324 research outputs found
Frozen photons in Jaynes Cummings arrays
We study the origin of "frozen" states in coupled Jaynes-Cummings-Hubbard arrays in the presence of losses. For the case of half the array initially populated with photons while the other half is left empty we show the emergence of self-localized photon or "frozen" states for specific values of the local atom-photon coupling. We analyze the dynamics in the quantum regime and discover important additional features appear not captured by a semiclassical treatment, which we analyze for different array sizes and filling fractions. We trace the origin of this interaction-induced photon "freezing" to the suppression of excitation of propagating modes in the system at large interaction strengths. We discuss in detail the possibility to experimentally probe the relevant transition by analyzing the emitted photon correlations. We find a strong signature of the effect in the emitted photons statistics
Linear stability theory as an early warning sign for transitions in high dimensional complex systems
We analyse in detail a new approach to the monitoring and forecasting of the onset of transitions in high dimensional complex systems by application to the Tangled Nature model of evolutionary ecology and high dimensional replicator systems with a stochastic element. A high dimensional stability matrix is derived in the mean field approximation to the stochastic dynamics. This allows us to determine the stability spectrum about the observed quasi-stable configurations. From overlap of the instantaneous configuration vector of the full stochastic system with the eigenvectors of the unstable directions of the deterministic mean field approximation, we are able to construct a good early-warning indicator of the transitions occurring intermittently
Probing the depths of the India-Asia collision: U-Th-Pb monazite chronology of granulites from NW Bhutan
[1] Rocks metamorphosed to high temperatures and/or high pressures are rare across the Himalayan orogen, where peak metamorphic conditions recorded in the exposed metamorphic core, the Greater Himalayan Sequence (GHS), are generally at middle to upper amphibolite facies. However, mafic garnet-clinopyroxene assemblages exposed at the highest structural levels in Bhutan, eastern Himalaya, preserve patchy textural evidence for early eclogite-facies conditions, overprinted by granulite-facies conditions. Monazite hosted within the leucosome of neighboring granulite-facies orthopyroxene-bearing felsic gneiss yields LA-MC-ICP-MS U-Th-Pb ages of 13.9 ± 0.3 Ma. Monazite associated with sillimanite-grade metamorphism in granulite-hosting migmatitic gneisses yields U-Th-Pb rim ages between 15.4 ± 0.8 Ma and 13.4 ± 0.5 Ma. Monazite associated with sillimanite-grade metamorphism in gneiss at structurally lower levels yields U-Pb rim ages of 21–17 Ma. These data are consistent with Miocene exhumation of GHS material from a variety of crustal depths at different times along the Himalayan orogen. We propose that these granulitized eclogites represent lower crustal material exhumed by tectonic forcing over an incoming Indian crustal ramp and that they formed in a different tectonic regime to the ultrahigh-pressure eclogites in the western Himalaya. Their formation and exhumation in the Miocene therefore do not require diachroneity in the timing of the initial India-Asia collision
Heart rate variability before and after cycle exercise in relation to different body positions
The purpose of this study was to assess the effect of three different body positions on HRV measures following short-term submaximal exercise. Thirty young healthy males performed submaximal cycling for five minutes on three different occasions. Measures of HRV were obtained from 5-min R to R wave intervals before the exercise (baseline) and during the last five minutes of a 15 min recovery (post-exercise) in three different body positions (seated, supine, supine with elevated legs). Measures of the mean RR normal-to-normal intervals (RRNN), the standard deviation of normal-to-normal intervals (SDNN), the root mean square of successive differences (RMSSD) and the low-frequency (LF) and the high-frequency (HF) spectral power were analyzed. Post-exercise RRNN, RMSSD were significantly higher in the two supine positions (p 0.05). Post-exercise time domain measures of HRV (RRNN, SDNN, RMSSD) were significantly lower compared with baseline values (p < 0.01) regardless body position. Post-exercise ln LF and ln HF in all three positions remained significantly reduced during recovery compared to baseline values (p < 0.01). The present study suggests that 15 minutes following short-term submaximal exercise most of the time and frequency domain HRV measures have not returned to pre-exercise values. Modifications in autonomic cardiac regulation induced by body posture present at rest remained after exercise, but the post-exercise differences among the three positions did not resemble the ones established at res
Non-equilibrium many-body effects in driven nonlinear resonator arrays
We study the non-equilibrium behavior of optically driven dissipative coupled
resonator arrays. Assuming each resonator is coupled with a two-level system
via a Jaynes-Cummings interaction, we calculate the many-body steady state
behavior of the system under coherent pumping and dissipation. We propose and
analyze the many-body phases using experimentally accessible quantities such as
the total excitation number, the emitted photon spectra and photon coherence
functions for different parameter regimes. In parallel, we also compare and
contrast the expected behavior of this system assuming the local nonlinearity
in the cavities is generated by a generic Kerr effect rather than a
Jaynes-Cummings interaction. We find that the behavior of the experimentally
accessible observables produced by the two models differs for realistic regimes
of interactions even when the corresponding nonlinearities are of similar
strength. We analyze in detail the extra features available in the
Jaynes-Cummings-Hubbard (JCH) model originating from the mixed nature of the
excitations and investigate the regimes where the Kerr approximation would
faithfully match the JCH physics. We find that the latter is true for values of
the light-matter coupling and losses beyond the reach of current technology.
Throughout the study we operate in the weak pumping, fully quantum mechanical
regime where approaches such as mean field theory fail, and instead use a
combination of quantum trajectories and the time evolving block decimation
algorithm to compute the relevant steady state observables. In our study we
have assumed small to medium size arrays (from 3 up to 16 sites) and values of
the ratio of coupling to dissipation rate which makes our
results implementable with current designs in Circuit QED and with near future
photonic crystal set ups.Comment: 22 pages, 6 figure
Timing and mechanism of the rise of the Shillong Plateau in the Himalayan foreland
The Shillong Plateau (northeastern India) constitutes the only significant topography in the Himalayan foreland. Knowledge of its surface uplift history is key to understanding topographic development and unraveling tectonic–climate–topographic coupling in the eastern Himalaya. We use the sedimentary record of the Himalayan foreland basin north of the Shillong Plateau to show that the paleo-Brahmaputra river was redirected north and west by the rising plateau at 5.2–4.9 Ma. We suggest that onset of plateau uplift is a result of increased fault-slip rates in response to stresses caused by the Indian lithosphere bending beneath the Himalaya
Non-equilibrium supercurrent through mesoscopic ferromagnetic weak links
We consider a mesoscopic normal metal, where the spin degeneracy is lifted by
a ferromagnetic exchange field or Zeeman splitting, coupled to two
superconducting reservoirs. As a function of the exchange field or the distance
between the reservoirs, the supercurrent through this device oscillates with an
exponentially decreasing envelope. This phenomenon is similar to the tuning of
a supercurrent by a non-equilibrium quasiparticle distribution between two
voltage-biased reservoirs. We propose a device combining the exchange field and
non-equilibrium effects, which allows us to observe a range of novel phenomena.
For instance, part of the field-suppressed supercurrent can be recovered by a
voltage between the additional probes.Comment: 7 pages, 8 figures, Europhys. Lett., to be published, corrected two
reference
Human alpha 2A-adrenergic receptor gene expressed in transgenic mouse adipose tissue under the control of its regulatory elements.
Catecholamines regulate white adipose tissue function and development by acting through beta- and alpha2-adrenergic receptors (ARs). Human adipocytes express mainly alpha 2A- but few or no beta 3-ARs while the reverse is true for rodent adipocytes. Our aim was to generate a mouse model with a human-like alpha2/beta-adrenergic balance in adipose tissue by creating transgenic mice harbouring the human alpha 2A-AR gene under the control of its own regulatory elements in a combined mouse beta 3-AR-/- and human beta 3-AR+/+ background. Transgenic mice exhibit functional human alpha 2A-ARs only in white fat cells. Interestingly, as in humans, subcutaneous adipocytes expressed higher levels of alpha2-AR than perigonadal fat cells, which are associated with a better antilipolytic response to epinephrine. High-fat-diet-induced obesity was observed in transgenic mice in the absence of fat cell size modifications. In addition, analysis of gene expression related to lipid metabolism in isolated adipocytes suggested reduced lipid mobilization and no changes in lipid storage capacity of transgenic mice fed a high-fat diet. Finally, the development of adipose tissue in these mice was not associated with significant modifications of glucose and insulin blood levels. Thus, these transgenic mice constitute an original model of diet-induced obesity for in vivo physiological and pharmacological studies with respect to the alpha2/beta-AR balance in adipose tissue
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