4,922 research outputs found
Towards gauge theories in four dimensions
The abundance of infrared singularities in gauge theories due to unresolved
emission of massless particles (soft and collinear) represents the main
difficulty in perturbative calculations. They are typically regularized in
dimensional regularization, and their subtraction is usually achieved
independently for virtual and real corrections. In this paper, we introduce a
new method based on the loop-tree duality (LTD) theorem to accomplish the
summation over degenerate infrared states directly at the integrand level such
that the cancellation of the infrared divergences is achieved simultaneously,
and apply it to reference examples as a proof of concept. Ultraviolet
divergences, which are the consequence of the point-like nature of the theory,
are also reinterpreted physically in this framework. The proposed method opens
the intriguing possibility of carrying out purely four-dimensional
implementations of higher-order perturbative calculations at next-to-leading
order (NLO) and beyond free of soft and final-state collinear subtractions.Comment: Final version to appear in JHE
Recent developments from the loop-tree duality
In this talk, we review the most recent developments of the four-dimensional
unsubstraction (FDU) and loop-tree duality (LTD) methods. In particular, we
make emphasis on the advantages of the LTD formalism regarding asymptotic
expansions of loop integrands.Comment: 8 pages, 1 figure. Presented at 13th International Symposium on
Radiative Corrections RADCOR2017, 24-29 September 2017, St. Gilgen, Austri
Causal representation of multi-loop Feynman integrands within the loop-tree duality
The numerical evaluation of multi-loop scattering amplitudes in the Feynman
representation usually requires to deal with both physical (causal) and
unphysical (non-causal) singularities. The loop-tree duality (LTD) offers a
powerful framework to easily characterise and distinguish these two types of
singularities, and then simplify analytically the underling expressions. In
this paper, we work explicitly on the dual representation of multi-loop Feynman
integrals generated from three parent topologies, which we refer to as Maximal,
Next-to-Maximal and Next-to-Next-to-Maximal loop topologies. In particular, we
aim at expressing these dual contributions, independently of the number of
loops and internal configurations, in terms of causal propagators only. Thus,
providing very compact and causal integrand representations to all orders. In
order to do so, we reconstruct their analytic expressions from numerical
evaluation over finite fields. This procedure implicitly cancels out all
unphysical singularities. We also interpret the result in terms of entangled
causal thresholds. In view of the simple structure of the dual expressions, we
integrate them numerically up to four loops in integer space-time dimensions,
taking advantage of their smooth behaviour at integrand level.Comment: 24 pages, 8 figures. v2: references added; matches published versio
A stroll through the loop-tree duality
The Loop-Tree Duality (LTD) theorem is an innovative technique to deal with multi-loop scattering amplitudes, leading to integrand-level representations over a Euclidean space. In this article, we review the last developments concerning this framework, focusing on the manifestly causal representation of multi-loop Feynman integrals and scattering amplitudes, and the definition of dual local counter-terms to cancel infrared singularities
Target Selection for the Apache Point Observatory Galactic Evolution Experiment (APOGEE)
The Apache Point Observatory Galactic Evolution Experiment (APOGEE) is a
high-resolution infrared spectroscopic survey spanning all Galactic
environments (i.e., bulge, disk, and halo), with the principal goal of
constraining dynamical and chemical evolution models of the Milky Way. APOGEE
takes advantage of the reduced effects of extinction at infrared wavelengths to
observe the inner Galaxy and bulge at an unprecedented level of detail. The
survey's broad spatial and wavelength coverage enables users of APOGEE data to
address numerous Galactic structure and stellar populations issues. In this
paper we describe the APOGEE targeting scheme and document its various target
classes to provide the necessary background and reference information to
analyze samples of APOGEE data with awareness of the imposed selection criteria
and resulting sample properties. APOGEE's primary sample consists of ~100,000
red giant stars, selected to minimize observational biases in age and
metallicity. We present the methodology and considerations that drive the
selection of this sample and evaluate the accuracy, efficiency, and caveats of
the selection and sampling algorithms. We also describe additional target
classes that contribute to the APOGEE sample, including numerous ancillary
science programs, and we outline the targeting data that will be included in
the public data releases.Comment: Accepted to AJ. 31 pages, 11 figure
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