In this work, the double-loop-like characteristics of K0.5Na0.5NbO3 + x mol% K5.4Cu1.3Ta10O9 ceramic and its relationships with the transition temperature, aging, and switching have been investigated. Our results reveal that the phase transition temperature is an important parameter determining the aging requirement for the ceramics to exhibit the double-loop-like characteristics. For a ceramic with a high transition temperature, e. g. the ceramic with x = 0.75 (tetragonal-orthorhombic phase temperature similar to 206 degrees C), the vacancies can migrate during the crystal transformation and settle in a distribution with the same symmetry as the crystal after the transformation. As a result, defect dipoles along the polarization direction are formed and provide restoring forces to reverse the switched polarizations, and thus producing a double polarization hysteresis (P-E) loop. On the other hand, aging is required for a ceramic with a low transition temperature, e. g. aging at 80 degrees C for 30 days is required for the ceramic with x = 1.5 (transition temperature similar to 175 degrees C). Our results also reveal that the defect dipoles can be switched under a slow-switching electric field (<1 Hz) or at high temperatures (100 degrees C), thus leading to an opening of the double P-E loop.