Hurricanes, cyclones and typhoons are weather phenomena wh ich induce damages for billions of dollars yearly and pose significant risks to communities world wide. The need fo r better meteoro logical prediction methods is therefore more important than ever, part icularly with the emergence of "ext reme weather" conditions. Super-co mputer methods are key tools for storm-analysis and prediction, and are used frequently to predict the direction of large low-pressure systems such as Hurricanes heading yearly for A merican continent, cyclones in Australia and typhoons in Japan. The dynamical behaviour of these vast low-pressure systems is not fully understood, and the directions of these weather phenomena are often resolved too late for evacuation procedures to be fully effect ive. In order to increase the understanding of low-pressure systems and meteorological pred iction, a hybrid v iew on the behaviour of hurricane systems based on a blend of quantum mechanics and classical physics is introduced in this brief note. The aims are to introduce a mathemat ical contemp lation to bring to the attention of meteorolog ical modelers a putative behaviour of the storm systems analogue with electron orbital density functional theory, and to use electron orbital theory to imp rove the resolution and predictive power of storm modeling. The mathematical discussion presented herein shows that a low-pressure system can be subdivided into N-layers, with physical and energetical qualities. Such qualit ies comprise angular mo menta and individual energ ies of high-density regions which can be used to predict the direction of the low-p ressure system. The results and mathemat ical d iscussion presented herein serve as a foundation for Hurricane theory improvement.