Integrating quantum components into traditional microchip technology to enhance the performance of electronics
Quantum Motion
Imperial College London
One of the most promising platforms in the rapidly evolving field of quantum technologies is silicon. This type of manufacturing material allows for the fabrication of microchips with billions of transistors and shown the capability to implement high quality quantum dot structures at large scale.
Alberto aims to explore the intersection of these two silicon capabilities for applications in the field of cryogenic electronics. The developments in this field have been focused on optimizing circuit designs to account for changes in classical components properties at cryogenic temperatures, however with this project, Alberto hopes to use the unique properties of quantum dot structures to design circuits that improve the existing cryoelectronic solutions.
With applications in quantum computing and sensing, astronomy, and nuclear resonance tomography, this research hopes to demonstrate a practical use case of quantum dots in cryoelectronic analogue integrated circuits.
Biography:
Alberto has over 10 years of experience in the integrated circuit design industry, having worked primarily as an Analogue Integrated Circuit Design Engineer. He holds an MEng in Industrial Engineering, specializing in Electronics, and an MSc in Analogue and Digital Integrated Circuit Design. Additionally, Alberto earned a Distinction in Quantum Technologies from UCL. Currently, he leads the Analogue Integrated Circuit Design Group at Quantum Motion Technology, focusing on the design of cryoelectronic systems essential for controlling large-scale quantum computers. Alberto aims to further explore the intersection between quantum technologies and circuit engineering in the field of cryogenic electronics.