Abstract The central United States frequently exhibits warm and dry biases in simulations of summertime conditions, a persistent feature that remains unresolved. While previous studies linked these biases to misrepresented surface energy exchanges, the role of belowground processes remains poorly understood. Here, we demonstrate that inadequate representation of root water uptake in land surface models contributes to this bias. Using both offline Noah‐MP and coupled WRF‐Noah‐MP simulations with static and dynamic root water uptake schemes, we show that the inclusion of dynamic root processes reduces 2‐m air temperature biases and enhances precipitation, primarily by increasing the rain rate of convective systems. Offline and coupled simulations further reveal that the cooling effects and precipitation increases are amplified through positive land‐atmosphere feedback, active only in the coupled model. These findings highlight an important role of root in modulating land‐atmosphere interactions and underscore the need to refine root‐zone processes to improve regional atmospheric simulations.