Nontechnical Description: Laser beams carrying orbital angular momentum are of great interest in both classical and quantum optics. Among these beams, Laguerre-Gaussian modes are very unique for their intensity profiles making them of particular interest in particle manipulation, optical communications, detection, atom trapping and quantum applications. The current generation methods of these beams have many limitations. This collaborative research aims at the design, development and application of a novel high power, tunable, orbital angular momentum laser source at hard-to-reach wavelengths. It combines a novel vertical external cavity surface emitting laser design and intra-cavity generation of high order orbital angular momentum beams. The proposed laser source will be very efficient, compact and low cost, opening doors to new applications. The lasers will then be used to conduct novel experiments in the generation and study of ultra-cold atoms, atom trapping and quantum turbulence. The broader impact of the research focuses on the education and training of graduate and undergraduate students in the areas of lasers, photonics and quantum physics. The research will seek to broaden participation of women and underrepresented minorities through internship and summer REU programs. Technical Description: Lasers generating orbital angular momentum beams including Laguerre-Gaussian beams are of great interest in various fields of science and engineering. These beams have numerous applications including particle manipulation, underwater and free-space optical communications, imaging and detection. Watt-level, high-order Laguerre-Gaussian beams in the visible band are particularly desirable in quantum optics and atom trapping. Experiments using Watt-level high-order Laguerre-Gaussian beams are proposed as traps for ultra-cold and Bose-condensed atoms and for experiments in quantum turbulence. The current orbital angular momentum sources have limitations in power, tunability, compactness or wavelength of operation, thereby constraining their broad deployment. The goal of the research is to develop a novel high-power, tunable laser source with targeted Laguerre-Gaussian modes at hard-to-reach wavelengths. The approach is based on intracavity mode conversion of Hermite-Gaussian and Laguerre-Gaussian modes in a two-color Vertical External Cavity Surface Emitting Laser and efficient nonlinear frequency conversion for the generation of higher-order Laguerre-Gaussian modes in the visible and mid-IR wavelengths. The research merges concepts of semiconductor laser engineering, nonlinear mode conversion, atomic molecular and optical physics. The intellectual merits of this high-risk high-reward research includes significant technical advancement in areas of semiconductor quantum well design and growth, intracavity laser mode mixing and manipulation, nonlinear optical materials, laser cavity design and applications in atom trapping, cooling and quantum turbulence research and applications. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.