“In string theory,” writes physicist Michu Kaku, “all particles are vibrations on a tiny rubber band; physics is the harmonies on the string; chemistry is the melodies we play on vibrating strings; the universe is a symphony of strings, and the “Mind of God” is cosmic music resonating in 11 dimensional hyperspace.”
In stark contrast, “Not Even Wrong” is how string theory –commonly referred to as a “theory of everything” –has been famously described by theoretical mathematician Peter Woit at Columbia University. One of the biggest ideas in physics, string theory has offered the possibility that all known forces, particles, and interactions can be connected in one framework –an idea that has up until now been challenged because it was testable, and hence, not falsifiable.
“Until recently I had no idea just how much X-ray astronomers bring to the table when it comes to string theory, but we could play a major role,” said Christopher Reynolds of the University of Cambridge in the United Kingdom, who led the search for an “axion” –as-yet-undetected particles should have extraordinarily low masses that could explain the mystery of dark matter, which accounts for the vast majority of matter in the universe. “If these particles are eventually detected it would change physics forever.”
Despite having many different versions of string theory circulating throughout the physics community for decades, there have been very few experimental tests. Astronomers using NASA’s Chandra X-ray Observatory, however, have now made a significant step forward in this area.
By searching through galaxy clusters, the largest structures in the universe held together by gravity, researchers were able to hunt for a specific particle that many models of string theory predict should exist. While the resulting non-detection does not rule out string theory altogether, it does deliver a blow to certain models within that family of ideas.
These as-yet-undetected particles should have extraordinarily low masses. Scientists do not know the precise mass range, but many theories feature axion masses ranging from about a millionth of the mass of an electron down to zero mass.
One unusual property of these ultra-low-mass particles would be that they might sometimes convert into photons (that is, packets of light) as they pass through magnetic fields. The opposite may also hold true: photons may also be converted into axions under certain conditions. How often this switch occurs depends on how easily they make this conversion, in other words, on their “convertibility.”
Some scientists have proposed the existence of a broader class of ultra-low-mass particles with similar properties to axions. Axions would have a single convertibility value at each mass, but “axion-like particles” would have a range of convertibility at the same mass.
“While it may sound like a long shot to look for tiny particles like axions in gigantic structures like galaxy clusters, they are actually great places to look,” said co-author David Marsh of Stockholm University in Sweden. “Galaxy clusters contain magnetic fields over giant distances, and they also often contain bright X-ray sources. Together these properties enhance the chances that conversion of axion-like particles would be detectable.”
To look for signs of conversion by axion-like particles, the team of astronomers examined over five days of Chandra observations of X-rays from material falling towards the supermassive black hole in the center of the Perseus galaxy cluster. They studied the Chandra spectrum, or the amount of X-ray emission observed at different energies, of this source. The long observation and the bright X-ray source gave a spectrum with enough sensitivity to have shown distortions that scientists expected if axion-like particles were present.
The lack of detection of such distortions allowed the researchers to rule out the presence of most types of axion-like particles in the mass range their observations were sensitive to, below about a millionth of a billionth of an electron’s mass.
“Our research doesn’t rule out the existence of these particles, but it definitely doesn’t help their case,” said co-author Helen Russell of the University of Nottingham in the UK. “These constraints dig into the range of properties suggested by string theory, and may help string theorists weed their theories.”
The latest result was about three to four times more sensitive than the previous best search for axion-like particles, which came from Chandra observations of the supermassive black hole in M87. This Perseus study is also about a hundred times more powerful than current measurements that can be performed in laboratories here on Earth for the range of masses that they have considered.
Clearly, one possible interpretation of this work is that axion-like particles do not exist. Another explanation is that the particles have even lower convertibility values than this observation’s detection limit, and lower than some particle physicists have expected. They also could have higher masses than probed with the Chandra data.
Source: Christopher S. Reynolds et al. Astrophysical Limits on Very Light Axion-like Particles from Chandra Grating Spectroscopy of NGC 1275, The Astrophysical Journal (2020). DOI: 10.3847/1538-4357/ab6a0c , On Arxiv: https://arxiv.org/abs/1907.05475]
Image Credit: NASA/CXC/Univ. of Cambridge/C. Reynolds et al.