The efficient and selective organozirconium(IV)-mediated, intermolecular hydrothiolation of terminal alkynes by aliphatic, benzylic, and aromatic thiols using CGCZrMe(2) (CGC = Me(2)SiCp'' NCMe(3), Cp'' = C(5)Me(4)), Cp*ZrBn(3) (Cp* = C(5)Me(5), Bn = benzyl), Cp*ZrCl(2)NMe(2), Cp*(2)ZrMe(2), and Zr(NMe(2))(4) precatalysts is reported. These transformations are shown to be highly Markovnikov-selective, with selectivities up to 99%, and typically in greater than 90% yields. The reaction has been demonstrated on the preparative scale with 72% isolated yield and 99% Markovnikov selectivity. A mixture of anti-Markovnikov products is occasionally observed as a result of a known, non-organometallic, radical mechanism, which can be suppressed by addition of a radical inhibitor. Kinetic investigations show that the CGCZrMe(2)-mediated reaction between 1-pentanethiol and 1-hexyne is first-order in catalyst concentration, first-order in alkyne concentration, and also first-order in thiol at lower concentrations but transitions to zero-order at concentrations > 0.3 M. Deuterium labeling of the alkyne yields k(H)/k(D) = 1.3(0.1), along with evidence of thiol-mediated protonolytic detachment of product from the Zr center. Activation parameters for CGCZrMe(2)-mediated 1-pentanethiol hydrothiolation of 1-hexyne measured over the temperature range of 50-80 degrees C are DeltaH(double dagger) = +18.1(1.2) kcal/mol and DeltaS(double dagger) = -20.9(2.5) e.u. for [alkyne] and [thiol] at 0.2 M. These and other findings are consistent with turnover-limiting alkyne insertion into the Zr-SR bond, followed by a thiol-induced Zr-C protonolysis. Observed zirconium-thiolate dimers in the reaction medium suggest instances of dimeric catalyst resting states and possible aggregated, hydrothiolation-active species.