80,114 research outputs found
Dark Matter and Indirect Detection in Cosmic Rays
In the early years, cosmic rays contributed essentially to particle physics
through the discovery of new particles. Will history repeat itself? As with the
discovery of the charged pion, the recent discovery of a Higgs-like boson may
portend a rich new set of particles within reach of current and near future
experiments. These may be discovered and studied by cosmic rays through the
indirect detection of dark matter.Comment: 8 pages, to appear in the Proceedings of Centenary Symposium 2012:
Discovery of Cosmic Rays, Denver, Colorado, June 201
Dark Matter Phenomenology
I review recent developments in the direct and indirect detection of dark
matter and new candidates beyond the WIMP paradigm.Comment: 6 pages, to appear in the Proceedings of the Tenth Conference on the
Intersections of Particle and Nuclear Physics (CIPANP 2009), San Diego,
California, 26-31 May 200
Non-WIMP Candidates
Non-WIMP dark matter candidates include particles motivated by minimality,
candidates motivated by experimental anomalies, and exotic possibilities
motivated primarily by the desire of clever iconoclasts to highlight how truly
ignorant we are about the nature of dark matter. In this review, I discuss
candidates that are not WIMPs, but nevertheless share the same theoretical
motivations as WIMPs and also naturally have the correct relic density. There
are two classes: superWIMP dark matter, where the desired relic density is
inherited through decays, and WIMPless dark matter, where the dark matter's
mass and couplings scale together to maintain the desired thermal relic
density.Comment: 20 pages, published as Chapter 10, pp. 190-204, in Particle Dark
Matter: Observations, Models and Searches, edited by Gianfranco Bertone
(Cambridge University Press, 2010), available at
http://cambridge.org/us/catalogue/catalogue.asp?isbn=978052176368
Testing Supersymmetry at the Next Linear Collider
If new particles are discovered, it will be important to determine if they
are the supersymmetric partners of standard model bosons and fermions.
Supersymmetry predicts relations among the couplings and masses of these
particles. We discuss the prospects for testing these relations at a future
linear collider with measurements that exploit the availability of
polarized beams.Comment: Talk presented at DPF'94, Albuquerque, New Mexico, Aug 2-6, 1994, 6
pages, Latex with world_sci.sty, 3 figures available upon request,
SLAC-PUB-6662. (text with encapsulated figures available in ps form by
anonymous ftp from preprint.slac.stanford.edu, directory
pub/preprints/hep-ph/9409
Dark Matter Implications for Linear Colliders
The existence of dark matter is currently one of the strongest motivations
for physics beyond the standard model. Its implications for future colliders
are discussed. In the case of neutralino dark matter, cosmological bounds do
not provide useful upper limits on superpartner masses. However, in simple
models, cosmological considerations do imply that for supersymmetry to be
observable at a 500 GeV linear collider, some signature of supersymmetry must
appear before the LHC.Comment: 4 pages, 2 figures, to appear in the proceedings of Linear Collider
Workshop 2000, Fermilab, October 200
ILC Cosmology
Recent breakthroughs in cosmology pose questions that require particle
physics answers. I review the problems of dark matter, baryogenesis, and dark
energy and discuss how particle colliders, particularly the International
Linear Collider, may advance our understanding of the contents and evolution of
the Universe.Comment: 18 pages, Plenary Colloquium presented at the 2005 International
Linear Collider Workshop, Stanford, California, USA, 18-22 March 200
Naturalness and the Status of Supersymmetry
For decades, the unnaturalness of the weak scale has been the dominant
problem motivating new particle physics, and weak-scale supersymmetry has been
the dominant proposed solution. This paradigm is now being challenged by a
wealth of experimental data. In this review, we begin by recalling the
theoretical motivations for weak-scale supersymmetry, including the gauge
hierarchy problem, grand unification, and WIMP dark matter, and their
implications for superpartner masses. These are set against the leading
constraints on supersymmetry from collider searches, the Higgs boson mass, and
low-energy constraints on flavor and CP violation. We then critically examine
attempts to quantify naturalness in supersymmetry, stressing the many
subjective choices that impact the results both quantitatively and
qualitatively. Finally, we survey various proposals for natural supersymmetric
models, including effective supersymmetry, focus point supersymmetry,
compressed supersymmetry, and R-parity-violating supersymmetry, and summarize
their key features, current status, and implications for future experiments.Comment: 38 pages, to appear in Annual Review of Nuclear and Particle Science;
v2: fixed typos, updated Higgs results, added references and a parable,
published versio
Mitigation of dynamical instabilities in laser arrays via non-Hermitian coupling
Arrays of coupled semiconductor lasers are systems possessing complex
dynamical behavior that are of major interest in photonics and laser science.
Dynamical instabilities, arising from supermode competition and slow carrier
dynamics, are known to prevent stable phase locking in a wide range of
parameter space, requiring special methods to realize stable laser operation.
Inspired by recent concepts of parity-time () and non-Hermitian
photonics, in this work we consider non-Hermitian coupling engineering in laser
arrays in a ring geometry and show, both analytically and numerically, that
non-Hermitian coupling can help to mitigate the onset of dynamical laser
instabilities. In particular, we consider in details two kinds of
nearest-neighbor non-Hermitian couplings: symmetric but complex mode coupling
(type-I non-Hermitian coupling) and asymmetric mode coupling (type-II
non-Hermitian coupling). Suppression of dynamical instabilities can be realized
in both coupling schemes, resulting in stable phase-locking laser emission with
the lasers emitting in phase (for type-I coupling) or with phase
gradient (for type-II coupling), resulting in a vortex far-field beam. In
type-II non-Hermitian coupling, chirality induced by asymmetric mode coupling
enables laser phase locking even in presence of moderate disorder in the
resonance frequencies of the lasers.Comment: revised version, changed title, added one figure and some reference
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