N-Heterocyclic Carbenes (NHCs) have been regarded as promising supporting ligands for their great bonding ability toward transition metal and main group element. To broaden chemistry of NHCs and NHC complexes, several electron-donating functional groups have been incorporated into the imidazole ring. Electron-withdrawing group, however, received considerable less attention. In an attempt to realize the N-borylated N-heterocyclic carbene, a series of N-borylated imidazolium salts have been prepared and characterized. Interestingly, the deprotonation of the N-boryl imidazolium salt initiated a 1,2-boryl shift from nitrogen atom to the C2 carbon of imidazole to yield the corresponding 2-boryl imidazole. In order to understand the migration process, we have carried out the crossover experiment, which confirmed the inter-molecular migration processes upon deprotonation. Also, radical trapping experiments revealed the presence of two unusual radical species, a Li+ coordinated NHC radical and a diarylboryl radical, originated from homolytic B-N bond breaking. Therefore, the 1,2-boryl migration of NHC can be explained. Upon generation of the putative N-boryl NHC, a B-N bond cleavage occurred to generate two stable radicals, which could escape the solvent cage and recombine randomly to accomplish the intermolecular migration process.