The pure rotational spectrum of the TiCl + ion in its X 3Φ r ground state has been measured in the frequency range 323–424 GHz, using a combination of direct absorption and velocity modulation techniques. The ion was created in an AC discharge of TiCl 4 and argon. Ten, eleven, and nine rotational transitions were recorded for the 48Ti 35Cl +, 48Ti 37Cl +, and 46Ti 35Cl + isotopomers, respectively; fine structure splittings were resolved in every transition. The rotational fine structure pattern was irregular with the Ω = 4 component lying in between the Ω = 2 and 3 lines. This result is consistent with the presence of a nearby 3Δ r state, which perturbs the Ω = 2 and 3 sub-levels, shifting their energies relative to the Ω = 4 component. The data for each isotopomer were analyzed in a global fit, and rotational and fine structure parameters were determined. The value of the spin–spin constant was comparable to that of the spin–orbit parameter, indicating a large second-order spin–orbit contribution to this interaction. The bond length established for TiCl +, r 0 = 2.18879 (7) Å, is significantly shorter than that of TiCl, which has r 0 = 2.26749 (4) Å. The shorter bond length likely results from a Ti 2+Cl − structure in the ion relative to the neutral, which is thought to be represented by a Ti +Cl − configuration. The higher charge on the titanium atom shortens the bond.