The scope and limitations of the alkylation of [closo-B-12(OH)(12)](2-) using a series of fourteen alkyl and aralkyl halides and two p-toluenesulfonic acid esters in the presence of N,N-diisopropylethylamine have been investigated. The dodecaalkoxy-closo-dodecaborate products, [closo-B-12(OR)(12)](2-), and their hypercloso two-electron oxidation products have been explored. The species [closo-B-12(OR)(12)](2-) containing 26 cage-bonding electrons may undergo two reversible, sequential, one-electron oxidation processes, producing a 25-electron radical anion and a 24-electron neutral species. Several oxidizing reagents were investigated for the chemical oxidation of [closo-B-12(OR)(12)](2-) and [hypercloso-B-12(OR)(12)](-) to [hypercloso-B-12(OR)(12)]. Both FeCl(3)(.)6H(2)O and K3Fe(CN)(6) in 90/5/5 ethanol/acetonitrile/H2O were found to be the reagents of choice. The reverse reaction leading from the neutral species to the radical anion and subsequently to the dianion was achieved using sodium borohydride in ethanol. A variety of alkoxyl derivatives have been synthesized by heating the reactants for extended periods of time in acetonitrile at the reflux temperature. The use of elevated reaction temperatures attained by employing moderate argon pressure (autoclave) over the reaction mixture led to drastic reductions in reaction times and increased efficiency. X-ray diffraction studies of substituted dodecabenzyl ether derivatives proved that 2(2-) has approximate I-h symmetry while hypercloso-2, -3, -9, -11, -12, and -13 have approximate D-3d point group symmetry due to Jahn-Teller distortion from I-h.