This work focuses on the temperature-dependent carrier dynamics of InAs/GaAs quantum dots. We present an abnormal observation of low-temperature spike on carrier lifetimes caused by the change of decay curves from bi-exponential to mono-exponential decay. Theoretically, we then propose a three-level system containing a dark excitonic state and calculate it with rate equations; we find that at low temperature, the curves behave bi-exponentially due to the slow rate of the spin-flip relaxation of dark excitons; however at higher temperature, carriers are able to relax through an additional path with a much faster rate and the process becomes dominating, leading to the mono-exponential decay curves. The study suggests that to realize high-temperature operation spin storage taking the advantage of dark excitons in QDs, one must consider the fast relaxation through the extra mechanisms favored by thermal energy.