In the present report we analyzed the origin of this feature based on finite-difference time-domain (FDTD) approach as well as a simple point dipole model that incorporates the interparticle interaction with the dipole-dipole potential. It has been found that the simple point dipole model is useful AL3818 cell line for qualitative discussion on the optical field distribution in the metal nanoparticle assemblies. From the analysis, we have found that the interparticle interaction, which causes the propagation of the plasmon excitation in
the assemblies, seems to be essential for the localization of the enhanced field at the rim. We propose that regular close-packed assemblies do not yield efficiently enhanced optical fields in visible to near-infrared region, and rather assemblies with large fluctuation CCI-779 order are more advantageous to get highly enhanced fields. (C) 2011 Elsevier B.V. All rights reserved.”
“Premise of the study: Biological invasions threaten global biodiversity, resulting in severe ecological and economic costs. Phenotypic plasticity and differentiation in fi tness-related traits after introduction can contribute to increased performance in invasive populations of plants. We determined whether postintroduction evolution in
trait means or in their plasticity, or inherent species-wide phenotypic plasticity has promoted invasiveness in a European annual forb.\n\nMethods: In a common greenhouse, we compared several fi tness-related traits and the phenotypic plasticity of those traits under four
levels of nutrients among native and invasive populations of Centaurea melitensis. We tested 18 populations from three regions of similar mediterranean climate type: the native range (southern Spain) and two invaded ranges (California and central Chile).\n\nKey results: Centaurea NVP-AUY922 in vitro melitensis possesses overall phenotypic plasticity, which is a trait that promotes invasiveness. Invasive populations were differentiated from native plants for several trait means and their levels of phenotypic plasticity in directions that enhance competitive ability and success. Invasive plants fl owered earlier and grew faster in the early stages of growth phases, important features for invasiveness.\n\nConclusions: Phenotypic plasticity, its evolution postinvasion, and the evolution of fi tness-related trait means in invasive populations have potentially contributed to the invasion of C. melitensis in California and Chile. Along with an overall wide range of tolerance to growing conditions, C. meltiensis populations that have colonized habitats in California and Chile have undergone rapid evolution in several life history traits and the plasticities of those traits in directions that would promote invasiveness in mediterranean ecosystems.