A two species trap for chromium and rubidium atoms. J. Mod. Opt, (51):1807, Jan 20, 2004. [PUMA: myown Pi5 pi5_X] URL
A two-frequency acousto-optic modulator driver to improve the beam pointing stability during intensity ramps. Rev. Sci. Instrum., (78):043101, 2007. [PUMA: SFB_TRR21_A2 myown DipQuantumGases Pi5] URL
Absorption spectroscopy for laser cooling and high-fidelity detection of barium monofluoride molecules. Phys. Rev. A, (108)6:062812, American Physical Society, December 2023. [PUMA: ColdMolecules myown pi5] URL
Alignment of D-state Rydberg molecules. Phys. Rev. Lett., (112):143008, Jan 19, 2014. [PUMA: myown SFB_TRR21_B6 StrongIntRydGases Pi5 FormerProjects] URL
Amplification of light and atoms in a Bose-Einstein condensate. Phys. Rev. Lett., (85):4225, Jun 27, 2000. [PUMA: myown Pi5 pi5_X] URL
An atomic Faraday beam splitter for light generated from pump degenerate four-wave mixing in a hollow-core photonic crystal fiber. Phys. Rev. A, (103):043501, April 2021. [PUMA: myown pi5 QOpticsHotAtoms] URL
An echo experiment in a strongly interacting Rydberg gas. Phys. Rev. Lett., (100):013002, 2008. [PUMA: myown SFB_TRR21_A4 StrongIntRydGases Pi5 FormerProjects] URL
An experimental and theoretical guide to strongly interacting Rydberg gases. J. Phys. B: At. Mol. Opt. Phys., (45):113001, May 25, 2012. [PUMA: myown SFB_TRR21_B6 StrongIntRydGases Pi5 FormerProjects] URL
An intense source of cold Rb atoms from a pure two-dimensional magneto-optical trap. Phys. Rev. A., (66):023410, Aug 26, 2002. [PUMA: myown Pi5 pi5_X] URL
An optogalvanic gas sensor based on Rydberg excitations. Journal of Physics B: Atomic, Molecular and Optical Physics, (53)9:094001, 2020. [PUMA: myown pi5 TraceGasSensing] URL
Analyzing the collective emission of a Rydberg-blockaded single-photon source based on an ensemble of thermal atoms. Phys. Rev. A, (109)1:013705, American Physical Society, January 2024. [PUMA: myown pi5 QOpticsHotAtoms] URL
Anisotropic Superfluid Behavior of a Dipolar Bose-Einstein Condensate. Phys. Rev. Lett., (121):030401, Jul 17, 2018. [PUMA: myown DipQuantumGases Pi5]
Artificial atoms can do more than atoms: Deterministic single photon subtraction from arbitrary light fields. Phys. Rev. Lett., (107):093601, Aug 25, 2011. [PUMA: myown SFB_TRR21_B6 Pi5 QOpticsHotAtoms] URL
Atom based RF electric field sensing. Journal of Physics B: Atomic, (48):202001, Sep 9, 2015. [PUMA: myown Pi5 TraceGasSensing] URL
Atom Interferometry with Mechanical Structures. in "Laser Spectroscopy X", ((1992))1992. [PUMA: myown Pi5 pi5_X] URL
Atom Lithography Using Light Forces. Microelectronic Engineering, (30):383-386, Jan 1, 1996. [PUMA: myown SFB_TRR21_A1 Pi5]
Atom nanolithography with multilayer light masks: Particle optics analysis. Phys. Rev. A, (72):023417, Jul 29, 2005. [PUMA: myown Pi5 pi5_X] URL
Atom-Based Sensing of Weak Radio Frequency Electric Fields Using Homodyne Readout. Scientific Reports, (7):42981, Feb 20, 2017. [PUMA: myown Pi5 TraceGasSensing] URL
Atom-Based Vector Microwave Electrometry Using Rubidium Rydberg Atoms in a Vapor Cell. Phys. Rev. Lett., (111):063001, August 2013. [PUMA: myown Pi5 TraceGasSensing] URL
Atom-molecule coherence for ultralong range Rydberg dimers. Nature Physics, (6):970–974, Nov 21, 2010. [PUMA: myown SFB_TRR21_B6 StrongIntRydGases Pi5 FormerProjects] URL