Green Light On Gold Atoms

Green Light On Gold Atoms

This workshop follows the submission of a community letter, which outlined the intention to organise a community workshop is to discuss options for a quantum technology development programme coordinated at the Europe-wide level. An even more mysterious form of energy called “dark energy” accounts for about 70% of the mass-energy content of the universe. This idea stems from the observation that all galaxies seems to be receding from each other at an accelerating pace, implying that some invisible extra energy is at work. Phillips, “Laser cooling and trapping of neutral atoms”, Rev. Mod. Ashkin, “Acceleration and trapping of particles by radiation pressure”, Phys. The process described above should therefore be seen as the fission of an incoming photon from the laser into a pair of photon and phonon – akin to nuclear fission of an atom into two smaller pieces.

  • He grew up in rural Toggenburg, in eastern Switzerland, where his father owned a textile factory in the Neckertal region.
  • Using tailored magnetic potentials generated by current-carrying wires on the chip, they perform experiments on the quantum physics of atomic Bose-Einstein condensates .
  • To produce pionic helium, one of the two electrons of the helium atom is replaced by a pion.
  • Of particular importance is how single-atom transistors can be switched simultaneously on a large scale in order to perform the logical operations required of a computer chip.
  • Nano-antennas are the backbone of nanoplasmonics, a field that is profoundly impacting biosensing, photochemistry, solar energy harvesting, and photonics.

One goal of these experiments is to realize hybrid quantum systems in which ultracold atoms and a solid-state system on the chip interact coherently. In existing techniques for measuring microwaves , the field distribution has to be scanned point-by-point, so that data acquisition is slow. Moreover, most techniques only allow for a measurement of the amplitudes, but not of the phases of the microwave field. Furthermore, macroscopic probe heads used for the measurement can distort the microwave field and result in poor spatial resolution. We have recently developed a novel technique that avoids these drawbacks and allows for the direct and complete imaging of microwave magnetic fields with high spatial resolution . In this technique, tiny clouds of laser-cooled ultracold atoms serve as non-invasive probes for the microwave field.

Charge Control

By 2025, they plan to have complex processors ready for production. The ultimate goal is to integrate the new components into common silicon chips , but the researchers also see potential for use in artificial intelligence, machine learning and autonomous systems. Much like a normal light switch, the single-atom transistor consists of a switching element and two tiny electrodes that are separated by a gap; here, however, the incredibly narrow opening has the diameter of just one atom. When the switch is turned on, a single metal atom is flipped into the gap, closing the circuit.


The detection of this particle is difficult because it decays quickly. Pions decay so quickly that most of the particles have transformed in other particles by the time they reach the surface of the Earth. We are interested in controlling and measuring single electron charge transfer between molecules and ultimately within molecule–metal networks on surfaces. Recently we measured the reorganization energy upon charging a single molecule on an insulator. By showing entanglement between light and vibration in a crystal that one could hold in their finger during the experiment, the new study creates a bridge between our daily experience and the fascinating realm of quantum mechanics. The researchers used a very short laser-pulse to trigger a specific pattern of vibration inside a diamond crystal.


The resulting flow of electricity can be used to power common electronic devices—for example, a halogen lamp, as Schimmel has demonstrated in his Karlsruhe lab. In our experiment , the microwave field to be imaged drives a transition between two hyperfine states of the atoms. The probability of finding an atom in either state thereby oscillates with a Rabi frequency which depends on the local microwave field strength at the position of the atom.

To solve this problem, they developed a special measurement method to capture the spin of the carbon atom through a series of weak measurements in quick succession. As a result, they were able to keep the influence of their observation so small as to not influence the system measurably, leaving the original circular motion perceptible. The technique is based on nuclear magnetic resonance, which takes advantage of the fact that certain atomic nuclei interact with a magnetic field. A key factor here is the nuclear spin, which can be compared with the spinning of a child’s top.

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