6,221 research outputs found
Exact Cosmological Solutions of Theories via Hojman Symmetry
Nowadays, theory has been one of the leading modified gravity theories
to explain the current accelerated expansion of the universe, without invoking
dark energy. It is of interest to find the exact cosmological solutions of
theories. Besides other methods, symmetry has been proved as a powerful
tool to find exact solutions. On the other hand, symmetry might hint the deep
physical structure of a theory, and hence considering symmetry is also well
motivated. As is well known, Noether symmetry has been extensively used in
physics. Recently, the so-called Hojman symmetry was also considered in the
literature. Hojman symmetry directly deals with the equations of motion, rather
than Lagrangian or Hamiltonian, unlike Noether symmetry. In this work, we
consider Hojman symmetry in theories in both the metric and Palatini
formalisms, and find the corresponding exact cosmological solutions of
theories via Hojman symmetry. There exist some new solutions significantly
different from the ones obtained by using Noether symmetry in theories.
To our knowledge, they also have not been found previously in the literature.
This work confirms that Hojman symmetry can bring new features to cosmology and
gravity theories.Comment: 16 pages, revtex4; v2: discussions added, Nucl. Phys. B in press; v3:
published version. arXiv admin note: text overlap with arXiv:1505.0754
Probing for the Cosmological Parameters with PLANCK Measurement
We investigate the constraints on cosmological parameters especially for EoS
of dark energy, inflationary parameters, neutrino mass and curvature of
universe using simulated Planck data. Firstly we determine cosmological
parameters with current observations including ESSENCE, WMAP3, Boomerang-2K2,
CBI, VSA, ACBAR, SDSS LRG and 2dFGRS, and take best-fit model as the fiducial
model in simulations. In simulations we pay attention to the effects of
dynamical dark energy in determination of cosmological parameters. We add
simulated SNAP data to do all the simulations. Using present data, we find
Quintom dark energy model is mildly favored while \LambdaCDM remains a good
fit. In the framework of dynamical dark energy, the constraints on inflationary
parameters, m_{\nu} and \Omega_{K} become weak compared with the constraints in
\LambdaCDM. Intriguingly, we find that the inflationary models with a "blue"
tilt, which are excluded about 2\sigma in \LambdaCDM model, are well within
2\sigma region with the presence of the dynamics of dark energy. The upper
limits of neutrino mass are weakened by a factor of 2 (95% C.L.), say,
m_{\nu}<1.59 eV and m_{\nu}<1.53 eV for two forms of parametrization of the
equation of state of dark energy. The flat universe is a good fit to the
current data, namely, |\Omega_{K}|<0.03 (95% C.L.). With the simulated Planck
and SNAP data, dynamical dark energy and \LambdaCDM might be distinguished at
4\sigma. And uncertainties of inflationary parameters, m_{\nu} and \Omega_{K}
can be reduced obviously. We also constrain the rotation angle \Delta\alpha,
denoting possible cosmological CPT violation, with simulated Planck and CMBpol
data and find that our results are much more stringent than current constraint
and will verify cosmological CPT symmetry with a higher precision. (Abridged)Comment: 15 pages, 8 figures and 3 tables, Accepted for publication in
Int.J.Mod.Phys.
Graphene-plasmon polaritons: From fundamental properties to potential applications
With the unique possibilities for controlling light in nanoscale devices,
graphene plasmonics has opened new perspectives to the nanophotonics community
with potential applications in metamaterials, modulators, photodetectors, and
sensors. This paper briefly reviews the recent exciting progress in graphene
plasmonics. We begin with a general description for optical properties of
graphene, particularly focusing on the dispersion of graphene-plasmon
polaritons. The dispersion relation of graphene-plasmon polaritons of spatially
extended graphene is expressed in terms of the local response limit with
intraband contribution. With this theoretical foundation of graphene-plasmon
polaritons, we then discuss recent exciting progress, paying specific attention
to the following topics: excitation of graphene plasmon polaritons,
electron-phonon interactions in graphene on polar substrates, and tunable
graphene plasmonics with applications in modulators and sensors. Finally, we
seek to address some of the apparent challenges and promising perspectives of
graphene plasmonics.Comment: Invited minireview paper on graphene plasmon polaritons, 11 pages, 4
figure
Determining Cosmological Parameters with Latest Observational Data
In this paper, we combine the latest observational data, including the WMAP
five-year data (WMAP5), BOOMERanG, CBI, VSA, ACBAR, as well as the Baryon
Acoustic Oscillations (BAO) and Type Ia Supernoave (SN) "Union" compilation
(307 sample) to determine the cosmological parameters. Our results show that
the CDM model remains a good fit to the current data. In a flat
universe, we obtain the tight limit on the constant EoS of dark energy as,
(). For the dynamical dark energy models with time
evolving EoS, we find that the best-fit values are and ,
implying the preference of Quintom model whose EoS gets across the cosmological
constant boundary. For the curvature of universe, our results give
(95% C.L.) when fixing w_{\DE}=-1. When considering
the dynamics of dark energy, the flat universe is still a good fit to the
current data. Regarding the neutrino mass limit, we obtain the upper limits,
eV (95% C.L.) within the framework of the flat
CDM model. When adding the SDSS Lyman- forest power spectrum
data, the constraint on can be significantly improved, eV (95% C.L.). Assuming that the primordial fluctuations are
adiabatic with a power law spectrum, within the CDM model, we find
that the upper limit on the ratio of the tensor to scalar is (95%
C.L.) and the inflationary models with the slope are excluded at
more than confidence level. However, in the framework of dynamical
dark energy models, the allowed region in the parameter space of (,) is
enlarged significantly. Finally, we find no evidence for the large running of
the spectral index. (Abridged)Comment: 8 pages, 5 figures, 2 tables, More discussion on NE
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