15 meters deep, in a basement of Zhejiang University, China has installed a machine the size of a building capable of doing something hitherto impossible for a laboratory: reproducing in hours what nature takes centuries to build. Or destroy. Its name is CHIEF1900 and it can rotate at extreme speeds or generate a gravitational force a thousand times greater than that of the Earth, which for example serves to simulate an earthquake and its effects.
Context. For a geology professional, analyzing a portion of land means deciphering the history of the planet in layers: each stratum is a record of millions of years. The problem is that nature writes it slowly. Reproducing this phenomenon in a laboratory has been one of the great challenges of experimental physics for decades. Hypergravity centrifuges are the tool that comes closest to that goal.
These machines are capable of rotating at extreme speeds, generating forces hundreds or thousands of times greater than Earth’s gravity. When rotating, the arms generate outward pressure on everything inside the machine. The faster it is, the greater the force. The result is a controlled hypergravity field that compresses time and distance.
What China has achieved. Zhejiang University (Hangzhou) has completed the construction of the most powerful hypergravity centrifuge in the world: it will have a total capacity of 1,900g·ton, that is, it can apply 1,900G to a one-tonne sample. The CHIEF1900 will surpass the record that China had established a few months before (September 2025), with the CHIEF1300.
This power makes it possible to replicate land deformations on a kilometer scale, simulate the transport of pollutants over millennia, evaluate the resistance of a dam to an earthquake or generate thousands of new material samples. As a reference, with the CHIEF1300 they have already been able to reproduce the pressure of the seabed at a depth of 2,000 meters to evaluate the extraction of methane hydrates, or simulate how a 20-meter tsunami affects the seabed.
Why is it important. To natural disasters such as earthquakes or tsunamis we have to add other consequences of human activity such as the breaking of dams, contamination of aquifers or deformation of the soil under high-speed infrastructure or the melting of glaciers. Predicting how these phenomena will behave requires information that is not available since obtaining them in real conditions is either impossible or would take decades.
Dan Wilson, deputy director of the Center for Geotechnical Modeling at the University of California, explains for Popular Mechanics that this will be one of the four largest dynamic centrifuges in the world, that is, it can simulate active earthquakes using hypergravity. Chen Yunmin, chief scientist of the project, sums it up accurately: It aims to create experimental environments spanning from milliseconds to tens of thousands of years, and from the atomic to the kilometer scale.
How they have done it. To build a machine with such performance, Zhejiang University brought together a multidisciplinary team that brings together personnel specialized in civil engineering, thermodynamics or automation. Among the technical challenges they faced was heat: at high rotation speeds, the centrifuge reaches such temperatures that the stability of the system is compromised.
The solution was a cooling system that combines vacuum, forced ventilation and glacial coolant. The fact that the installation is buried has an explanation: it minimizes external vibrations, which could contaminate the experiments to be carried out.
Pending subjects. Although the installation dates back to the end of 2025 and Popular Mechanics mentions which is already operational, no scientific results from CHIEF1900 are yet available.
At an operational level, these scale models reproduce the loads well but not always all the size effects: certain material behaviors do not scale linearly under hypergravity, which requires caution in the interpretation of results. To minimize this risk, it is common for the data obtained to be compared with that of other similar facilities around the world.
In Xataka | China has taken a silent step in the new space race: the world’s first system to measure time on the Moon
In Xataka | It’s not a telescope, it’s a time machine: what James Webb reveals to us about “deep space”
Cover | Peter Herrmann and Arthur Wang Xinhua
GIPHY App Key not set. Please check settings