In recent years, an increasingly large variety of molecular species have been successfully
cooled to low energies, and innovative techniques continue to emerge to reach ever more …

Ultracold molecules confined in optical lattices or tweezer traps can be used to process
quantum information and simulate the behaviour of many-body quantum systems. Molecules …

Quantum sensing and metrology use coherent superposition states of quantum systems to
detect and measure physical effects of interest. Their sensitivity is typically limited by the …

After decades of improvements in cooling techniques of several atomic species and in
finding methods for the achievement of stable quantum mixtures, the field is now ready for …

Ultracold atoms, molecules and ions provide a unique playground to explore chemistry at
ultracold temperatures. In this Review, we discuss what makes these systems particularly …

Many experimental platforms for quantum science depend on state control via laser fields.
Frequently, however, the control fidelity is limited by optical phase noise. This is exacerbated …

We present a theoretical study of the excitations of the two-dimensional supersolid state of a
Bose-Einstein condensate with either dipole-dipole interactions or soft-core interactions …

Quantum systems with SU (N) symmetry are paradigmatic settings for quantum many-body
physics. They have been studied for the insights they provide into complex materials and …

Only bosonic molecular species have been directly laser cooled to date, primarily due to an
abundance of bosonic isotopes in nature and to their simpler hyperfine structure. Fermionic …

Quantum gases of doubly polar molecules represent appealing frameworks for a variety of
cross-disciplinary applications, encompassing quantum simulation and computation …