TY - JOUR
T1 - Calculation of Rydberg interaction potentials
AU - Weber, Sebastian
AU - Tresp, Christoph
AU - Menke, Henri
AU - Urvoy, Alban
AU - Firstenberg, Ofer
AU - Buechler, Hans Peter
AU - Hofferberth, Sebastian
N1 - German Research Foundation through Emmy-Noether-grant [HO 4787/1-1]; German Research Foundation through GiRyd project [HO 4787/1-3]; German Research Foundation [SFB/TRR21]; Ministry of Science, Research and the Arts of Baden-Wurttemberg through RiSC grant [33-7533.-30-10/37/1]; European Union H FET Proactive project RySQ [640378]; Minerva FoundationWe thank Charles Adams, Przemyslaw Bienias, Rick van Bijnen, Antoine Browaeys, Johannes Deiglmayr, Hannes Gorniaczyk, Christian Gross, Julius de Hond, Jan Kumlin, Thierry Lahaye, Igor Lesanovsky, Weibin Li, Robert Low, Thomas Niederprum, Herwig Ott, Asaf Paris-Mandoki, Tilman Pfau, Thibault Peyronel, Pierre Pillet, Thomas Pohl, Jonathan Pritchard, Georg Raithel, James Shaffer, Nikola Sibalic, Johannes Zeiher for important discussions and for testing our pair interaction software. We are very thankful to Antoine Browaeys and Thierry Lahaye for providing their data on the angular dependence of the Forster resonance. This work is funded by the German Research Foundation through Emmy-Noether-grant HO 4787/1-1, GiRyd project HO 4787/1-3 and SFB/TRR21 and the Ministry of Science, Research and the Arts of Baden-Wurttemberg through RiSC grant 33-7533.-30-10/37/1 and the European Union H2020 FET Proactive project RySQ (grant N. 640378). OF acknowledges support from the Minerva Foundation. We thank Charles Adams, Przemyslaw Bienias, Rick van Bijnen, Antoine Browaeys, Johannes Deiglmayr, Hannes Gorniaczyk, Christian Gross, Julius de Hond, Jan Kumlin, Thierry Lahaye, Igor Lesanovsky, Weibin Li, Robert Low, Thomas Niederprum, Herwig Ott, Asaf Paris-Mandoki, Tilman Pfau, Thibault Peyronel, Pierre Pillet, Thomas Pohl, Jonathan Pritchard, Georg Raithel, James Shaffer, Nikola Sibalic, Johannes Zeiher for important discussions and for testing our pair interaction software. We are very thankful to Antoine Browaeys and Thierry Lahaye for providing their data on the angular dependence of the Forster resonance. This work is funded by the German Research Foundation through Emmy-Noether-grant HO 4787/1-1, GiRyd project HO 4787/1-3 and SFB/TRR21 and the Ministry of Science, Research and the Arts of Baden-Wurttemberg through RiSC grant 33-7533.-30-10/37/1 and the European Union H2020 FET Proactive project RySQ (grant N. 640378). OF acknowledges support from the Minerva Foundation.
PY - 2017/6/12
Y1 - 2017/6/12
N2 - The strong interaction between individual Rydberg atoms provides a powerful tool exploited in an ever-growing range of applications in quantum information science, quantum simulation and ultracold chemistry. One hallmark of the Rydberg interaction is that both its strength and angular dependence can be fine-tuned with great flexibility by choosing appropriate Rydberg states and applying external electric and magnetic fields. More and more experiments are probing this interaction at short atomic distances or with such high precision that perturbative calculations as well as restrictions to the leading dipole-dipole interaction term are no longer sufficient. In this tutorial, we review all relevant aspects of the full calculation of Rydberg interaction potentials. We discuss the derivation of the interaction Hamiltonian from the electrostatic multipole expansion, numerical and analytical methods for calculating the required electric multipole moments and the inclusion of electromagnetic fields with arbitrary direction. We focus specifically on symmetry arguments and selection rules, which greatly reduce the size of the Hamiltonian matrix, enabling the direct diagonalization of the Hamiltonian up to higher multipole orders on a desktop computer. Finally, we present example calculations showing the relevance of the full interaction calculation to current experiments. Our software for calculating Rydberg potentials including all features discussed in this tutorial is available as open source.
AB - The strong interaction between individual Rydberg atoms provides a powerful tool exploited in an ever-growing range of applications in quantum information science, quantum simulation and ultracold chemistry. One hallmark of the Rydberg interaction is that both its strength and angular dependence can be fine-tuned with great flexibility by choosing appropriate Rydberg states and applying external electric and magnetic fields. More and more experiments are probing this interaction at short atomic distances or with such high precision that perturbative calculations as well as restrictions to the leading dipole-dipole interaction term are no longer sufficient. In this tutorial, we review all relevant aspects of the full calculation of Rydberg interaction potentials. We discuss the derivation of the interaction Hamiltonian from the electrostatic multipole expansion, numerical and analytical methods for calculating the required electric multipole moments and the inclusion of electromagnetic fields with arbitrary direction. We focus specifically on symmetry arguments and selection rules, which greatly reduce the size of the Hamiltonian matrix, enabling the direct diagonalization of the Hamiltonian up to higher multipole orders on a desktop computer. Finally, we present example calculations showing the relevance of the full interaction calculation to current experiments. Our software for calculating Rydberg potentials including all features discussed in this tutorial is available as open source.
UR - http://www.scopus.com/inward/record.url?scp=85020551110&partnerID=8YFLogxK
U2 - https://doi.org/10.1088/1361-6455/aa743a
DO - https://doi.org/10.1088/1361-6455/aa743a
M3 - مقالة
SN - 0953-4075
VL - 50
JO - Journal of Physics B: Atomic, Molecular and Optical Physics
JF - Journal of Physics B: Atomic, Molecular and Optical Physics
IS - 13
M1 - 133001
ER -