A5093895814- Acoustic Wave Resonator Technologies
- Photorefractive and Nonlinear Optics
- Electromagnetic Scattering and Analysis
- Quantum optics and atomic interactions
- Quantum Computing Algorithms and Architecture
- Atomic and Subatomic Physics Research
- Atomic and Molecular Physics
- Advanced Antenna and Metasurface Technologies
- Quantum Chromodynamics and Particle Interactions
- Mechanical and Optical Resonators
- Mass Spectrometry Techniques and Applications
Universität Innsbruck
2025
We propose an experimental setup for manipulating the spontaneous emission of trapped ions, based on a spatial light modulator. Anticipated novelties include potential to entangle more than two ions through single photon detection event and control visibility spatially distinguishable emitters. The can be adapted most existing ion traps commonly used in quantum technology.
We describe how the annihilation of antiprotons can be utilized to generate highly charged synthetic qubits in an ion-trap setup. identify qubit transitions hyperfine splitting Hydrogen-like atoms composed isomer and a single electron ground state. promising candidates isomers Y, Nb, Rh, In, Sb, for which transition lies infrared whose excited state level lifetime is hundreds milliseconds, suitable metrology applications.
Levitated dipolar scatterers exhibit exceptional performance as optomechanical systems for observing quantum mechanics at the mesoscopic scale. However, their tendency to scatter light in almost any direction poses experimental challenges, particular limiting collection efficiencies and, consequently, information extractable from system. In this article, we present a setup designed enhance gleaned measurements by constraining back action specific spatial direction. This approach facilitates...