In physics, there are two great
pillars of thought that don't quite fit together. The Standard Model of
particle physics describes all known fundamental particles and three forces:
electromagnetism, the strong nuclear force, and the weak nuclear force. Meanwhile,
Einstein's general relativity describes gravity and the fabric of spacetime.
However, these frameworks are
fundamentally incompatible in many ways, says Jonathan Heckman, a theoretical physicist at the University of Pennsylvania. The Standard Model treats forces
as dynamic fields of particles, while general relativity treats gravity as the
smooth geometry of spacetime, so gravity "doesn't fit into physics's
Standard Model," he explains.
In a recent paper in Physical Review Research,
Heckman, Rebecca Hicks, a Ph.D. student at Penn's School of Arts &
Sciences, and their collaborators turn that critique on its head. Instead of
asking what string theory predicts, the authors ask what it definitively cannot
create. Their answer points to a single exotic particle that could show up at
the Large Hadron Collider (LHC). If that particle appears, the entire
string-theory edifice would be, in Heckman's words, "in enormous
trouble."
String theory: The good, the bad, the energy-hungry
For decades, physicists have sought
a unified
theory that can
reconcile quantum mechanics, and by extension, the behavior of subatomic particles, with gravity—which
is described as a dynamic force in general relativity but is not fully
understood within quantum contexts, Heckman says.
A good contender for marrying
gravity and quantum phenomena is string theory, which posits that all
particles, including a hypothetical one representing gravity, are tiny
vibrating strings and which promises a single framework encompassing all forces
and matter.
"But one of the drawbacks of
string theory is that it operates in high-dimensional math and a vast
'landscape' of possible universes, making it fiendishly difficult to test
experimentally," Heckman says, pointing to how string theory necessitates
more than the familiar four dimensions— x, y, z, and time—to be mathematically
consistent.
"Most versions of string
theory require a total of 10 or 11 spacetime dimensions, with the extra
dimensions being sort of 'curled up' or folding in on one another to extremely
small scales," Hicks says.
To make matters even trickier,
string theory's distinctive behaviors only clearly reveal themselves at
enormous energies, "those far beyond what we typically encounter or even
generate in current colliders," Heckman says.
Hicks likens it to zooming in on a
distant object: At everyday, lower energies, strings look like regular
point-like particles, just as a faraway rope might appear to be a single line.
"But when you crank the energy
way up, you start seeing the interactions as they truly are—strings vibrating
and colliding," she explains. "At lower energies, the details get
lost, and we just see the familiar particles again. It's like how from far
away, you can't make out the individual fibers in the rope. You just see a
single, smooth line."
That's why physicists hunting for signatures of string theory must push their colliders—like the LHC—to ever-higher energies, hoping to catch glimpses of fundamental strings rather than just their lower-energy disguises as ordinary particles.
Why serve string theory a particle it likely won't be able to return?
Testing a theory often means
searching for predictions that confirm its validity. But a more powerful test,
Heckman says, is finding exactly where a theory fails. If scientists discover
that something a theory forbids actually exists, the theory is fundamentally
incomplete or flawed.
Because string theory's predictions
are vast and varied, the researchers instead asked if there's a simple particle
scenario that string theory just can't accommodate.
They zeroed in on how string theory
deals with particle "families," groups of related particles bound
together by the rules of the weak nuclear force, responsible for radioactive
decay. Typically, particle families are small packages, like the electron and
its neutrino sibling, that form a tidy two-member package called a doublet.
String theory handles these modest particle families fairly well, without
issue.
However, Heckman and Hicks
identified a family that is conspicuously absent from any known string-based
calculation: a five-member particle package, or a 5-plet. Heckman likens this
to trying to order a Whopper meal from McDonald's: "No matter how creatively
you search the menu, it never materializes."
"We scoured every toolbox we
have, and this five-member package just never shows up," Heckman says.
But what exactly is this elusive 5-plet?
Hicks explains it as an expanded
version of the doublet: "The 5-plet is its supersized cousin, packing five
related particles together."
Physicists encapsulate this
particle family in a concise mathematical formula known as the Lagrangian,
essentially the particle-physics cookbook. The particle itself is called a
Majorana fermion, meaning it acts as its own antiparticle, akin to a coin that
has heads on both sides.
Identifying such a particle would
directly contradict what current string theory models predict is possible,
making the detection of this specific particle family at the LHC a high-stakes
test, one that could potentially snap string theory.
Why a 5-plet hasn't been spotted and the vanishing-track clue
Hicks cites two major hurdles for
spotting these 5-plet structures: "production and subtlety."
In a collider, energy can literally
turn into mass; Einstein's E = mc² says that enough kinetic oomph (E) can be
converted into the heft (m) of brand-new particles, so the heavier the quarry
the rarer the creation event.
"The LHC has to slam protons
together hard enough to conjure these hefty particles out of pure energy,"
Hicks explains, citing Einstein's E = mc², which directly links energy (E) to
mass (m). "As the masses of these particles climb toward a trillion
electron volts, the chance of creating them drops dramatically."
Even if produced, detection is
challenging. The charged particles in the 5-plet decay very quickly into nearly
invisible products.
"The heavier states decay into
a soft pion and an invisible neutral particle, zero (X0)," Hicks says.
"The pion is so low-energy it's basically invisible, and X0 passes
straight through. The result is a track that vanishes mid-detector, like
footprints in snow suddenly stopping."
Those signature tracks get picked up by LHC's ATLAS (short for A Toroidal LHC ApparatuS) and CMS (Compact Muon Solenoid), house-sized "digital cameras" wrapped around the collision center. They sit at opposite collision points and operate independently, giving the physics community two sets of eyes on every big discovery. Penn physicists like Hicks are part of the ATLAS Collaboration, helping perform the searches that look for quirky signals like disappearing tracks.
Why a 5-plet matters for dark matter
Hicks says finding the 5-plet isn't
only important for testing string theory, pointing to another exciting
possibility: "The neutral member of the 5-plet could explain dark matter, the mysterious mass shaping up most of our
universe's matter."
Dark matter constitutes roughly 85%
of all matter in the universe, yet scientists still don't know what exactly it
is.
"If the 5-plet weighs around
10 TeV—about 10,000 proton masses—it neatly fits theories about dark matter's
formation after the Big Bang," Hicks says. "Even lighter 5-plets
could still play a role as part of a broader dark matter landscape."
"If we detect a 5-plet, it's a
double win," says Hicks. "We'd have disproven key predictions of
string theory and simultaneously uncovered new clues about dark matter."
What the LHC has already ruled out
Using existing ATLAS data from
collider runs, the team searched specifically for 5-plet signals. "We
reinterpreted searches originally designed for 'charginos'—hypothetical charged
particles predicted by supersymmetry—and looked for 5-plet signatures,"
Hicks says of the team's search through the repurposed ATLAS disappearing-track
data. "We have found no evidence yet, which means any 5-plet particle must
weigh at least 650–700 GeV, five times heavier than the Higgs boson."
For context, Heckman says,
"this early result is already a strong statement; it means lighter 5-plets
don't exist. But heavier ones are still very much on the table."
Future searches with upgraded LHC
experiments promise even sharper tests. "We're not rooting for string
theory to fail," Hicks says. "We're stress-testing it, applying more
pressure to see if it holds up."
"If string theory survives, fantastic," Heckman says. "If it snaps, we'll learn something profound about nature."
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