Nematic liquid crystals are a unique type of liquid crystals that exhibit the flow of a liquid while having a rod-like structure. By having only long-range positional order, nematic liquid crystals can be extremely sensitive to external stimuli such as an electric field. Building off this sensitivity, ferroelectric nematic liquid crystals can be synthesized. Ferronematic liquid crystals show spontaneous polar order that makes them highly sensitive to external electric fields. This can be particularly useful in creating sensors, liquid crystal displays, and opto-electronic devices. To enhance ferronematic liquid crystals, we focused on adding a new aspect of phototunability. Phototunability of the molecules involves changing the isomer through light exposure, which can change the function of the liquid crystal. Synthesis was done via various standard protocols, purification was done using Flash Chromotography and separations, and analysis was done using Mass Spectroscopy and Nuclear Magnetic Resonance (NMR). To successfully synthesize these materials, they must have high dipole moments, low aspect ratios, and modulation of charge density. By focusing on these attributes and phototunability, I was able to synthesize molecules, modifying the aspect ratio and dipole moment. Through characterization of Polarized Optical Microscopy (POM), Differential Scanning Calorimetry (DSC), P-E Hysteresis, and Second Generation Harmonic (SHG), two of the molecules were ferroelectric. Thus, the project was successful in the synthesis of pure ferronematic liquid crystals. These molecules can be further analyzed to observe their phototunable capabilities and be used in different electronic devices.