Modulated-beam mass spectrometry and thermally-stimulated desorption measurements were used to show that Sb 4 is dissociatively chemisorbed on clean Si(100) at all temperatures investigated, from 100 to 1025°C. For Si substrate temperatures T s less than 600°C, desorption was only observed from precursor states corresponding to Sb 4 molecules adsorbed on top of a dissociatively chemisorbed Sb layer. The Sb 4 sticking probability s was nearly unity and independent of θ Sb for θ Sb ≲ 0.7 monolayers (ML) but decreased rapidly with increasing θ Sb above 0.7 ML to reach s = 0 at a saturation coverage of θ Sb = 1.0 ML (referenced to the surface site density of unreconstructed Si(100), 6.8 × 10 14 cm −2). Above 600°C, the desorbing Sb 4 flux decreased rapidly as the saturation coverage decreased and an increasing fraction of the impinging Sb 4 flux was desorbed from dissociatively chemisorbed states as Sb monomers. Sb 1 was the only desorbing species detected at T s ≳ 800°C. The activation energy for Sb 1 desorption was 2.40 ± 0.1 eV for θ Sb ≲ 0.5 ML and 2.33 ± 0.1 eV for θ Sb ≳ 0.5 ML as determined by thermally stimulated desorption, surface lifetime, and saturation coverage measurements. A simple model for Sb 4/Si(100) interactions involving a mobile Sb 4 precursor state and repulsive lateral interactions between chemisorbed Sb adatoms was used to calculate desorption rate kinetics and found to provide excellent agreement with the measured data.