An aquifer thermal energy storage (ATES) system used for renewable and sustainable energy via storing heat and thermal energy in aquifers is a new technology. Such a system is operated by injecting/extracting the heat water into/from the aquifer and applied to heating and cooling the buildings. The exiting analytical models for ATES were developed based on quasi 3-D model and assumed that the heat transfer between the water and soil in the aquifer is instantaneous. We therefore propose a model to describe the temperature distribution due to heated water injection in the ATES system with considering the thermal exchange between fluid phase and solid phase. The model is composed of an aquifer which is bounded by two rocks on the top and at the bottom with different thermal properties. The solution of the model is derived by the methods of Laplace transform and Weber transform. An analytical solution is also derived for small conductivity value of the rocks. The results of sensitivity analysis indicate that the parameters of injection rate and thickness are the most sensitive parameters in the model. The model is compared with quasi 3-D model which is based on the assumption of thin aquifer thickness. The present solution can be used to investigate the influence of the parameters on the spatiotemporal temperature distribution and predict the thermal front distribution in the ATES system.