Probing the light induced dipole-dipole interaction in momentum space

We theoretically investigate the mechanical effect of the light-induced dipole-dipole interaction potential on the atoms in a Bose-Einstein condensate. We present numerical calculations on the magnitude and shape of the induced potentials for different experimentally accessible geometries. It is shown that the mechanical effect can be distinguished from the effect of incoherent scattering for an experimentally feasible setting

Spin-3 Chromium Bose-Einstein Condensates

We analyze the physics of spin-3 Bose-Einstein condensates, and in particular the new physics expected in on-going experiments with condensates of Chromium atoms. We first discuss the ground-state properties, which, depending on still unknown Chromium parameters, and for low magnetic fields can present various types of phases. We also discuss the spinor-dynamics in Chromium spinor condensates, which present significant qualitative differences when compared to other spinor condensates. In particular, dipole-induced spin relaxation may lead for low magnetic fields to transfer of spin into angular momentum similar to the well-known Einstein-de Haas effect. Additionally, a rapid large transference of population between distant magnetic states becomes also possible.Comment: 4 pages, 3 eps figures. Error in the previous version correcte

TERRITORIAL BEHAVIOR AND CORTICAL BRAIN PLASTICITY IN ADULT MALE SCELOPORUS OCCIDENTALIS

The hippocampus is a brain region that can undergo tremendous plasticity in adulthood. The hippocampus is related to the formation of spatial memories in birds and mammals. In birds, plasticity in the hippocampus occurs when formation of such memories is directly relevant to survival or reproduction, such as for breeding or food caching. In reptiles, the homologues to the hippocampus are the dorsal and medial cortices (DC and MC). In several lizard, snake and turtle species, these structures have been related to spatial memory. Experimental investigations indicate that differences in DC volume are related to space use associated with differing foraging ecologies. Differences in MC volume have been associated with territory size-based mate acquisition strategies. Furthermore, territory size has previously been correlated with plasma testosterone (T) levels. Therefore, I hypothesized that neuroplasticity within the MC/DC is controlled by demands on spatial navigation and seasonal differences and that these changes may involve the action of T. During two experimental trials, male Western Fence Lizards (Sceloporus occidentalis) were placed into either large or small semi-natural enclosures and allowed to interact with a female and intruder males over the span of seven weeks. One trial was performed during the spring breeding season and the other during the summer non breeding season, to examine seasonal differences in plasticity. Blood samples were collected at initial time of capture and before sacrifice to measure plasma T. Immunostaining for doublecortin was used to determine the density of immature neurons in each region, and cresyl violet staining allowed for volume measurements of specific regions. MC cell layer neurogenesis was higher in lizards placed in large enclosures than those in small enclosures and higher in the summer than in the spring. DC volume was smaller in lizards held in large enclosures than those in small enclosures. The decreased DC volume seen lizards held in large enclosures may indicate a cost to the increased neurogenesis in the MC of lizards in the same enclosures. These results indicate a possible trade-off between DC volume and MC neurogenesis that allows for switching between the ability to solve novel spatial tasks using the DC while storing a cognitive map in the MC. During the spring, T had no relationship with MC volume, while during the summer this was negative, so effects of T on the MC may be seasonal

Toward High Performance Nanocarbon Fibers

High performance carbon fibers (CFs) have been a commercially available since their commercial boom in the 1970s, and are generally produced via carbonization of poly (acrylonitrile) (PAN). More recently, carbon nanomaterials like graphene and carbon nanotubes (CNTs) have been discovered and have shown excellent mechanical, thermal, and electrical properties due to their sp2 carbon repeating structure. Graphene and CNTs can both be organized into macroscopic fibers using a number of different techniques, resulting in fibers with promising mechanical performance that can be readily multifunctionalized. In some cases, the two materials have been combined, and the resulting hybrid fibers have been shown to display synergistically enhanced mechanical properties. The incredible intrinsic properties of graphene and CNTs has never been fully realized in their fiber assemblies, so part of the aim of this work is to discover methods to improve upon the performance of nanocarbon based fibers. Carbon nanomaterials can be difficult to work with because of the difficulty in processing them into commercially viable materials, and the challenges associated with scalable production techniques. So, the main goal of this work is to prepare hybrid graphene and CNT based fibers with optimal mechanical performance using simple, cost-effective methods

Signing NOT (or not): A typological perspective on standard negation in Sign Language of the Netherlands

The expression of standard negation by means of manual and/or non-manual markers has been described for a considerable number of sign languages. Typological comparisons have revealed an intriguing dichotomy: while some sign languages require a manual negative element in negative clauses (manual-dominant sign languages), in others negation can be realized by a non-manual marker alone (in particular a headshake; non-manual-dominant sign languages). We are here adding data from Sign Language of the Netherlands (NGT) to the picture, and we demonstrate that NGT belongs to the latter group. Still, detailed comparison suggests that NGT patterns differently from other non-manual-dominant sign languages, thereby improving our understanding of the typological variation in this domain. A novel contribution of the present study is that it is based on naturalistic corpus data, showing more variation than often found in elicitation and grammaticality judgment studies of sign languages, but also presenting new problems of interpretation

A two-lobe Journal Bearing with adjustable Gap Geometry for Vibration Reduction of flexible Rotors

Flexible rotors in journal bearings can exhibit large vibration amplitudes during the passage of bending critical speeds.  To reduce these vibrations, a two-lobe journal bearing with adjustable gap geometry is presented. By an adjustment of  the gap height, stiffness and damping properties of the bearing and as a consequence the damping ratio of the rotor  system can be varied during the operation. When the system passes a critical speed in a run-up process, a large gap is  adjusted for higher damping. After the resonance pass through, the gap height is reduced to increase the load  carrying  capacity and to enlarge the stability margin. Investigating the Jeffcott rotor in adjustable journal bearings demonstrates the basic effects. For a validation, a test rig is set up and a related mathematical model is created.  Various experiments are made and compared with numerical results