This thesis is about how Fe catalysts can be degraded using photocatalysis and how Fe catalysts can degrade small molecules in conjunction with light. The goal of this paper is to look further into more sustainable methods of organic chemistry. Many current organic chemistry practices involve the use of precious metals. Iron is a more sustainable catalyst because it is abundant and inexpensive which is important for preserving the earth and making the organic chemistry more accessible. Along the same lines, light is a renewable energy source and has demonstrated its ability to aid in reactions. Overall, the goal of this paper is to explore the more sustainable alternatives to harsh and toxic organic chemistry practices through the use of Iron and light.

Amidinates and guanidinates are promising supporting ligands in organometallic and coordination chemistry, highly valued for their accessibility, tunability, and comparability with other popular anionic N-chelating hard donor ligands like β-diketiminates. By far the most powerful way to access these ligands involves direct metal-nucleophile insertion into N,N’- substituted carbodiimides. However, the majority of reported examples require the use of commercially accessible carbodiimide peptide coupling reagents with simple alkyl substituents leading to low variation in potential substituents. Presented here is the design, synthesis, and isolation of a novel N,N’-bis[3-(diphenylphosphino)propyl]carbodiimide via an Aza-Wittig reaction between two previously described air stable substrates. At room temperature, 3-(diphenylphosphanyl-borane)-propylisocyanate was added to N-(3-(diphenylphospino)propyl)-triphenylphosphinimine, leading to product formation in minutes. One-pot phosphine-borane deprotection, followed by simple filtration of the crude mixture through a small, basic silica plug using pentane and diethyl ether granted the corresponding carbodiimide in high purity and yield (over 70%), confirmed by 1H, 13C, and 31P NMR spectroscopy. In addition to accessing different central carbon substituents, modification of phosphine substituents should be easily accessible through minor variations in the synthesis. With these precursors, anionic amidinates and guanidinates capable of κ4 -N,N,P,P-coordination may be accessed. The ability of the labile phosphine arms to associate and dissociate may facilitate catalysis. Thus, this carbodiimide provides a tunable, reliable one step precursor to novel substituted amidinates and guanidinates for homogeneous transition metal catalysis.

The trifluoromethyl group is an essential chemical motif in pharmaceutical and agrochemical industries. The trifluoromethyl group has similar steric bulk to a methyl group, but exhibits strongly electron withdrawing properties. As a result, a trifluoromethyl group can provide a molecule with enhanced lipophilicity, bioavailability, and metabolic stability, which makes it a commonly used tool to tune activity of agrochemicals and pharmaceutical candidates. There are many methods to generate a new trifluoromethyl moiety, but many of these methods rely on stoichiometric metal reagents or harsh reaction conditions. One strategy to install the trifluoromethyl group under benign conditions is with photoredox catalysis. In the field of photocatalysis, iron has emerged as an alternative for precious metals due to its low cost, earth-abundance, and environmentally benign nature. Methods of trifluoromethylation utilizing iron catalysis do exist, but they often rely on expensive CF3 precursors such as Togni’s Reagent and trifluoromethyl iodide. This thesis demonstrates a method using iron photocatalysis for decarboxylative trifluoromethylation of alkenes using trifluoroacetic acid. We have successfully enabled trifluoromethylation of select methoxy-substituted benzene derivatives as well as a number of alkenes, including those bearing sulfone and ketone groups.