Cross-coupling reactions of non-activated alkyl halides are potentially useful chemical transformations. At the same time, however, they are challenging due to a series of unproductive side reactions. Recently, significant progress has been made to overcome these difficulties. With judicious choice of metal, ligands, and reaction conditions, the normally problematic β- H elimination can be suppressed. As a consequence, a number of examples of the successful coupling of non-activated alkyl halides have been demonstrated. The mechanistic understanding of such reactions is, in most cases, still primitive. In the majority of cases, the active catalysts are generated in situ and remain unidentified and unknown. This dissertation is devoted to mechanistic studies of alkyl-alkyl cross-coupling catalyzed by a well-defined nickel pincer complex [(MeNN2)Ni-Cl] (1; Nickamine). This complex showed excellent activity for the cross-coupling of unactivated alkyl halides. Moreover, several nickel alkyl complexes bearing β-hydrogen atoms have been isolated. These features offered a unique platform to carry out mechanistic studies to gain a better understanding of nickel-catalyzed crosscoupling reactions. Chapter one provides examples of palladium-, iron-, cobalt-, and nickel-catalyzed alkyl-alkyl cross-coupling reactions. In each case mechanistic details are discussed. At the end of the chapter cross-coupling reactions using Nickamine are presented. In chapter two the propensity of isolated nickel alkyl complexes to undergo -hydride elimination is explored. Isomerization and olefin exchange experiments show that -hydride elimination is kinetically viable but thermodynamically unfavorable in [(MeNN2)Ni-alkyl] complexes. The intermediacy of an [(MeNN2)Ni-H] (6) species was corroborated by trapping experiments. The alkyl complex [(MeNN2)Ni-propyl] catalyzes olefin isomerization reactions. In chapter three the aforementioned nickel(II) hydride complex 2 was synthesized by reaction of [(MeNN2)Ni-OMe] (10) with Ph2SiH2, and was characterized by NMR and IR spectroscopy, as well as X-ray crystallography. Complex 6 was unstable in solution, and decomposed via two reaction pathways. The first pathway was through intramolecular N-H reductive elimination to III give MeNN2H and Ni particles. The second pathway was intermolecular, giving H2, Ni particles, and a five-coordinate Ni(II) complex [(MeNN2)2Ni] (12) as the products. Compound 6 reacted with ethylene and acetone, forming [(MeNN2)Ni-Et] (2) and [(MeNN2)Ni-OiPr] (13), respectively. Complex 6 also reacted with alkyl halides, yielding nickel(II) halide complexes and alkanes. The reduction of alkyl halides was rendered catalytic, using 1 as catalyst, NaOiPr or NaOMe as base, and Ph2SiH2 or Me(EtO)2SiH as the hydride source. The catalysis appeared to operate via a radical mechanism. In chapter four a detailed mechanistic study of alkyl-alkyl Kumada coupling catalyzed by the preformed nickel(II) pincer complex 1 is reported. The coupling proceeds through a radical process, involving two nickel centers for the oxidative addition of alkyl halide. The catalysis is 2nd order in Grignard reagent, 1st order in catalyst, and 0th order in alkyl halide. A transient species, [(MeNN2)Ni-Alkyl2](Alkyl2-MgCl), is identified as the key intermediate responsible for the activation of alkyl halide, the formation of which is the turnover-determining step of the catalysis. Finally, a catalytic cycle for Nickamine-catalyzed cross-coupling reactions was established. This dissertation elaborates the properties of nickel-alkyl and nickel-hydride complexes of the Nickamine system. It elucidates many mechanistic features of the alkyl-alkyl Kumada coupling reactions catalyzed by Nickamine, and establishes, for the first time, a bimetallic oxidative addition mechanism for nickel-catalyzed coupling reactions. The work significantly enhances the current understanding of cross-coupling reactions of alkyl halides.