Unveiling how each brain regions communicate is crucial for understanding how the brain processes emotion, timing, learning and memory. Neural oscillation within and across brain regions have been proposed to correlate to these cognitive processes. While performing distinct behavioral tasks, the entorhinal and hippocampal circuitries display prominent theta and gamma activities. Their precision of synchronization is served as a mechanism for the rhythmical changes in neuronal excitability and provides effective functional communication. One of the synchronized phenomenon known as theta phase to gamma amplitude cross-frequency coupling (CFC) is depicted gamma amplitudes often entrain in specific phases of the theta frequency. The theta-gamma oscillatory coupling is thought to be strengthened during learning and maintain in working memory. However, it is still unclear what the function role of neural oscillation in hippocampus and medial entorhinal cortex (MEC) in the behavioral performance. Differential-reinforcement-of-low-rate (DRL) schedules are used to evaluate the brain wave properties in modulating behavioral functions such as impulse inhibition, temporal perception and working memory processes. We hypothesized that communication between the hippocampal CA1 region and the MEC is critical for executing the DRL procedure because working memory refers to the instant system that holds and manipulates operational information over short periods of time. Our data show theta power in the CA1 one seconds prior to lever pressing may predict internal times. Also, the CFC in CA1 theta phases to MEC fast gamma amplitudes was low during impulsive behavior. Thus, these results suggest that subjects may not think carefully and the poor communication between the CA1 and MEC results in impulsivity. We speculate the working memory impairment in the hippocampal formation accounts for the poor performance on the DRL. In addition, because the endogenous cannabinoid system is predominant in the rat CA1-MEC network, several previous research has also suggested that the alternation in timing perception is through the failure of accumulation temporal information of possessing working memory in the hippocampal endocannabinoid system. To further understand the role of CFC in timing behavior, we hypothesized that the communication between the CA1 and MEC is essential for the transmission of temporal associated working memory. We use the DRL-10 tasks to examine the inter-response-time (IRT) distributions under the effects of cannabinoids, arachidonylcyclopropylamide (ACPA), because the task requires subjects performing at the optimal timing. Our results depict after activation CB1 receptors from MEC presynapses, the CFC in CA1 theta phases to MEC fast gamma amplitudes declines and is possibly influenced by interfering with the interneurons in CA1 circuitries. Then, this inefficient communication leads to impairment in temporal working memory during critical IRT and eventually led to the time overproduction, in which subjects generate longer time intervals than predetermined. In our study, we have found several cognitive impairments are associated with disturbances in CFC in the hippocampal entorhinal pathway in our results. A decrease in cross-frequency coupling leads to impulsivity. Additionally, under the effects of cannabinoids on CB1 receptors, the alternation in these oscillation activities result in time underestimation. To sum up, our data may help decipher the brain functions during DRL and benefit in understanding how the hippocampal entorhinal circuitries work on the temporal memory and impulsivity. overproduction, in which subjects generate longer time intervals than predetermined. In our study, we have found several cognitive impairments are associated with disturbances in CFC in the hippocampal entorhinal pathway in our results. A decrease in cross-frequency coupling leads to impulsivity. Additionally, under the effects of cannabinoids on CB1 receptors, the alternation in these oscillation activities result in time underestimation. To sum up, our data may help decipher the brain functions during DRL and benefit in understanding how the hippocampal entorhinal circuitries work on the temporal memory and impulsivity.