204,817 research outputs found
The two dimensional antiferromagnetic Heisenberg model in the presence of an external field
We present numerical results on the zero temperature magnetization curve and
the static structure factors of the two dimensional antiferromagnetic
Heisenberg model in the presence of an external field. The impact of
frustration is also studied.Comment: 6 pages, 16 figures, REVTE
Magnesium and magnesium alloys as degradable metallic biomaterials
Drawbacks associated with permanent metallic implants lead to the search for degradable metallic biomaterials. Magnesium has been considered as it is essential to bodies and has a high biodegradation potential. For magnesium and its alloys to be used as biodegradable implant materials, their degradation rates should be consistent with the rate of healing of the affected tissue, and the release of the degradation products should be within the body's acceptable absorption levels. Conventional magnesium degrades rapidly, which is undesirable. In this study, biodegradation behaviours of high purity magnesium and commercial purity magnesium alloy AZ31 in both static and dynamic Hank's solution have been systematically investigated. The results show that magnesium purification and selective alloying are effective approaches to reduce the degradation rate of magnesium. In the static condition, the corrosion products accumulate on the materials surface as a protective layer, which results in a lower degradation rate than the dynamic condition. Anodised coating can significantly further reduce the degradation rate of magnesium. This study indicates that magnesium can be used as degradable implant materials as long as the degradation is controlled at a low rate. Magnesium purification, selective alloying and anodised coating are three effective approaches to reduce the rate of degradation
Nd-doped aluminum oxide integrated amplifiers at 880 nm, 1060 nm, and 1330 nm
Neodymium-doped Al2O3 layers were deposited on thermally oxidized Si substrates and channel waveguides were patterned using reactive-ion etching. Internal net gain on the Nd3+ transitions at 880, 1064, and 1330 nm was investigated,\ud
yielding a maximum gain of 6.3 dB/cm at 1064 nm. Values for the energy-transfer upconversion parameter for different Nd3+\ud
concentrations were deduced
The Impact of Radio AGN Bubble Composition on the Dynamics and Thermal Balance of the Intracluster Medium
Feeding and feedback of active galactic nuclei (AGN) are critical for
understanding the dynamics and thermodynamics of the intracluster medium (ICM)
within the cores of galaxy clusters. While radio bubbles inflated by AGN jets
could be dynamically supported by cosmic rays (CRs), the impact of CR-dominated
jets are not well understood. In this work, we perform three-dimensional
simulations of CR-jet feedback in an isolated cluster atmosphere; we find that
CR jets impact the multiphase gas differently than jets dominated by kinetic
energy. In particular, CR bubbles can more efficiently uplift the cluster gas
and cause an outward expansion of the hot ICM. Due to adiabatic cooling from
the expansion and less efficient heating from CR bubbles by direct mixing, the
ICM is more prone to local thermal instabilities, which will later enhance
chaotic cold accretion onto the AGN. The amount of cold gas formed during the
bubble formation and its late-time evolution sensitively depend on whether CR
transport processes are included or not. We also find that low-level, subsonic
driving of turbulence by AGN jets holds for both kinetic and CR jets;
nevertheless, the kinematics is consistent with the Hitomi measurements.
Finally, we carefully discuss the key observable signatures of each bubble
model, focusing on gamma-ray emission (and related comparison with Fermi), as
well as thermal Sunyaev-Zel'dovich constraints.Comment: accepted to Ap
The Fermi Bubbles: Gamma-ray, Microwave, and Polarization Signatures of Leptonic AGN Jets
The origin of the Fermi bubbles and the microwave haze is yet to be
determined. To disentangle different models requires detailed comparisons
between theoretical predictions and multi-wavelength observations. Our previous
simulations have demonstrated that the primary features of the Fermi bubbles
could be successfully reproduced by recent jet activity from the central active
galactic nucleus (AGN). In this work, we generate gamma-ray and microwave maps
and spectra based on the simulated properties of cosmic rays (CRs) and magnetic
fields in order to examine whether the observed bubble and haze emission could
be explained by leptons contained in the AGN jets. We also investigate the
model predictions of the polarization properties of the Fermi bubbles. We find
that: (1) The same population of leptons can simultaneously explain the bubble
and haze emission given that the magnetic fields within the bubbles are very
close to the exponentially distributed ambient field, which can be explained by
mixing in of the ambient field followed by turbulent field amplification; (2)
The centrally peaked microwave profile suggests CR replenishment, which is
consistent with the presence of a more recent second jet event; (3) The bubble
interior exhibits a high degree of polarization because of ordered radial
magnetic field lines stretched by elongated vortices behind the shocks;
highly-polarized signals could also be observed inside the draping layer; (4)
Enhancement of rotation measures could exist within the shock-compressed layer
because of increased gas density and more amplified and ordered magnetic
fields. We discuss the possibility that the deficient haze emission at b<-35
degrees is due to the suppression of magnetic fields, which is consistent with
the existence of lower-energy CRs causing the polarized emission at 2.3 GHz.
Possible AGN jet composition in the leptonic scenario is also discussed.Comment: 15 pages, 9 figures, matched with MNRAS published versio
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