New Experiment To “Trap” Dark Matter Could Unravel Mysteries of the Universe

New Experiment To “Trap” Dark Matter Could Unravel Mysteries of the Universe

New Experiment To “Trap” Dark Matter Could Unravel Mysteries of the Universe

Scientists have devised a 3D-printed vacuum system to detect dark matter and explore dark energy, using ultra-cold lithium atoms to identify domain walls and potentially explain the universe’s accelerating expansion.



Scientists have developed a novel 3D-printed vacuum system designed to ‘trap’ dark matter, aiming to detect domain walls. This advancement represents a significant step forward in deciphering the mysteries of the universe.

Scientists from the University of Nottingham’s School of Physics have created a 3D-printed vacuum system that they will use in a new experiment to reduce the density of gas, then and add in ultra-cold lithium atoms to try to detect dark walls. The research has been published in the scientific journal Physical Review D.

Professor Clare Burrage from the School of Physics is one of the lead authors on the study and explains: “Ordinary matter that the world is made from is only a tiny fraction of the contents of the universe, around 5%, the rest is either dark matter or dark energy – we can see their effects on how the universe behaves but we don’t know what they are. One way people try to measure dark matter is to introduce a particle called a scalar field.

“Dark matter is the missing mass in galaxies, dark energy can explain the acceleration of the expansion of the universe. The scalar fields that we are looking for could be either dark matter, or dark energy. By introducing the ultra-cold atoms and examining the effects it produces we may be able to explain why the expansion of the universe is accelerating and whether this has any effects on Earth.”

The researchers based the construction of the 3D vessels on the theory that light scalar fields, with double well potentials and direct matter couplings, undergo density-driven phase transitions, leading to the formation of domain walls.

Methodology and Theory

Professor Burrage continues: “As density is lowered defects form – this is similar to when water freezes into ice, water molecules are random and when they freeze you get a crystal structure with molecules lined up at random, with some lined up one way and some another and this creates fault lines. Something similar happens in scalar fields as the density gets lower. You can’t see these fault lines by eye but if particles pass across them it might change their trajectory These defects are dark walls and can prove the theory of scalar fields – either that these fields exist or don’t.”

To detect these defects or dark walls the team has created a specially designed vacuum that they will use in a new experiment that will mimic moving from a dense environment to a less dense environment. Using the new set-up they will cool lithium atoms with laser photons to -273 which is close to absolute zero, at this temperature they take on quantum properties which makes analysis more precise and predictable.

Lucia Hackermueller, Associate Professor in the School of Physics has led the design of the laboratory experiment, she explains, “The 3D printed vessels we are using as the vacuum chamber have been constructed using theoretical calculations of Dark Walls, this has created what we believed to be the ideal shape, structure, and texture to trap the dark matter. To successfully demonstrate that dark walls have been trapped, we will let a cold atom cloud pass through those walls. The cloud is then deflected. To cool those atoms we fire laser photons at the atoms, which reduces the energy in the atom – this is like slowing down an elephant using snowballs!”

The system took the team three years to build and they expect to have results within a year.

Dr. Hackermueller adds: “Whether we prove dark walls exist or not it will be an important step forward in our understanding of dark energy and dark matter, and an excellent example of how a well-controlled lab experiment can be designed to directly measure effects that are relevant for the Universe and otherwise cannot be observed.”

Source: SciTechDaily

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