Neutrinos are known as "ghost particles", because they are known to travel through solid objects with ease.
But a new study demonstrates that some of these sub-atomic particles are stopped in their tracks when they encounter our planet.
Neutrinos interact so weakly with matter than a single one can pass through a light-year (10 trillion km) of lead without hitting an atom.
The results come from the IceCube experiment, located in Antarctica.
It's an important measurement that's consistent with the Standard Model – the theory that describes the behaviour of fundamental forces and particles (such as neutrinos).
The neutrinos seen by the IceCube detector had very high energies. The energy of the neutrinos was a critical factor, because the higher the energy, the more likely they are to interact with matter and therefore be absorbed by the Earth.
IceCube is an array of 5,160 basketball-sized optical sensors called Digital Optical Modules (DOMs) that are encased within a cubic kilometre of very clear Antarctic ice near the South Pole.
IceCube's sensors do not directly observe the neutrinos, but instead measure flashes of blue light, known as Cherenkov radiation. These flashes are emitted by other particles such as muons, which are produced when neutrinos interact with the ice.
By measuring the light patterns from these interactions in or near the detector array, IceCube can estimate the neutrinos directions and energies.
The team found there were fewer energetic neutrinos making it all the way through the Earth to the IceCube detector than those that reached it from less obstructed paths – such as near-horizontal trajectories.
"Understanding how neutrinos interact is key to the operation of IceCube," said Francis Halzen, chief scientist for the IceCube and a professor of physics at the University of Wisconsin-Madison.
The results will allow team members to calculate something called the "cross-section" for these high-energy neutrinos with a high degree of accuracy. The cross section describes the probability that neutrinos of a given energy will interact with matter.
"We were of course hoping for some new physics to appear, but we unfortunately find that the Standard Model, as usual, withstands the test," said Prof Halzen.
The finding, published in Nature journal, provide the first cross-section measurements for a neutrino energy range that is up to 1,000 times higher than previous measurements at particle accelerators.
Most of the neutrinos selected for this study were more than a million times more energetic than those produced by more familiar sources, like the sun or nuclear power plants.
The analysis could also be of interest to geophysicists who would like to use neutrinos to image the Earth's interior, though this will require more data than was used in the current study.
Most of the neutrinos used in the analysis are generated in the Earth's atmosphere, through a process initiated by cosmic rays. But the study also includes a small number of "astrophysical neutrinos", which are produced by unknown sources beyond the Earth's atmosphere.
Another neutrino experiment, known as the Deep Underground Neutrino Experiment (Dune) is currently in development, and is due to switch on in the 2020s.
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