Dein Suchergebnis zum Thema: Ritter

The researchers at the Max-Planck-Institut für Kohlenforschung aim to develop new, tailor-made catalysts – products that accelerate chemical reactions without themselves being changed. With the aid of catalysts, natural products and medically-active substances with a complicated structure can be efficiently synthesised; similarly, biomass can be converted to fuels and key basic chemicals.
Theory and Spectroscopy +49 208 306-2190 frank.neese@kofo.mpg.de more Tobias Ritter

The researchers at the Max-Planck-Institut für Kohlenforschung aim to develop new, tailor-made catalysts – products that accelerate chemical reactions without themselves being changed. With the aid of catalysts, natural products and medically-active substances with a complicated structure can be efficiently synthesised; similarly, biomass can be converted to fuels and key basic chemicals.
Theory and Spectroscopy +49 208 306-2190 frank.neese@kofo.mpg.de more Tobias Ritter

Ein Quantengatter, das ein Team um G. Rempe am Max-Planck-Institut für Quantenoptik entwickelt hat, bewirkt eine logische Verknüpfung zwischen einem Atom in einem Resonator und einem Photon. Ein solches CNOT-Gatter an zwei Qubits ist essentiell für einen Quantencomputer, könnte aber auch bei der Quantenkommunikation wie der Quantenkryptographie oder in Quantennetzwerken zum Einsatz kommen.
© Stephan Ritter / MPI für Quantenoptik Die digitale Revolution dürfte in der

The researchers at the Max-Planck-Institut für Kohlenforschung aim to develop new, tailor-made catalysts – products that accelerate chemical reactions without themselves being changed. With the aid of catalysts, natural products and medically-active substances with a complicated structure can be efficiently synthesised; similarly, biomass can be converted to fuels and key basic chemicals.
Theory and Spectroscopy +49 208 306-2190 frank.neese@kofo.mpg.de more Tobias Ritter

The researchers at the Max-Planck-Institut für Kohlenforschung aim to develop new, tailor-made catalysts – products that accelerate chemical reactions without themselves being changed. With the aid of catalysts, natural products and medically-active substances with a complicated structure can be efficiently synthesised; similarly, biomass can be converted to fuels and key basic chemicals.
Theory and Spectroscopy +49 208 306-2190 frank.neese@kofo.mpg.de more Tobias Ritter

The researchers at the Max-Planck-Institut für Kohlenforschung aim to develop new, tailor-made catalysts – products that accelerate chemical reactions without themselves being changed. With the aid of catalysts, natural products and medically-active substances with a complicated structure can be efficiently synthesised; similarly, biomass can be converted to fuels and key basic chemicals.
Theory and Spectroscopy +49 208 306-2190 frank.neese@kofo.mpg.de more Tobias Ritter

The researchers at the Max-Planck-Institut für Kohlenforschung aim to develop new, tailor-made catalysts – products that accelerate chemical reactions without themselves being changed. With the aid of catalysts, natural products and medically-active substances with a complicated structure can be efficiently synthesised; similarly, biomass can be converted to fuels and key basic chemicals.
Theory and Spectroscopy +49 208 306-2190 frank.neese@kofo.mpg.de more Tobias Ritter

With a quantum gate Max Planck physicists are developing an essential logic element for quantum computers.
© Stephan Ritter / MPI of Quantum Optics Atoms and photons under control: Two

Wissenschaftliche Publikationen
.; Ritter, T.: Illuminating aromatic deuteration.

Quantenkryptographie ermöglicht heute bereits abhörsichere Kommunikation, ist aber mit bestehender Technologie auf Entfernungen unter 100 km limitiert. Ein Quantenrepeater könnte dieses Problem im Prinzip lösen, ist aber leider noch nicht realisiert worden. Wir verfolgen zwei verschiedene experimentelle Ansätze, um ein Quantengatter für Photonen zu bauen, welches als essentieller Baustein für einen Quantenrepeater benötigt wird.
Ritter A quantum gate between a flying optical photon and a single trapped atom