The effects of the aspect ratio on unsteady solutions through the curved duct flow are studied numerically by a spectral based computational procedure with a temperature gradient between the vertical sidewalk for the Grashof number 100≤Gr ≤2 000.The outer wall of the duct is heated while the inner wall is cooled and the top and bottom walls are adiabatic.In this paper,unsteady solutions are calculated by the time history analysis of the Nusselt number for the Dean numbers Dn = 100 and Dn = 500and the aspect ratios 1 ≤ 7 ≤ 3.Water is taken as a working fluid(Pr = 7.0).It is found that at Dn = 100,there appears a steady-state solution for small or large Gr.For moderate Gr,however,the steady-state solution turns into the periodic solution if 7 is increased.For Dn = 500,on the other hand,it is analyzed that the steady-state solution turns into the chaotic solution for small and large Gr for any 7 lying in the range.For moderate Gr at Dn = 500,however,the steady-state flow turns into the chaotic flow through the periodic oscillating flow if the aspect ratio is increased. The effects of the aspect ratio on unsteady solutions through the curved duct flow are studied numerically by a spectral based computational procedure with a temperature gradient between the vertical sidewalk for the Grash of number 100≤Gr≤2 000.The outer wall of the duct is heated while the inner wall is cooled and the top and bottom walls are adiabatic. In this paper, unsteady solutions are calculated by the time history analysis of the Nusselt number for the Dean numbers Dn = 100 and Dn = 500 and the aspect ratios 1 ≤ 7 ≤ It is found that at Dn = 100, there is a steady-state solution for small or large Gr. For moderate Gr, however, the steady-state solution turns into the periodic solution if 7 is increased. For Dn = 500, on the other hand, it is analyzed that the steady-state solution turns into the chaotic solution for small and large Gr for any 7 lying in the range. For moderate Gr at Dn = 500, however, the steady-state flow turns int o the chaotic flow through the periodic oscillating flow if the aspect ratio is increased.