116 research outputs found
Four-gluon scattering at three loops, infrared structure and Regge limit
We compute the three-loop four-gluon scattering amplitude in maximally
supersymmetric Yang-Mills theory, including its full color dependence. Our
result is the first complete computation of a non-planar four-particle
scattering amplitude to three loops in four-dimensional gauge theory and
consequently provides highly non-trivial data for the study of non-planar
scattering amplitudes. We present the amplitude as a Laurent expansion in the
dimensional regulator to finite order, with coefficients composed of harmonic
poly-logarithms of uniform transcendental weight, and simple rational
prefactors. Our computation provides an independent check of a recent result
for three-loop corrections to the soft anomalous dimension matrix that predicts
the general infrared singularity structure of massless gauge theory scattering
amplitudes. Taking the Regge limit of our result, we determine the three-loop
gluon Regge trajectory. We also find agreement with very recent predictions for
sub-leading logarithms
Solvable Relativistic Hydrogenlike System in Supersymmetric Yang-Mills Theory
The classical Kepler problem, as well as its quantum mechanical version, the
Hydrogen atom, enjoy a well-known hidden symmetry, the conservation of the
Laplace-Runge-Lenz vector, which makes these problems superintegrable. Is there
a relativistic quantum field theory extension that preserves this symmetry? In
this Letter we show that the answer is positive: in the non-relativistic limit,
we identify the dual conformal symmetry of planar super
Yang-Mills with the well-known symmetries of the Hydrogen atom. We point out
that the dual conformal symmetry offers a novel way to compute the spectrum of
bound states of massive bosons in the theory. We perform nontrivial tests
of this setup at weak and strong coupling, and comment on the possible
extension to arbitrary values of the coupling.Comment: 4 pages, 3 figures. Clarifications added; published versio
High energy behaviour of form factors
We solve renormalization group equations that govern infrared divergences of
massless and massive form factors. By comparing to recent results for planar
massive three-loop and massless four-loop form factors in QCD, we give
predictions for the high-energy limit of massive form factors at the four- and
for the massless form factor at five-loop order. Furthermore, we discuss the
relation which connects infrared divergences regularized dimensionally and via
a small quark mass and extend results present in the literature to higher
order.Comment: 21 page
What can we learn about QCD and collider physics from N=4 super Yang-Mills?
Tremendous ongoing theory efforts are dedicated to developing new methods for
QCD calculations. Qualitative rather than incremental advances are needed to
fully exploit data still to be collected at the LHC. The maximally
supersymmetric Yang-Mills theory ( sYM) shares with QCD the
gluon sector, which contains the most complicated Feynman graphs, but at the
same time has many special properties, and is believed to be solvable exactly.
It is natural to ask what we can learn from advances in sYM
for addressing difficult problems in QCD. With this in mind, we review here
several remarkable developments and highlights of recent results in sYM. This includes all-order results for certain scattering amplitudes,
novel symmetries, surprising geometrical structures of loop integrands, novel
tools for the calculation of Feynman integrals, and bootstrap methods. While
several insights and tools have already been carried over to QCD and have
contributed to state-of-the-art calculations for LHC physics, we argue that
there is a host of further fascinating ideas waiting to be explored.Comment: 30 pages, 8 figures. Invited review to appear in Annual Review of
Nuclear and Particle Science; v2: presentation improve
Two-loop planar master integrals for the production of off-shell vector bosons in hadron collisions
We describe the calculation of all planar master integrals that are needed
for the computation of NNLO QCD corrections to the production of two off-shell
vector bosons in hadron collisions. The most complicated representatives of
integrals in this class are the two-loop four-point functions where two
external lines are on the light-cone and two other external lines have
different invariant masses. We compute these and other relevant integrals
analytically using differential equations in external kinematic variables and
express our results in terms of Goncharov polylogarithms. The case of two equal
off-shellnesses, recently considered in Ref. [1], appears as a particular case
of our general solution.Comment: 28 pages, many figures; ancillary files included with arXiv
submissio
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