Quantum-Stabilized States in Magnetic Dipolar Quantum Gases

Ultracold Bose gases of highly magnetic atoms exhibit unique interaction properties that lead to striking many-body behaviors, both at and beyond the mean field. A decade ago, a universal stabilization mechanism driven by quantum fluctuations was discovered in these gases. This mechanism prevents the systems from collapsing and instead allows exotic states of matter to arise, including ultradilute quantum droplets, crystallized quantum states, and especially supersolids. After introducing key features of dipolar quantum Bose gases—including their interactions, ground states, and excitations in a mean-field framework, as well as the onset of quantum-fluctuation stabilization—we review the progress made in understanding the emergence and intriguing properties of these quantum stabilized states. Both theory and experiments are discussed.