The influence of dephasing on the quantum spin Hall effect (QSHE) is studied. In the absence of dephasing, the longitudinal resistance in a QSHE system exhibits the quantum plateaus. We find that these quantum plateaus are robust against the normal dephasing but fragile with the spin dephasing. Thus, these quantum plateaus only survive in mesoscopic samples. Moreover, the longitudinal resistance increases linearly with the sample length but is insensitive to the sample width. These characters are in excellent agreement with the recent experimental results [science 318, 766 (2007)]. In addition, we define a new spin Hall resistance that also exhibits quantum plateaus. In particular, these plateaus are robust against any type of dephasing and therefore, survive in macroscopic samples and better reflect the topological nature of QSHE. Recently, the quantum spin Hall effect (QSHE), existed in a new quantum state of matter with a non-trivial topological property, has generated great interest.[1] QSHE occurs in the topological insulator with a bulk energy gap and two helical edge states crossing inside the gap. This energy-band structure guarantees that the carriers only flow along the boundary and that carriers with opposite spin-polarizations move in opposite directions on a given edge. The other key ingredient for QSHE is the presence of the spin-orbit interaction (SOI). When electrons move under an electric field, the SOI drives the electrons with opposite spins to deflect to the opposite transverse boundaries, and the special energy-band structure leads to the quantum spin Hall conductance.[1] The existence of QSHE was first proposed in a graphene film in which the SOI opens a bandgap around the Dirac-points and establishes the edge states. [2,3]. Soon afterwards, QSHE was predicted to exist in some other two-or threedimensional systems. [4,5,6,7] In particular, Bernevig et al. recently found that CdTe/HgTe/CdTe quantum well has an "inverted" type energy-band structure with proper well thicknesses [7] where QSHE naturally exists. Soon after this work, QSHE was successfully realized in an experiment [8,9] in which a quantized longitudinal resistance plateau was observed when the sample's electron density was varied in the absence of a magnetic field. [8] However, in the experiment of Ref.[8], the quantized longitudinal resistance plateaus could only emerge in mesoscopic samples. This character is very different from the regular quantum Hall effect (QHE). In QHE, the Hall resistance plateaus exist in macroscopic samples, robust against the impurity scattering as well as the inelastic (dephasing) scattering. This leads some to speculate that the inelastic scattering which induces phase relaxation, destroys the quantized plateaus in QSHE [1,7], however, there has been no theoretical or experimental investigation thus far.In this Letter, we study how QSHE is affected by de- In a realistic sample, there are in general a number of possible dephasing processes, but these can be classified into two categories. In the fir...
