The abstractive adsorption of an HCl molecule on a single dangling bond has been investigated by scanning tunneling microscopy (STM). Each single dangling bond is an isolated reaction site and is produced on hydrogen-passivated Si(100) surfaces by controlling the sample temperature and annealing time. From the STM images, we conclude that a HCl molecule can undergo a selective abstraction reaction with a Si dangling bond and that the reaction prefers the adsorption of the H atom over the Cl atom. The ratio of H-abstraction to Cl-abstraction is 3:1. Experimental evidence also indicates that the adsorption process involves a precursor state, or an adsorption complex. Upon adsorption of a phonon, the adsorption complex transforms to a chemisorbed adsorption of one atom and let free the complementary atom on the surface. If H is first abstracted, the complementary Cl atom can either replace an nearby H atom with ~35% probability or is rejected back to vacuum. This research reveals a direct experimental visualization of the abstractive chemisorptions.