This paper examines the interactions between ice-albedo, lapse-rate and cloud-top feedbacks with the aid of GCM climate experiments published by Wetherald and Manabe (1975). First we establish that the long-wave modification effect (the so-called “greenhouse effect”) of clouds depends largely on the temperature difference Tsc between surface and cloud tops. If Tsc changes with a change in the surface temperature Ts, then the longwave modification effect of clouds would change which would result in a modification of the initial change in Ts. This feedback between the longwave modification effect of clouds and Ts, is referred to as the cloud top feedback in this paper. The sign of this feedback is considered positive (negative) when it amplifies (decreases) an initial change in Ts and it is shown that the sign is determined by the sign of dTsc/dTs. In the GCM climate experiments of Wetherald and Manabe (1975), dTsc/dTs < 0 at low latitudes and dTsc/dTs > 0 at high latitudes; consequently, cloud top... Abstract This paper examines the interactions between ice-albedo, lapse-rate and cloud-top feedbacks with the aid of GCM climate experiments published by Wetherald and Manabe (1975). First we establish that the long-wave modification effect (the so-called “greenhouse effect”) of clouds depends largely on the temperature difference Tsc between surface and cloud tops. If Tsc changes with a change in the surface temperature Ts, then the longwave modification effect of clouds would change which would result in a modification of the initial change in Ts. This feedback between the longwave modification effect of clouds and Ts, is referred to as the cloud top feedback in this paper. The sign of this feedback is considered positive (negative) when it amplifies (decreases) an initial change in Ts and it is shown that the sign is determined by the sign of dTsc/dTs. In the GCM climate experiments of Wetherald and Manabe (1975), dTsc/dTs < 0 at low latitudes and dTsc/dTs > 0 at high latitudes; consequently, cloud top...