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Permalink Reply by Paolo Manzelli on October 24, 2011 at 1:46pm

Advances in nano-scale-science  includes Entanglement in nano and bio-molecular systems . 

http://www.edscuola.it/archivio/lre/Nano-science.pdf

 

The objective of EGOCREANET (www.edscuola.it/lre.html) in the context of "Nanopaprika"  is to open a debate to sharing innovation and hypotheses on the future of nano-science to provide a forum for researchers and industry managers to exchange and discuss latest and future design and analysis for nano-scale science .

 Namely, we are interested in establishing the feasibility and characteristics of Quantum - entanglement in nano-scale dimension opening a networking through the trans-disciplinary application of the concept of entanglement to  cultural and science design, modelling in art and science and visual  simulation of nano-scale innovation.

A particular focus of such open debate will be to the issues of Quantum Entenhlement theory  regarding , quantum molecular entanglement in  nano-scale,and to other relevant topics  including: quantum coherence in delocalized bond structures and quantum entanglement in nanoscale dot- systems etc.. .

Paolo Manzelli  OCT/24/2011-Firenze <pmanzelli.lre@gmail.com>

 

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Permalink Reply by Paolo Manzelli on October 24, 2011 at 2:45pm

Note about the entanglement in nano-scale science: 

One of most peculiar properties of Quantum Physiscs is focused on the Entanglement that get the possibility to built up special quantum shared states based on delocalized electon's field. 

In fact Entanglement permits to change the degre of localization of quantum/wave particles ;in fact also during  a spatial separation of pairwise electrons quantum entanglement generate a new  partial localized conjugate-systems of bonding atoms. 

The entanglement activity can evolve in strenght  and in coherence of sinultanety properties of mixed delocalized states and/or in the  successive  decay to localized single states  in function of some noises ( temperature and other interferences) that dis-entangled the stability in the time-scale of the simultaneity co-existence of entangled states . 

To investigate on the properties innovation of entanglement effects I think that good experimental  information can be obtaied looking at the spectum of emission induced by  lasers and measured in femto-seconds (Femto-chemistry *). In fact this fast-method of investigation can give information observed  exactly what happens at the molecular level during a chemical reaction. So that ultrafast molecular dynanics in future  can permit to deeply understand the effect of entangled  hybridization of elecron's field ( in some way similar to the mettallic bond) caused by the overposition of  electron orbitals to create the molecular bonding in the nano-scale dimension. 

(*) http://www.zewail.caltech.edu/JChemEduc.pdf

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Permalink Reply by Paolo Manzelli on October 29, 2011 at 3:24pm

Orbitali atomici, essendo aree geometriche di probabilita, non avendo significato fisico dovrebbero essere inattivi e non giocare alcun ruolo nelle proprieta fisiche dei Materiali Nano. Ma si scopre che questi, orbitali cambiano al livello di Interfaccia di codificazione di vari tipi di nanostrutture, www.sciencedaily.com/releases/2007/10/071012095246.htm
Paolo pmanzelli.lre @ gmail.com

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