This thesis deals with the calculation of the reaction of singlet cyclic nitrenium ions and isoelectronic analogues (carbenes, borenide anions) with H2O and CH3OH by density functional theory at B3LYP/6-31+G* level. This structures were then reoptimized with BVWN/6-31+G* level for comparison with the B3LYP results. There are two major sections for the reactions we studied and they are rendered here. Section 1 We study the reaction of H2O with nitrenium ions, carbenes and borenide anions in gas phase. The result of the major products of the reactions are alcohol derivatives. It is apparent that all the reactions are thermodynamically exothermic. The main mechanisms of nitrenium ions and carbenes systems are O-H bond insertions, but those of borenide anions are abstraction reactions. Borenide anions will abstract the proton in water to form stable intermediates H-BmR and OH—, and then undergo toward forming alcohol derivatives. Section 2 The reactions of CH3OH with nitrenium ions, carbenes and borenide anions are studied in this section. According to our results, nitrenium ions may undergo C-H bond insertions toward forming alcohol derivatives, or undergo O-H bond insertions toward forming ether derivatives. The main mechanisms of carbenes system are C-H bond insertions. Similarly, carbenes may undergo C-H bond or O-H bond insertions, but the main mechanism is O-H bond insertion. In borenide anions system, there is no O-H bond insertion mechanism. In addition to C-H bond insertions, borenide anions can break the C-O bond in CH3OH. The B atom may act as a nucleophilic agent to attack the C atom in CH3OH，and then break the C-O bond . Or, the B atom may act as an electronphilic agent to accept the lone pair electrons on the O atom to form B-O bond and simultaneously break the C-O bond. However, in the reaction of borenide anions with methanol, C-H bond insertions are calculated to be the major process in the whole possible pathways.