Quantum Optics
Condensed Matter and Quantum Optics Laboratory
Quantum Optics
Condensed Matter and Quantum Optics Laboratory
Study of the optical properties of single molecules for quantum information
The student adjusts lasers of different wavelengths that will be directed at the molecules by coupling them to unimodal optical fibers.
Atomic and confocal force microscope for the study of defects in two-dimensional materials such as boron nitride for applications in quantum metrology.
Student and professor analyze the topology of a sample with diamond nanoparticles using atomic microscopy and confocal microscopy to develop nanoscale sensors based on quantum mechanics.
Experimental setup for the study of magnetic particles.
Experimental setup for the study of light-trapped magnetic particles for the study of spin frustration in triangular geometrical configurations.
Students analyze the response of single molecules trapped by light under the effect of Brownian motion in the setup of optical tweezers.
Microscope temperature monitoring system using infrared light.
Microscope temperature monitoring system using infrared light.
Setup for the study of magnetic properties of thin films by using nitrogen-vacancy color centers in diamond.
Setup for the study of magnetic properties of thin films by using nitrogen-vacancy color centers in diamond.
Student works on the setup of electron spin resonance and confocal microscopy.
Student works on the setup of electron spin resonance and confocal microscopy to detect the properties of magnetic materials with perpendicular-to-plane anisotropy using the optically detected magnetic resonance technique.
Study of the optical properties of single molecules for quantum information
The student adjusts lasers of different wavelengths that will be directed at the molecules by coupling them to unimodal optical fibers.
Atomic and confocal force microscope for the study of defects in two-dimensional materials such as boron nitride for applications in quantum metrology.
Student and professor analyze the topology of a sample with diamond nanoparticles using atomic microscopy and confocal microscopy to develop nanoscale sensors based on quantum mechanics.
Experimental setup for the study of magnetic particles.
Experimental setup for the study of light-trapped magnetic particles for the study of spin frustration in triangular geometrical configurations.
Students analyze the response of single molecules trapped by light under the effect of Brownian motion in the setup of optical tweezers.
Microscope temperature monitoring system using infrared light.
Microscope temperature monitoring system using infrared light.
Setup for the study of magnetic properties of thin films by using nitrogen-vacancy color centers in diamond.
Setup for the study of magnetic properties of thin films by using nitrogen-vacancy color centers in diamond.
Student works on the setup of electron spin resonance and confocal microscopy.
Student works on the setup of electron spin resonance and confocal microscopy to detect the properties of magnetic materials with perpendicular-to-plane anisotropy using the optically detected magnetic resonance technique.
Welcome to the Condensed Matter and Quantum Optics Laboratory. Directed by professor Jerónimo Maze. In this laboratory we carry out experimental research in Experimental Condensed Matter Physics.
We invite you to click on each of the highlighted points to learn more about our techniques and equipment.