Experiment Overview
Zhang Xiangqian's unified field theory is not just theoretical derivation — he has also conducted a series of experiments to verify the core prediction: changing electromagnetic fields can produce gravitational field effects.
Experimental Timeline
First Discovery
In an accelerating charge experiment, anomalous force effects were first observed — objects exhibited motion that could not be explained by conventional electromagnetic forces.
Rotation Experiment
Using a changing magnetic field, a suspended ball was observed to spontaneously rotate. The rotation direction was consistent with the magnetic field change direction, ruling out conventional electromagnetic explanations.
Mass Variation Experiment
In a strong changing electromagnetic field, a precision balance measured small but detectable changes in object mass.
Low-Voltage Breakthrough
Reduced the required voltage from thousands of volts to 80V/30A, dramatically lowering the replication threshold. This means ordinary physics labs can attempt it.
Core Experiments
Experiment 1: Accelerating Charges Generate Gravitational Fields
According to the unified field theory, accelerating charges produce changing electromagnetic fields, which in turn produce gravitational field effects. The experiment passes high-frequency alternating current through a conductor and places test objects nearby to observe anomalous forces.
Experimental results showed that test objects exhibited motion in a direction different from electromagnetic forces, consistent with theoretical predictions.
Experiment 2: Changing Magnetic Fields Generate Vortex Gravitational Fields
A small ball is suspended by a thin thread near the center of a changing magnetic field. When the field changes rapidly, the ball exhibits rotational motion around the field axis. This rotation cannot be explained by conventional electromagnetic induction (the ball is non-conductive), which Zhang believes is direct evidence of a vortex gravitational field.
Low-Voltage Setup (80V/30A)
Early experiments required high-voltage equipment with a high replication threshold. After optimization, Zhang found a setup using an 80V/30A low-voltage power supply that can still observe the effects, greatly reducing equipment requirements and safety risks for independent replication.
US Patent
In 2024, Zhang applied for a US patent (US12417870) for the related experimental setup, an important step in securing intellectual property protection for the experimental method.
Why Is Independent Replication Critical?
The cornerstone of science is reproducibility. No matter how remarkable an experimental result, it can only be accepted by the scientific community when independent laboratories, using independent equipment, with different experimenters, replicate the same results.
Zhang's experiments have so far only been conducted and reported by himself. We call on capable physics laboratories and researchers to perform independent replications. For detailed experimental procedures and equipment lists, see the Experimental Setup page.
Note: All experimental results above were reported by Zhang Xiangqian himself and have not been independently verified by third parties. This site faithfully presents the experimental information without judging the reliability of the results.