Topological insulators represent a novel state of matter with surface charge carriers having a massless Dirac dispersion and locked helical spin polarization. Many exciting experiments have been proposed by theory, yet their execution has been hampered by the extrinsic conductivity associated with the unavoidable presence of defects in Bi 2 Te 3 and Bi 2 Se 3 bulk single crystals, as well as impurities on their surfaces. Here we present the preparation of Bi 2 Te 3 thin films that are insulating in the bulk and the fourpoint probe measurement of the conductivity of the Dirac states on surfaces that are intrinsically clean. The total amount of charge carriers in the experiment is of the order of 10 12 cm −2 only, and mobilities up to 4,600 cm 2 /Vs have been observed. These values are achieved by carrying out the preparation, structural characterization, angle-resolved and X-ray photoemission analysis, and temperature-dependent four-point probe conductivity measurement all in situ under ultra-high-vacuum conditions. This experimental approach opens the way to prepare devices that can exploit the intrinsic topological properties of the Dirac surface states.topological insulator | molecular beam epitaxy | thin films | in situ four-point conductance | Dirac electrons T he observation of a quantum spin Hall effect due to edge states in 2D HgTe/CdTe quantum wells (1-3) has opened the field of topological states in matter without external magnetic fields applied. In 3D materials, the existence of metallic surface states with massless Dirac dispersion, locked helical spin polarization, and a simultaneous bulk insulating behavior is the hallmark of a topological insulator state (TI) (4-7). For Bi 2 Te 3 and Bi 2 Se 3 (8-10), their presence and topological protection were inferred from angle-resolved photoelectron spectroscopy (ARPES) experiments (8, 9), Shubnikov-deHaas (SdH) oscillations, and weak antilocalization in magnetotransport (11), as well as quasiparticle interference with scanning tunneling microscopy (STM) (12, 13).The Bi 2 Te 3 and Bi 2 Se 3 TI materials, however, have a severe problem that has thus far hindered four-probe conductivity measurements involving the Dirac surface states (SSs) (10,14,15): the presence of vacancies and anti-site defects in the bulk seems unavoidable, with the result that the bulk conductivity will overwhelm the contribution of the surface states (16). A remedy often used thus far has been the application of counter doping (e.g., with Ca, Sn, or Pb) (9, 10, 17-19) or gating (20-22) of exfoliated samples. Another promising way to solve the problem is to use thin films (23, 24) so that the surface to bulk ratio of the conduction is increased. By varying the growth parameters, one can change the film from p-to n-type (25, 26), suggesting that it should be possible to make the films consistently insulating. Another important aspect is that the conductivity studies reported thus far (27-29) have their samples exposed to air for mounting of the contacts before the four-probe conductivity...
