Bosons Doubling

It is shown that next-nearest-neighbor interactions may lead to unusual paramagnetic or ferromagnetic phases which physical content is radically different from the standard phases. Actually there are several particles described by the same quantum field in a manner similar to the species doubling of the lattice fermions. We prove the renormalizability of the theory at the one loop level.Comment: 12 page

Hall effect encoding of brushless dc motors

Encoding mechanism integral to the motor and using the permanent magnets embedded in the rotor eliminates the need for external devices to encode information relating the position and velocity of the rotating member

A Second Generation (High-Speed) Maximum Power Tracker for Space Applications

During the past few years, considerable effort has been exerted by both industry and government to improve the performance of space power systems. One of the significant advances has been the development of practical Maximum Power-Point Tracking (MPPT) systems. This paper presents the background and evolution of a second-generation (high-speed) MPPT system capable of operation with solar arrays with rapidly fluctuating parameters due to mission operation (e.g., spin-stabilized spacecraft). An experimental model of the high-speed MPPT system has been constructed and tested. Results from these tests are presented herein. The second-generation MPPT system provides a means of efficient power conditioning that can result in significant increases over conventional systems in space-power system capability. Of additional importance is the applicability of the basic technology to all types of spacecraft, and the wide variety of power-system configurations with which the high-speed MPPT system concept may be used

Noncommutative Quantum Mechanics Viewed from Feynman Formalism

Dyson published in 1990 a proof due to Feynman of the Maxwell equations. This proof is based on the assumption of simple commutation relations between position and velocity. We first study a nonrelativistic particle using Feynman formalism. We show that Poincar\'{e}'s magnetic angular momentum and Dirac magnetic monopole are the direct consequences of the structure of the sO(3) Lie algebra in Feynman formalism. Then we show how to extend this formalism to the dual momentum space with the aim of introducing Noncommutative Quantum Mechanics which was recently the subject of a wide range of works from particle physics to condensed matter physics.Comment: 11 pages, To appear in the Proceedings of the Lorentz Workshop "Beyond the Quantum", eds. Th.M. Nieuwenhuizen et al., World Scientific, Singapore, 2007. Added reference

Les herbicides inhibateurs du photosystème II, effets sur les communautés algales et leur dynamique

Nous présentons une revue bibliographique à propos des effets des herbicides inhibiteurs du Photosystème II (PS II) sur les communautés algales. Ces herbicides sont abondamment utilisés dans les pratiques phytosanitaires. Ils sont susceptibles de contaminer les milieux aquatiques et, étant donné leur mode d'action inhibitrice de la photosynthèse, ils peuvent agir directement sur les algues. De nombreuses études ont été réalisées afin d'évaluer l'impact des contaminations par ces herbicides sur les microphytes, en particulier leur effet sur la croissance et la physiologie de certaines algues (monocultures en laboratoire). D'autres études expérimentales et quelques rares in situ, ont porté sur l'impact des herbicides inhibiteurs de la photosynthèse sur la structure des peuplements algaux. Certaines tendances ont pu être ainsi dégagées quant à la sensibilité et la résistance aux herbicides des différentes espèces étudiées soit isolément, soit au sein des peuplements. Les herbicides inhibiteurs du PS II perturbent effectivement la structure des peuplements phytoplanctoniques de façon plus ou moins marquée. L'impact des herbicides sur les algues est variable selon la structure des peuplements (liée aux successions) et les paramètres environnementaux, notamment liés à la saison. Nous devons donc développer nos connaissances à propos des interactions entre toxiques et facteurs environnementaux sur des pas de temps correspondant non seulement aux rythmes des contaminations mais aussi aux rythmes des succesions alagles, car ces interactions sont susceptibles de réduire ou d'amplifier les conséquences d'une pollution par ces toxiques dans les milieux aquatiques.The aim of this paper is to present a review about the impact of Photo system II (PS II) inhibitors on algae communities. A brief discussion of the use in agriculture, the different chemical families, the photosynthetic inhibition effect and the occurrence of these compounds in aquatics systems is followed by the presentation of the impacts these herbicides have on algae. Many studies investigate the effects of PS II inhibitors on algae growth and physiology. The response to pollutants were studied by monitoring changes in terms of different parameters : chlorophyll fluorescence induction usually increases with PS II inhibitors. Concentration of pigments decreases with PS II inhibitors, but increases sometimes with low contaminations of these toxicants (it is probably an homeostasis effect). Pigment ratio can change with herbicide exposure. Primary production (measured by 14C incorporation or dissolved O2) usually decreases with PS II inhibitors. But, the " excretion " of dissolved organic compounds may increase with PS II inhibitors. These herbicides may alter or change cell morphology of algae. In consequence algae growth is inhibited by PS II inhibitors exposure. But growth inhibition varies, depending on each species' (and strain) sensibility or resistance to each herbicide. By this way, PS II inhibitors can affect the algae community structure. In consequence, herbicides exert a selection pressure when the exposure reaches a certain level, and this for a sufficient period of time. Since organisms vary in their resistance to toxicants, the selection pressure will exclude the sensitive ones which will be replaced by resistant ones. Sometimes, responses to pollutants which are measured by global changes in biomass, pigments, dissolved O2... can recover after a lagtime. This apparent ability to recover from effects of herbicides can be explained by the following selection effect : resistant species are indirectly stimulated and develop in the contaminated environment. The result is an algae community which has an increased resistance to these toxicants as compared to a community which has not been affected by the toxicants. This difference in resistance, between the unselected and the selected communities, may be detected by comparison of results from short term physiological tests performed with the respective community and by comparison of each community structure (taxonomy). This methodological approach called Pollution-Induced Community Tolerance (PICT) is of a great interest as a biological marker of specific pollution in aquatic systems. Indirect effects of algae response to PS II inhibitors occur in the polluted ecosystem according to changes of the physicochemical conditions (decrease of dissolved O2 concentrations and pH, increase of dissolved organic and inorganic matters ...). Furthermore, the impact of herbicides on algae communities varies, depending on the community's species composition (depending on successions) and on environmental factors such as interspecific interactions and physicochemical parameters (depending on seasonal changes). Interspecific interactions implies competition for the limiting nutrients among algae and allelopathic interactions among algae, as well as interactions between algae and other trophic levels (microbial loop, grazing pressure ...). These interactions between herbicides and environmental factors may reduce or emphasize the consequences of such a pollution in aquatic systems. Seasonal change of algae communities species composition (algae successions) occurs as a response to changing environmental factors by the way of interspecific interactions and physicochemical parameters. Therefore, algae succession is affected by the herbicide destructuration of the algae communities. At the opposite, interactions and successions may affect the response of algae communities to the toxic. In this sense, herbicides act as a supplementary factor of disturbance in algae successions. Structural changes, induced by these herbicides, are usually accompanied by the attributes which are typical of an early successional stage. But, according to the " Intermediate Disturbance Hypothesis " the species richness should be maximal at intermediate intensities of herbicide contamination and at intermeadite frequencies of contaminations. The question is to compare the algae successions rythms and the frequencies of herbicides contaminations. Then, the time factor (or the persisting quality, which is difficult to assess in experimental studies) has to be taken in account in monitoring aquatic polluted systems, because of the seasonal variability in the response of algae to PS II inhibitors as well as the seasonal variability of water bodies' contamination by these herbicides through watersheds. Moreover, usually, low values of herbicides' concentrations occur in aquatic environments but are persistant. It results that aquatic organisms are exposed during long periods of time, meaning that indirect effects, via interactions between herbicides and environmental factors, may be emphazised. To further investigate these interactions and the herbicide persistance in aquatic systems, we have to develop experimental studies. This approach, however, must be complemented with in situ studies monitored with a timing of investigation relative to the natural population fluctuations and " pulses " of herbicides in these systems. Investigation must take place on various aquatic ecosystems. If a greater effort is given to monitor natural systems, for both herbicides and herbicides-induced effects, this will provide greater confidence in future predictions regarding the safety of PS II inhibitors in aquatic environments

Efficient oxide phosphors for light upconversion; green emission from Yb3+ and Ho3+ co-doped Ln(2)BaZnO(5) (Ln = Y, Gd)

This is the author's accepted version of the article. The final published article can be found here: http://dx.doi.org/10.1039/C0JM01652