Project B02: Optical clocks testing fundamental physics

In this project we will investigate and implement methods to circumvent limitations in accuracy and stability using both an operational strontium lattice clock and a more flexible setup with ultracold calcium. With these optical clocks we will investigate fundamental questions of the temporal and spatial stability of e.g. the fine structure constant α and its potential couplings to dark matter. Specifically tailored motional quantum states shall be used to identify and minimize motion-related clock uncertainties. To address limitations from the linewidth of the interrogation laser, which is in fact limiting the stability of most ion and neutral atom clocks, we will in parallel investigate an active optical frequency source based on super-fluorescence on a narrow clock transition.

Introduction

Supported by their ever-improving precision, optical clocks have been employed over the past two decades to perform some of the most stringent tests of fundamental physical principles. Following this idea, the goal of this project is to employ high-performance optical clocks to search for violations of the predictions of the standard model of particle physics, commonly referred to as new-physics effects.

Results

Towards this goal, we have tested local position invariance (LPI) by repeatedly comparing the output of atomic clocks realizing different clock transition frequencies. The different sensitivities of the involved atomic states to fundamental constants, such as the fine-structure constant α or the proton-to-electron mass ratio μ, allows us to either identify the corresponding violating constant or to constrain its instability. Within DQ-mat, we have recently established the most stringent bounds on temporal variations and a potential coupling to gravity for α and μ. These investigations profited in particular from the high sensitivity of the clock transitions of the Yb+ ion to variations of α.

To perform reliable tests and to further push the limits of our searches for new-physics effects, we have improved the understanding of frequency shifts resulting from blackbody radiation and the lattice laser light for the Sr clock, which aided to resolve a discrepancy between experimentally and theoretically determined atomic parameters and lead to a better understanding of the atomic structure of Sr. We have started to operate a Yb+ ion clock setup in which 88Sr+ can be employed as ancillary ion, e.g., to measure the perturbing thermal radiation. The latter investigation has also helped to resolve a serious tension in recent measurements of the 88Sr+ clock transition frequency.

Both systems, the 87Sr lattice clock and the 171Yb+ ion clock, have also been employed in long-term frequency comparisons and to search for another new-physics curiosity: dark matter.

Publications

Showing results 21 - 27 out of 27

Herbers S, Dörscher S, Benkler E, Lisdat C. Phase noise of frequency doublers in optical clock lasers. Optics express. 2019;27(16):23262-23273. doi: 10.1364/OE.27.023262
Schwarz R, Dörscher S, Al-Masoudi A, Vogt S, Li Y, Lisdat C. A compact and robust cooling laser system for an optical strontium lattice clock. Review of scientific instruments. 2019 Feb 25;90(2):023109. doi: 10.1063/1.5063552
Dörscher S, Schwarz R, Al-Masoudi A, Falke S, Sterr U, Lisdat C. Lattice-induced photon scattering in an optical lattice clock. Physical Review A. 2018 Jun 25;97(6):063419. doi: 10.1103/PhysRevA.97.063419
Mehlstäubler TE, Grosche G, Lisdat C, Schmidt PO, Denker H. Atomic clocks for geodesy. Reports on Progress in Physics. 2018 Jun;81(6):064401. Epub 2018 Apr 18. doi: 10.48550/arXiv.1803.01585, 10.1088/1361-6633/aab409
Origlia S, Pramod MS, Schiller S, Singh Y, Bongs K, Schwarz R et al. Towards an optical clock for space: Compact, high-performance optical lattice clock based on bosonic atoms. Physical Review A. 2018 Nov 29;98(5):053443. doi: 10.1103/PhysRevA.98.053443
Delva P, Lodewyck J, Bilicki S, Bookjans E, Vallet G, Le Targat R et al. Test of Special Relativity Using a Fiber Network of Optical Clocks. Physical review letters. 2017 Jun 2;118(22):221102. doi: 10.1103/PhysRevLett.118.221102
Pachomow E, Dahlke VP, Tiemann E, Riehle F, Sterr U. Ground-state properties of Ca2 from narrow-line two-color photoassociation. Physical Review A. 2017 Apr 25;95(4):043422. doi: 10.48550/arXiv.1702.00710, 10.1103/PhysRevA.95.043422
All publications of the Collaborative Research Centre

Project leader

Dr. Nils Huntemann
Address
Bundesallee 100
38116 Braunschweig
Dr. Nils Huntemann
Address
Bundesallee 100
38116 Braunschweig
PD Dr. Christian Lisdat
Address
Bundesallee 100
38116 Braunschweig
PD Dr. Christian Lisdat
Address
Bundesallee 100
38116 Braunschweig

Staff

Dr. Sören Dörscher
Address
Bundesallee 100
D-38116 Braunschweig
Dr. Sören Dörscher
Address
Bundesallee 100
D-38116 Braunschweig