Generation and characterization of microwave quantum states
Doktorsavhandling, 2022
Quantum mechanics is the branch of physics that describes the properties and behavior of systems on the atomic and subatomic level. Over the past decades there has also been considerable progress in engineering larger-scale quantum systems. In this day and age, quantum information and quantum technology are rapidly developing areas of research where quantum effects are harnessed to improve sensitivity in measurements, encrypt secure communications, and enhance the performance of information processing and computing. Specific types of quantum states are needed for these purposes, and they can be challenging to generate in practice. This thesis describes methods to generate and characterize microwave states that could be useful for quantum computing protocols based on quantum states of light.
Kollektorn A423, Kemivägen 9
Opponent: Prof. Liang Jiang, Pritzker School of Molecular Engineering, University of Chicago
Författare
Ingrid Strandberg
Chalmers, Mikroteknologi och nanovetenskap, Tillämpad kvantfysik
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The theory of quantum mechanics started developing in the 1920s to account for certain phenomena involving light and radiation that could not be explained by classical physics, such as the spectra of light emitted by atoms. Over the last decades we have seen the emergence of quantum information science which addresses the question whether we can use the quantum behavior of light to create new technologies, and indeed, it turns out that quantum effects are useful for applications in cryptography, sensing, and computing.
Advances in engineering have also resulted in the ability to fabricate controllable quantum systems that can be utilized within those fields.
There are different platforms for quantum technologies, but superconducting circuits are seen as particularly promising and large companies such as Google and Amazon are investing in this.
The perhaps most important step in order to be able to take advantage of quantum effects is quantum state preparation. Microwaves are the natural frequency range for superconducting circuits, and in this thesis we demonstrate different ways to prepare useful microwave quantum states. Additionally, we characterize the states and their properties since it is also exceedingly important to verify which state was generated.
Advances in engineering have also resulted in the ability to fabricate controllable quantum systems that can be utilized within those fields.
There are different platforms for quantum technologies, but superconducting circuits are seen as particularly promising and large companies such as Google and Amazon are investing in this.
The perhaps most important step in order to be able to take advantage of quantum effects is quantum state preparation. Microwaves are the natural frequency range for superconducting circuits, and in this thesis we demonstrate different ways to prepare useful microwave quantum states. Additionally, we characterize the states and their properties since it is also exceedingly important to verify which state was generated.
Styrkeområden
Nanovetenskap och nanoteknik
Ämneskategorier
Fysik
Nanoteknik
Datorsystem
Den kondenserade materiens fysik
ISBN
978-91-7905-671-1
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5137
Utgivare
Chalmers
Kollektorn A423, Kemivägen 9
Opponent: Prof. Liang Jiang, Pritzker School of Molecular Engineering, University of Chicago