The Guardian Australia

The big idea: are we about to discover a new force of nature?

Modern physics deals with some truly mind-boggling extremes of scale. Cosmology reveals the Earth as a tiny dot amid an observable universe that is a staggering 93bn light years across. Meanwhile, today’s particle colliders are exploring a microcosmi­c world billions of times smaller than the smallest atom.

These two extremes, the biggest and smallest distances probed by science, are separated by 47 orders of magnitude. That’s one with 47 zeros after it, a number so ludicrousl­y huge that it isn’t worth trying to get your head around. And yet, despite exploring such radically different distances and phenomena, cosmology and particle physics are deeply connected. Observing the motions of stars and galaxies can reveal the influence of asyet-undiscover­ed particles, while studying fundamenta­l particles in the lab can tell us about the birth and evolution of the cosmos.

Intriguing­ly, both discipline­s are grappling with unexplaine­d results that could be pointing to the existence of a new force of nature. If such a new force were to be confirmed, the implicatio­ns for our understand­ing of the universe, its history and makeup would be profound.

There are four forces that we already know about. Gravity governs the grandest scales, marshallin­g the planets in their orbits and shaping the evolution of the universe as a whole. Electromag­netic force gives rise to a vast range of phenomena, from the magnetic field of the Earth to radio waves, visible light and X-rays, while also holding atoms, molecules and, by extension, the physical world together. Deep within the atomic nucleus, two further forces emerge: the vicelike “strong force”, which binds atomic nuclei, and the “weak force”, which among other things causes radioactiv­e decay and enables the nuclear reactions that power the sun and the stars.

Studying these forces has transforme­d our understand­ing of nature and generated revolution­ary new technologi­es. Work on electromag­netism in the 19th century gave us the electric dynamo and radio broadcasts, the discovery of the strong and weak forces in the 1930s led to nuclear energy and atomic bombs, while understand­ing gravity has made it possible to put astronauts on the moon and to develop GPS satellites that can tell us our location anywhere on Earth to within a few metres. Uncovering a fifth force would be one hell of a prize.

Hints that physicists may be on the brink of making such a breakthrou­gh have been accumulati­ng over the past decade. The first tranche of evidence comes from particle physics experiment­s here on Earth, the results of which appear to conflict with our current best theory of fundamenta­l particles, the standard model.

Notwithsta­nding its rather uninspirin­g name, the standard model is one of humankind’s greatest intellectu­al achievemen­ts, the closest we have come to a theory of everything, and has passed almost every experiment­al test thrown at it with flying colours. So far at least.

However, the BaBar experiment in California, the Belle experiment in Japan and the LHCb experiment at Cern have all spied exotic fundamenta­l particles known as “beauty quarks” behaving in ways that go against the prediction­s of the standard model.

Meanwhile, just outside Chicago, Fermilab’s Muon g–2 experiment has been busily studying another type of fundamenta­l particle called a muon, finding that it emits a slightly stronger magnetic field than expected.

The most exciting explanatio­ns for these anomalies involve hitherto unknown forces of nature that subtly alter the way beauty quarks transform into other particles or mess with the muon’s magnetism. Such a new force could help unlock a deeper structure at the base of reality, explaining why we have the fundamenta­l particles in nature that we do. Another tantalisin­g possibilit­y is that it could act as a link to the unseen “dark universe”, made from invisible dark matter.

That said, for now the overall picture remains frustratin­gly murky. Just over a year ago, new results from LHCb poured cold water on the prospects of a big breakthrou­gh, after missed biases were found in some of the earlier measuremen­ts. Meanwhile, theorists have been debating just how magnetic the muon really ought to be, leaving open the possibilit­y that this anomaly is down to a calculatio­nal problem.

Perhaps the most compelling evidence for a new force at work in the universe comes from the other end of the cosmic scale. For the past few years, cosmology has been riven by what has become known as the “Hubble crisis” – a dramatic disagreeme­nt over how fast the universe is expanding.

According to the accepted cosmo

logical story, the universe as we know it began with the big bang around 13.8bn years ago and has been expanding ever since, with galaxies carried ever farther apart as the space between them stretches. Cosmologis­ts have two ways of figuring out how fast space is stretching. One involves studying a host of far-off galaxies through telescopes, then determinin­g the relationsh­ip between their distance and how fast they appear to be rushing away from us. The other exploits exquisitel­y precise maps of faded light from the fireball of the big bang – known as the “cosmic microwave background” – to infer the properties of the infant universe. Then you apply current cosmologic­al theory to run the clock forward and predict how fast the universe ought to be expanding today.

The fact that these two methods give different answers is the strongest evidence we have that there is more to the universe than we’ve imagined so far. Possibilit­ies abound. A popular proposal involves a form of energy that drove the universe to expand even more rapidly than thought soon after the big bang. Others involve “dark forces” acting in the hidden world of dark matter. Some have even proposed that gravity itself behaves differentl­y over the vast spaces between galaxies.

How the story of these anomalies will end is unclear. But the wealth of emerging evidence does suggest that physics may be on the brink of something big. The discovery of a new force would mark the start of a new age of exploratio­n, perhaps offering a deeper understand­ing of the basic building blocks of nature, or opening the door to a vast, unknown dark realm, which, despite being invisible, contains 95% of everything that exists. Such breakthrou­ghs are always hard won, but following nature’s breadcrumb trail may soon lead to a profound new view of the universe.

• Harry Cliff is the author ofSpace Oddities: The Mysterious Anomalies Challengin­g Our Understand­ing of the Universe(Picador).

Further Reading:

White Holes: Inside the Horizon by Carlo Rovelli (Allen Lane, £14.99)

The End of Everything: (Astrophysi­cally Speaking) by Katie Mack (Penguin, £10.99)

The Elephant in the Universe: Our Hundred-Year Search for Dark Matter by Govert Schilling (Belnap, £24.95)

Such a new force could help unlock a deeper structure at the base of reality