Research project A05 – SFB 1227 DQ-mat – Leibniz University Hannover

Introduction

The primary goal of this project is to advance the theoretical and practical frameworks of atom interferometry, focusing on extending both one-dimensional and large-momentum-transfer (LMT) models to incorporate three-dimensional aspects, inelastic scattering processes, and complex light-matter interactions. This includes optimising light pulse sequences for improved metrological accuracy, developing robust computational methods for analysing gravitational interactions of quantum systems and classical gravitational fields, and tailoring these advancements for diverse applications ranging from gravimetry to space projects. Collectively, these efforts aim to overcome current limitations in precision measurements and theoretical understanding, enhancing the utility of atom interferometry in various scientific and practical domains.

Results

In the previous funding period, we developed an analytical microscopic theory for high-order Bragg diffraction based on the adiabatic theorem. We presented a theoretical framework for analysing such pulses, grounded in the profound insight that the physics of Bragg pulses can be effectively described by the adiabatic theorem. Our research demonstrated that efficient Bragg diffraction can be achieved with any smoothly varying and adiabatic pulse shape, with high-fidelity Gaussian pulses being a prime example of such adiabatic pulses.

Another goal of the previous funding period was to set up a systematic mathematical scheme that would allow to compute in a systematic fashion all those additional terms in the Hamiltonian that result from the interaction of the system with an external gravitational field. Our approach was based on a well defined expansion scheme in terms of the inverse of the velocity of light (a so-called post-Newtonian approximation). This led to novel expansion techniques which we subsequently applied to a electromagnetically bound 2- body system (called “atom”), thereby giving the first complete and systematic derivation of all couplings such systems to the Eddington-Robertson class of spherically symmetric and static gravitational fields.

Publications

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Showing results 21 - 26 out of 26

Corgier R, Loriani S, Ahlers H, Posso-Trujillo K, Schubert C, Rasel EM et al. Interacting quantum mixtures for precision atom interferometry. New Journal of Physics. 2020 Dec 11;22(12):123008. doi: 10.1088/1367-2630/abcbc8

Fitzek F, Siemß JN, Seckmeyer S, Ahlers H, Rasel EM, Hammerer K et al. Universal atom interferometer simulation of elastic scattering processes. Scientific Reports. 2020 Dec 17;10(1):22120. doi: 10.1038/s41598-020-78859-1, 10.15488/10752

Hartmann S, Jenewein J, Giese E, Abend S, Roura A, Rasel EM et al. Regimes of atomic diffraction: Raman versus bragg diffraction in retroreflective geometries. Physical Review A. 2020 May 8;101(5):053610. doi: 10.1103/PhysRevA.101.053610

Loriani S, Schubert C, Schlippert D, Ertmer W, Pereira Dos Santos F, Rasel EM et al. Resolution of the colocation problem in satellite quantum tests of the universality of free fall. Physical Review D. 2020 Dec 18;102(12):124043. doi: 10.1103/PhysRevD.102.124043, 10.15488/10647

Schwartz PK, Giulini D. Classical perspectives on the Newton-Wigner position observable. International Journal of Geometric Methods in Modern Physics. 2020 Sept 17;17(12):2050176. doi: 10.1142/S0219887820501765

Siemß J-N, Fitzek F, Abend S, Rasel EM, Gaaloul N, Hammerer K. Analytic theory for Bragg atom interferometry based on the adiabatic theorem. Physical Review A. 2020 Sept 10;102(3):033709. doi: 10.1103/PhysRevA.102.033709

All publications of the Collaborative Research Centre

Overview