The novel phenomenon of intrinsic spin Hall e ect (ISHE) is that a dissipationless transverse spin-polarized current being induced only by applying an external electric field in a spin-orbit coupling material. It is unlike the extrinsic SHE, which arises from being scattered by the spin-orbit coupling impurities. However, the interplay between disorder and ISHE is still unclear. To understand whether the presence of disorder reduces or has no effect on the intrinsic value is important in predicting experimental detections. On the other hand, since the lateral movement of electrons in spin Hall effect can be recognized as the orbital motion, ISHE always accompanies the orbital angular momentum (OAM) Hall effect. The OAM Hall conductivity is the same in magnitude, but opposite in sign with the spin Hall conductivity (SHC) in the Rashba model. The suppression of SHC in the disordered Rashba model has already been studied by several authors, but the disorder effect on the OAM Hall e ect has not yet been known. In this thesis, the effects of short-ranged and spin-independent disorder on spin Hall conductivity in the Rashba, Dresselhaus and wurtzite model and on OAM Hall conductivity in the Rashba model and the Dresselhaus model have been studied in the linear response regime. Two methods were employed, the vertex correction within the ladder approximation and by the momentum relaxation time approximation. The effective conserved spin current gives the insights into the spin torque contribution to the ISHC. We found that by momentum relaxation time approximation, the spin torque contribution was one order smaller than the conventional contribution in the disordered system. Moreover, the SHC calculated from the effective conserved spin Hall current changed sign from the intrinsic system to the disordered system, while the SHC calculated from the conventional spin Hall current did not change sign. Results from the two methods imply that the spin torque contribution to the SHC may be from the electrons in the Fermi sea, unlike the conventional contribution to the SHC, which was from the electrons at the Fermi level. The results of the vertex correction of OAM Hall conductivity had a divergent term in the d.c. limit. The divergent term was due to the gauge dependent property of the ill-defined position operator in momentum space. Nonetheless, the OAM Hall conductivities recovered e/8pi in the ballistic limit and vanished in the diordered limit when only the interband contribution was taken into account. How to solve this ambiguity is still under study.