Dr. Stephan Dürr
Stephan Dürr
Telefon: +49 89 3 29 05 - 291
Raum: A 2.22
Prof. Dr. Thomas Udem
Thomas Udem
Telefon: +49 89 3 29 05 - 282 // -257
Raum: D 0.21 // D 0.39

kommende Kolloquien



Die Gastvorträge im Rahmen des MPQ-Kolloquiums finden von April bis Juli sowie von Oktober bis Januar jeweils dienstags um 14:30 Uhr statt. Verantaltungsort ist der Herbert-Walther-Hörsaal im Foyer des Max-Planck-Instituts für Quantenoptik.

Ansprechpartner für die wissenschaftliche Organisation:

Dr. Stephan Dürr und Dr. Thomas Udem

Wenn Sie einen Vortrag im Livestream verfolgen möchten, ist es nötig, dass Sie sich in eine entsprechende Mailing Liste eintragen. Daraufhin erhalten Sie Instruktionen zum Empfang des Livestreams.


Connecting the Resource Theories of Purity and Coherence

Connecting the Resource Theories of Purity and Coherence (Prof. Dagmar Bruss)

The resource theory of quantum coherence studies the off-diagonal elements of a density matrix in a distinguished basis, whereas the resource theory of purity studies all deviations from the maximally mixed state. A direct connection between the two resource theories is established by identifying purity as the maximal coherence which is achievable by unitary operations. The states that saturate this maximum form a family of maximally coherent mixed states. Furthermore, purity bounds the maximal amount of entanglement and discord that can be generated by unitary operations, thus demonstrating that purity is the most elementary resource for quantum information processing. [mehr]

High Harmonic Generation Interferometry

High Harmonic Generation Interferometry (Prof. Nirit Dudovich)

Attosecond science is a young field of research that has rapidly evolved over the past decade. The progress in this field opened a door into a new area of research that allows one to observe multi-electron dynamics in in atoms, molecules and solids. One of the most exciting advances in atto-science is high harmonic generation (HHG) spectroscopy. It allows one to combine sub-Angstrom spatial with attosecond temporal resolution, holding the potential of resolving the structure of electronic wavefunctions as they evolve in time. [mehr]

Surface enhanced coherent Raman scattering

Surface enhanced coherent Raman scattering (Prof. Eric Potma)

Surface-enhanced Raman scattering (SERS) is a popular technique that makes it possible to boost the otherwise weak Raman effect to levels that allow single molecule detection. A coherent, nonlinear equivalent of single molecules SERS is highly attractive, because it would allow the use single vibrational quantum oscillators with a narrow line width for a host of interesting applications. The translation of SERS into the domain of coherent Raman spectroscopy (CRS) has, however, not been trivial. This presentation zooms into some of the recent accomplishments in this area, highlights single molecule CRS experiments and discusses the possibilities of performing single vibrational oscillator measurements without the use of nanoscale plasmonic antennae. [mehr]

Quantum Logic Spectroscopy with Trapped Ions

Quantum Logic Spectroscopy with Trapped Ions (Prof. Dr. Dietrich Leibfried)

Quantum logic spectroscopy uses the quantized motion of trapped charged particles as a means to indirectly control charged quantum systems and gain information on their properties. A highly controllable atomic "logic" ion indirectly helps to manipulate the system under study and to report information back to the experimenter. This allows for precise quantum control of charged systems that are hard or impossible to directly control with light fields, such as atomic ions without convenient laser cooling transitions, molecular ions or charged elementary particles such as the proton. This talk will introduce the basic ideas behind quantum logic spectroscopy and illustrate its power based on example experiments in the NIST Ion Storage Group. [mehr]

Synthesizing Light: New Tools, Wavelengths and Opportunities

Synthesizing Light: New Tools, Wavelengths and Opportunities (Prof. Dr. Scott Diddams)

Frequency synthesis is ubiquitous in all aspects of our modern technological society, with examples being found in wide ranging applications from computing, communications and navigation systems to sensors and scientific instrumentation. Historically, the generation and precise control of electromagnetic radiation has been confined to the radio frequency and microwave domains. How­ever, optical frequency combs, first introduced by Prof. T.W. Hänsch, dramatically expand the synthesis bandwidth to cover the entire terahertz and optical domains as well. [mehr]

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