Optical anisotropy and nonlinearity in deep ultraviolet fluorooxoborates

Optical anisotropy and nonlinearity are two tantalizingly important and enticing properties of an optical crystal. Combining these two features will have a miraculous effect. The up conversion can extend solid state laser sources to the ultraviolet and deep ultraviolet (DUV) ranges through harmonic generation and for down conversion needed for quantum information technology, but only a few suitable materials are known as the medium because of the combination of properties that are required. These include suitable band gaps, moderate optical anisotropy for phase matching and strong nonlinear optical (NLO) response. Fluorooxoborates are a new ideal platform for this effect in DUV. Here we demonstrate that fluorooxoborate is the optimal framework for DUV NLO material and show that the significance of the incorporation of fluorine in borates. The NLO performance of fluorooxoborates is strongly improved in terms of local crystal structure and distribution of electronic states. Importantly, the role of fluorine is to control the structure, while maintaining high band gaps but does not directly provide large contributions to birefringence and the second harmonic generation as the conventional assumptions. This is a consequence of the microscopic electron distribution and the energy position of the fluorine states well below the valence band maxima. Based on our understandings, we constructed two artificial structure and they all behave as anticipated.