be used to form logical circuits.
• describe different classifications of quantum sensors, give examples of some applications, and discuss their advantages and disadvantages compared to classical sensors.
• explain how single photons and entangled photons can be used in communication and explain the principle of quantum cryptography.
• explain what quantum gates and quantum circuits are and describe how calculations can be performed using quantum computers.
• use linear algebra and BraKet notation to calculate simple quantum systems.
• describe some of the most well-known quantum algorithms and explain how to deal with noise in quantum information technology.

Admission to the course

Students who are admitted to study programmes at UiO must each semester register which courses and exams they wish to sign up for?in Studentweb.

Recommended previous knowledge

• MAT1100 ¨C Calculus
• MAT1110 ¨C Calculus and Linear Algebra
• IN1900 ¨C Introduction to Programming with Scientific Applications

Teaching

6 hours of teaching per week, divided into lectures, group discussion seminars, and practical sessions.

In addition, there are two mandatory lab demonstrations and two mandatory programming labs.

Requirements: Successful completion of a minimum of 15 points from learning activities, consisting of:

• submission of weekly assignments (1 point each, 8 possible points)
• participation in group discussion seminars (2 points each, 12 possible points)
• presentation of a self-selected project (7 points).

Examination

• Final written exam which counts 100 % towards the final?grade.

This course has mandatory exercises that must be approved before you can sit the final?exam.

Examination support material

• ?grim og Lian: St?rrelser og enheter i fysikk og teknikk?
• Rottman: Matematisk formelsamling?
• Approved calculator?
• Formula collection that will be handed out at the examination

Language of examination

The examination text is given in Norwegian. You may submit your response in Norwegian, Swedish, Danish or English.

Grading scale

Grades are awarded on a scale from A to F, where A is the best grade and F?is a fail. Read more about?the grading system.

Resit an examination

This course offers both postponed and resit of examination. Read more:

• Illness at exams / postponed exams
• Withdrawal during an examination / Resitting an examination

More about examinations at UiO

• Use of sources and citations
• Special exam arrangements due to individual needs
• Withdrawal from an exam
• Illness at exams / postponed exams
• Explanation of grades and appeals
• Resitting an exam
• Cheating/attempted cheating

You will find further guides and resources at the web page on examinations at UiO.