Bemisia tabaci (Gennadius) is an important agricultural pest that is polyphagous and widely distributed throughout tropical and subtropical areas of the world. Morphologically indistinguishable populations with different biological traits exist within B. tabaci. More than 30 biotypes of B. tabaci have been identified by multiple techniques that include specific phytotoxic reactions, isozymes, and DNA markers. Bemisia tabaci was proposed to be a species complex, with many biotypes and two described extant cryptic species, B. tabaci and B. argentifolii. In this study, molecular markers were used to study the molecular phylogeny of the B. tabaci complex. Phylogenetic analyses of mitochondrial cytochrome oxidase I (COI) gene sequences revealed two indigenous biotypes with overlapping distributions in East Asia: the Nauru and AN biotypes. The results also showed that the Nauru biotype is of Asian origin, and the AN biotype could be of Asian or Australian origin. In addition, phylogenetic and population genetic analyses indicated that biotypes B and Q occur in the Western North Pacific region due to multiple recent invasions. The invasive events were related to the ornamental plant trade from the Mediterranean region. Furthermore, synonymy of biotypes is also an important question which needs to be studied. All biotypes of B. tabaci were used to reconstruct a phylogenetic tree, and results indicated the existence of nine genetic groups: Asia-Australia, Asia, Italy, Mediterranean/North-Africa, Mediterranean/Asia Minor/Africa, Southeast Africa, New World, Sub-Saharan Africa, and Uganda. The distributions of genetic groups were related to the geographic region. The origin and divergence of B. tabaci were also discussed in this study. Hypotheses of originating in Africa and in South Asia are proposed and tested. Phylogenetic analyses revealed that samples from Africa formed the basal clade, which supports the out-of-Africa hypothesis. On the other hand, the hypothesis of a cryptic species complex of B. tabaci was also tested in this study. Whiteflies close to B. tabaci were also selected to reconstruct a phylogenetic tree and discuss the issue of a B. tabaci species complex. Phylogenetic analyses of COI and 16S ribosomal DNA revealed that B. tabaci is not a monophyly and support it being a species complex. Reproductive isolation and significantly different biological characters were also observed among genetic groups and provide information to suggest the existence of a B. tabaci species complex. Moreover, Asia and Asia-Australia genetic groups coexisting in Asia is also confusing. Hypotheses of sympatric divergence with radiating expansion and allopatric divergence with secondary contact were proposed. Microsatellite and mitochondrial markers were used to study the population structure and phylogeography of indigenous genetic groups of B. tabaci in Asia. Results revealed that the sympatric distribution of two indigenous genetic groups in Asia represents allopatric divergence with secondary contact. Furthermore, the Asia and Asia-Australia genetic groups both originated in Asia. However, there are still many interesting questions which need to be studied in B. tabaci in the future.