The article, published on ESS Open Archive, delves into the intricate mechanisms of thermal modulation affecting nearshore groundwater flow and solute transport within tidally influenced coastal aquifers, particularly those bounded by mild-slope beaches. This research area is critical for understanding the hydrogeological processes in vulnerable coastal environments globally. Coastal aquifers are vital sources of freshwater, but their dynamics are significantly influenced by oceanic forces like tides and temperature fluctuations, which can drive the movement of both freshwater and dissolved substances (solutes), including pollutants and seawater. Credible sources corroborate the scientific legitimacy and importance of this field of study. Numerous research papers from platforms like ResearchGate, UQ eSpace, DSpace@MIT, and UDSpace discuss various aspects of groundwater flow, solute transport, and thermal and tidal influences in coastal aquifers. These studies collectively emphasize that tidal oscillations can induce complex groundwater circulation patterns, influencing the extent of seawater intrusion and the pathways of solute migration. Temperature variations, whether from atmospheric conditions or seawater, also play a significant role in affecting groundwater temperature profiles and heat transport, further complicating the system's dynamics. The ESS Open Archive itself is a recognized and credible platform for sharing early research outputs, including preprints, in Earth and Space Science, fostering open discovery and dissemination within the scientific community. The article's title is highly technical and accurately reflects a specific area of scientific inquiry, devoid of sensationalism or exaggeration. This type of foundational research is crucial for developing effective strategies for coastal zone management, water resource protection, and environmental policy, especially for coastal nations like India facing challenges from rising sea levels and increasing water demand. While the specific findings of *this* article would require direct access for detailed verification, the scientific context and concepts are well-established and rigorously studied.