While all eyes are on the LHC to discover new, interesting particles species, condensed matter physicists have been working hard in attempts to detect Majorana fermions and Magnetic Monopoles in solids. In today's talk at the American Physical Society’s March meeting in Boston, Massachusetts, Leo Kouwenhoven presented findings that Majorana fermions have been detected in an indium antimonide nanowire apparatus. Indium antimonide nanowires are connected to a circuit with a gold
contact at one end and a slice of superconductor at the other, and then
exposed to a moderately strong magnetic field. Measurements of the
electrical conductance of the nanowires showed a peak at zero voltage
that is consistent with the formation of a pair of Majorana particles,
one at either end of the region of the nanowire in contact with the
superconductor. As a sanity check, the group varied the orientation of
the magnetic field and checked that the peak came and went as would be
expected for Majorana fermions.
Although other groups have previously reported circumstantial evidence
for the appearance of Majorana fermions in solid materials, Jay Sau, a
physicist at Harvard University in Cambridge, Massachusetts, who
attended Kouwenhoven’s talk, says that this is a direct measurement. “I
think this is the most promising-looking experiment yet,” he says. “It
would be hard to argue that it’s not Majorana fermions.”
Multiple schemes have been proposed in which Majorana fermions act as
the 'bits' in quantum computers, although Sau cautions that it’s not yet
clear whether those created by Kouwenhoven will be long-lived enough to
be used in that way.
As the LHC's
Higgs hunt continues, it's worthwhile to reflect on the current state
of cutting-edge experimental particle physics, as a whole. Indeed the Higgs boson is
a prediction of the Standard Model of particle physics, but as former CERN theoretical physicist John Ellis admitted,
in the range 114-135 GeV the "present electroweak vacuum would be
unstable for such a light Higgs in the Standard Model" forcing one to
come up with new physics to stabilize it. By "new", this means physics
beyond the Standard Model, such as for example, supersymmetry. Yet,
let's pretend the Standard Model is nice and stable with a ~125 GeV
Higgs particle. Does it tell us about every type of matter in the
universe? Sadly, it doesn't. Ordinary matter accounts for only 4.6% of
the mass-energy content of the observable universe, while mysterious
dark matter makes up about 23%. The rest of the mass-energy content, about 72.4%, is in the form of dark energy. So cosmologically, the Standard Model doesn't seem so standard after all.
So what kind of model explains the physics of dark energy and dark matter (the 95.4% of the universe), along with the 4.6% nicely described by the Standard Model? Many theorists would agree such a model must come from a complete theory of quantum gravity. The leading contender for such a theory is M-theory, the theory underlying the 10-dimensional string theories and 11-dimensional supergravity. There also exist other theories, such as Loop Quantum Gravity, which essentially aims to "quantize" space via Wilson loop operators. Ultimately, the goal is unification of all forces and matter in the universe, using just a single theory. And this theory, in turn, should describe 100% of the universe.
Are we close to figuring out a complete theory of quantum gravity, hence a theory of all matter and forces? There are hints that we are, but as always, many hurdles are mathematical. Historically, Newton had to invent Calculus to describe motion properly. Einstein had to invoke the tools of Riemann's Differential Geometry to describe space-time curvature. And will it now be Connes' Noncommutative Geometry that will serve as the magic bullet for quantum gravity? There is evidence that it might, as the coordinates of branes in string/M-theory are naturally noncommutative. Erik Verlinde has even proposed a model for dark energy and dark matter, which as a matrix model, is an application of noncommutative geometry. From a historical perspective, the use of new geometrical mathematics has proven fruitful, so we may very well be on the verge of a new physics revolution.