Scientists use purified liquid xenon to detect dark matter

A mile underground in an abandoned gold mine in South Dakota is a gigantic cylinder containing 10 tons of purified liquid xenon that is being closely watched by more than 250 scientists around the world. This xenon tank is at the heart of the LUX-ZEPLIN (LZ) experiment, which aims to detect dark matter – the mysterious invisible substance that makes up 85% of the matter in the universe.

“Humans have been searching for dark matter for over 30 years, and no one has yet made a convincing discovery,” said Dan Akerib, professor of particle physics and astrophysics at the SLAC National Accelerator Laboratory of the Department of Energy (DOE). But with the help of scientists, engineers, and researchers around the world, Akerib and his colleagues turned the LZ experiment into one of the world’s most sensitive particle detectors.

To reach this point, SLAC researchers built on their expertise working with liquid noble gases — the liquid forms of noble gases such as xenon — including advancing the technologies for cleaning liquid noble gases themselves and systems for detecting rare interactions with dark ones Matter within these liquids. And, Akerib said, what the researchers learned will aid not only the search for dark matter, but other experiments looking for rare particle physics processes.

“These are truly profound mysteries of nature, and this confluence of understanding the very large and the very small at the same time is very exciting,” said Akerib. “It is possible that we could learn something completely new about nature.”

Searching for dark matter deep underground

A current leading candidate for dark matter are weakly interacting massive particles, or WIMPs. However, as the acronym suggests, WIMPs hardly interact with ordinary matter, making them very difficult to detect, although in theory many of them are constantly passing us by.

To meet this challenge, the LZ experiment first went deep underground at the former Homestake gold mine that is now the Sanford Underground Research Facility (SURF) in Lead, South Dakota. There, the experiment is well protected from the constant bombardment of cosmic rays on Earth’s surface – a source of background noise that could make it difficult to detect hard-to-find dark matter.

Even then, finding dark matter requires a sensitive detector. For this reason, scientists are looking for noble gases, which are also known to be reluctant to react with anything. This means there are very few possibilities of what might happen when a dark matter particle, or WIMP, interacts with an atom of a noble gas, and therefore less chance of scientists missing an already elusive interaction.

But what noble- As it turns out,”Xenon is a particularly good precious metal for detecting dark matter,” said Akerib. Dark matter interacts most strongly with nuclei, and the interaction gets even stronger with the atomic mass of the atom, Akerib explained. For example, xenon atoms are a little over three times heavier than argon atoms, but are expected to have more than ten times stronger interactions with dark matter.

Another advantage: “Once you remove other contaminants from the liquid xenon it will be very quiet on its own‘ said Akerib. In other words, the natural radioactive decay of xenon is unlikely to stand in the way of detecting the interactions between WIMPs and xenon atoms.

Just the xenon, please

The trick, Akerib said, is to get pure xenon without all of the noble gas’s benefits being in dispute. However, purified noble gases are not readily available – the fact that they hardly interact with anything also means that they are generally quite difficult to separate from one another. And, “Unfortunately, you can’t buy an off-the-shelf purifier that cleans inert gases‘ said Akrib.

Akerib and his colleagues at SLAC therefore had to find a way to purify all the liquid xenon they needed for the detector.

The main impurity in xenon is krypton, the second lightest noble gas and a radioactive isotope that could mask the interactions it is actually looking for. To prevent krypton from becoming the particle detector’s kryptonite, Akerib and his colleagues spent several years perfecting a xenon purification technique using what is known as gas-carbon chromatography. The basic idea is to separate ingredients in a mixture based on their chemical properties while carrying the mixture through some sort of medium. In gas charcoal chromatography, helium is used as the carrier gas for the mixture and activated charcoal as the separation medium.

“You can think of the helium as a steady breeze through the charcoal‘ Akerib explained. “Each xenon and krypton atom spends some time sticking to the charcoal and some time not sticking to it. When the atoms are in a dissolved state, the helium breeze levitates them down the column.” Noble gas atoms are less sticky the smaller they are, which means that krypton is slightly less sticky than the xenon, so it gets swept away by the non-sticky helium “breeze,” thus separating the xenon from krypton. Researchers could then capture and discard the krypton and then retrieve the xenon, Akerib said.We did that for about 200 bottles of xenon gas – it was quite a big campaign.”

The LZ experiment isn’t the first experiment SLAC has been involved in looking for new physics with xenon. The Enriched Xenon Observatory Experiment (EXO-200), which ran from 2011 to 2018, isolated a specific xenon isotope to look for a process called neutrinoless double beta decay. The experiment’s results suggest the process is unimaginably rare, but a new proposed search called Next EXO (nEXO) will continue the search using a detector similar to LZ’s.

A different kind of power grid

No matter what noble liquid fills the detector, a sophisticated detection system is crucial if scientists ever hope to find anything like dark matter. Above and below the tower of liquid xenon for the LZ experiment are large high-voltage grids that create electric fields in the detector. When a dark matter particle collides with a xenon atom and knocks off some electrons, some electrons are released from the atom and separately produce a flash of light that can be detected by photodetectors, Ryan Linehan, a recent SLAC PhD graduate, explained to the LZ group participated in the development of the high-voltage grid.

Electric fields passing through the detector then propel the free electrons up into a thin layer of gas at the top of the cylinder, where they produce a second light signal. “We can use this second signal along with the original signal to learn a lot of information about position, energy, particle type and more,” said Linehan.

But these are no ordinary electrical grids — they carry tens of thousands of volts, so high that microscopic dust or dirt particles on the wire grid can trigger spontaneous reactions that rip electrons out of the wire itself, Linehan said. “And those electrons can create signals that look just like the electrons that came from the xenon,‘, masking the signals they are trying to detect.

The researchers found two main ways to minimize the chance of getting false signals from the grids, Linehan said. First, the team used a chemical process called passivation to remove iron from the surface of the grid wires, leaving a chromium-rich surface that reduces the wire’s tendency to emit electrons. Second, immediately before installation, the researchers sprayed the grids thoroughly – and very gently – with deionized water to remove dust particles. “These processes together helped us get the nets into a state where we could actually get clear data,” he said.

The LZ team published their first results online in early July, having pushed the search for dark matter further than ever.

Linehan and Akerib said they are impressed with what LZ’s global collaboration has achieved. “Together we learn something fundamental about the universe and the nature of matter,” said Akerib. “And we’re just getting started.”

The LZ effort at SLAC is led by Akerib along with Maria Elena Monzani, a senior scientist at SLAC and LZ associate operations manager for computers and software, and Thomas Shutt, founding spokesperson for the LZ collaboration.

The South Dakota Science and Technology Authority, which manages SURF under a collaborative agreement with the US Department of Energy, secured 80% of the xenon in LZ. Funding came from the Office of the Governor of South Dakota, the South Dakota Community Foundation, the South Dakota State University Foundation, and the University of South Dakota Foundation.

LZ is supported by the US Department of Energy, Office of Science and the National Energy Research Scientific Computing Center, a user facility of the DOE Office of Science. LZ is also supported by the US National Science Foundation, the UK Science & Technology Facilities Council, the Portuguese Foundation for Science and Technology and the Institute for Basic Science, Korea. Over 35 universities and advanced research institutions supported LZ. The LZ Collaboration recognizes the support of the Sanford Underground Research Facility.

Source: https://www6.slac.stanford.edu/