This paper focuses on the foundational framework and experimental testability of quantum gravity, a long-standing frontier in modern physics. We systematically examine the core challenges in quantizing gravity, including the non-renormalizability of gravitons and the lack of direct experimental evidence at the Planck scale. The work reviews potential lab-based test schemes—such as gravity-induced entanglement (GIE), gravitational wave quantum signature detection, and sub-millimeter gravitational redshift measurements—while analyzing their viability as genuine tests of quantum gravity. We also discuss the connection between quantum gravity theories (e.g., string theory, loop quantum gravity) and observable phenomena, aiming to bridge the gap between theoretical frameworks and experimental verification. This research provides a structured perspective for identifying gravity’s quantum fingerprints through feasible low-energy experiments, offering guidance for future experimental designs in quantum gravity.
lei guan (Sat,) studied this question.