Synthetic overcrowded alkene-based molecular motors achieve 360° unidirectional rotary motion of one motor half (rotator) relative to the other (stator) through sequential photochemical and thermal isomerization steps. In order to facilitate and expand the use of these motors for various applications, it is important to investigate ways to increase the rates and efficiencies of the reactions governing the rotary motion. Here, we use computational methods to explore whether the thermal isomerization performance of some of the fastest available motors of this type can be further improved by reducing the sizes of the motor halves. Presenting three new redesigned motors that combine an indanylidene rotator with a cyclohexadiene, pyran or thiopyran stator, we first use multiconfigurational quantum chemical methods to verify that the photoisomerizations of these motors sustain unidirectional rotary motion. Then, by performing density functional calculations, we identify both stepwise and concerted mechanisms for the thermal isomerizations of the motors and show that the rate-determining free-energy barriers of these processes are up to 25 kJ mol -1 smaller than those of the original motors.Furthermore, the thermal isomerizations of the redesigned motors proceed in fewer steps.Altogether, the results suggest that the redesigned motors are useful templates for improving the thermal isomerization performance of existing overcrowded alkene-based motors.3