Antiproton is the antiparticle of the proton. The lifetime of antiproton is almost infinite in the vacuum, but it is typically short in media since any collision with a proton will cause both particles to be annihilated in a burst of energy. The stopping, capture and annihilation of antiprotons in liquids and gases has been much studied experimentally, and found that, although most stopped antiprotons annihilate promptly (〖10〗^(-11) s), about 3% of all antiprotons (P ̅) annihilated with a 3 μs overall lifetime after being brought to rest in helium, if the stopping medium is solid, liquid or gaseous helium. This extremely long lifetime is explained by the idea of the capture of antiproton to form an antiprotonic helium atom (P ̅He^+). It is difficult, however, to obtain the capture cross section both theoretically and experimentally. From the theoretical point of view, the full quantal and nonperturbative solution of this problem is still out of the reach of the current high-power supercomputers, and reliable calculation has been achieved only in the cases of the collision of antiproton with the simple atoms, H, He, and Li. In this thesis, we propose a simple model to calculate the capture cross section of antiproton by atoms. According to Fermi and Teller, capture process can be explained by so called the adiabatic ionization mechanism, but the results of their model do not agree with the reliable results. We examine the possible faults in the model, that are the nonadiabatic effects and the assumption of classical straight line trajectory. We examined those two effects to propose a new model. In low energy (about lower than 0.1 a.u.), the formation cross section is proportional to 1/√E. In higher energy (about higher than 0.1 a.u.), the formation cross section is a linear function of 1/E. We found that our cross section agrees well with that obtained by reliable theories.