Temperature is the major abiotic factor controlling the rate of morphogenesis in fish. The present work investigated hatching time and the transition from endogenous to exogenous feeding at five constant temperatures over the range 15-35 °C. Clarias gariepinus eggs can be successfully hatched in ambient water temperatures between 20 and 35 °C, although at 30 °C the hatching rate is significantly improved. At 15 °C embryos do not survive. The period of hatching is inversely related to temperature such that synchronous hatching is encouraged by high temperature within the specific temperature range. The extent to which development rate and metabolic rate in C. gariepinus are accelerated by temperature is not the same. The duration between first feeding, yolksac absorption and the point-of-no-retum is inversely related to temperature. The same threshold temperature, below which development is theoretically arrested, can be estimated for C. gariepinus from the linear relationship between development rate and temperature up to hatching, first feeding and yolksac absorption. This closely approximates the lower lethal temperature of 15 °C estimated directly from embryo survival. The effect of temperature can be usefully modelled in C. gariepinus using the linear relationship V = a + bt to estimate t0 (threshold temperature) and Deff0 (effective day-degrees) and the hyperbolic relationship τ = Deff0/(t – t0) to determine development time. From the present work, t0 is 14.5 °C and Deff0 is 13, 26.3 and 35.7 for hatching, first feeding and yolksac absorption respectively for C. gariepinus. Unlike day-degrees, effective day-degrees remain independent of temperature over the range 20-35 °C. An approximate guide to development time at different constant temperatures within this range is given.