During the period of examination, the PI moved his place of employment from Institut Néel (Grenoble, FR) to the Karlsruhe Institute of Technology (Karlsruhe, DE). Together with his new team at KIT he set up a completely new optical laboratory for the purpose of the ERC Advanced Grant objectives. This includes the whole process starting with the acquisition of totally new lab instruments, especially in relation to optics (optical components and tables, lasers, spectrometer, photo detectors, and more), followed by the consecutive installation and set up of these, up to the implementation of a new software infrastructure for the complete experimental control.
The group set up a home-built scanning confocal microscope at room temperatures for the purpose of quantum emitter investigation and application. This includes a fast and reliable optics for fluorescence excitation (pulsed and continuous wave), a 3D piezo setup for full spatial control, and a micro-wave and magnetic field setup for the application of quantum gates. At first, the nitrogen-vacancy center (NV) in diamond was the quantum emitter of interest. As this field of research was completely new for the group of the PI, the focus was first set on the general investigation of this color center and the replication of fundamental results. With the gained experience and knowledge, the group is now able to perform basic magnetometry measurements both with ensemble NV and single NV.
Furthermore, the group set up two new home-built dilution cryostats for optical experiments at milli-Kelvin temperatures. In more detail, this involves a complete scanning confocal microscope where the samples of interest can be investigated at temperatures down to 30 mK. Special care has been taken by minimizing the vibrational background of the cryostat and its gas handling system. After the successful execution of proof-of-principle experiments (all-optical), the setup is now upgraded. The new design includes a superconducting vector magnet configuration, and micro-wave and DC feedlines for mK, enabling the full quantum control of our systems of interest.
The group focused also on molecular quantum emitter. After the installation of a new broadband tunable laser system and the integration of this in both confocal microscopes, molecules such as DBATT and rare earth compounds have been intensively under investigation at room temperatures and cryogenic temperatures. New optical characterization and readout techniques have been carried out with spintronic devices. In addition, a new chemical vapor deposition system for the synthesis of carbon nanotubes needed for the molecular spin-valves was set up and successfully used to build devices. To increase the possibility and reliability to produce complex carbon nanotube circuit in spin-valve devices a nanotube stapling technique inside a scanning electron microscope has been set up and used.