QZ and FaG supervised this work, helped in the analysis and interpretation of data, and, together with JZ, worked on the drafting and revisions of the NVP-BGJ398 manuscript. TJ and QZ conceived of the study and participated in its design and characterization. JZ participated in the design of the study
and provided analysis instruments. All authors read and approved the final manuscript.”
“Background Metal nanoparticles (NPs) have attracted much research interest due to their selleck screening library unusual chemical and physical properties, such as catalytic activity, novel electronics, optics, and magnetic properties, and they have potential applications in solar cells and biosensors [1–7]. Alloy nanoparticle systems have been found to exhibit optical limiting properties due to surface plasmon resonance and have been used in biodiagnostic applications [8, 9]. Alloy nanoparticles are materials used to tune the position of surface plasmon resonance, and thus help to produce materials for use in nonlinear optical applications [10–14]. Au-Cu alloy system is a completely dissoluble alloy. The position of surface plasmon resonance see more for Au NPs is about 520 nm. The
position of surface plasmon resonance for Cu NPs is 570 ~ 580 nm [15]. At low temperatures, Au, Au3Cu, AuCu, AuCu3, and Cu exist and order easily in Au-Cu alloys system. The prediction of the optical properties of such alloy systems is desirable if they are to be used in the design of optical devices. However, the optical properties of alloy systems are difficult to predict because of the random mixing of materials. The quasi-chemical method is a statistical approach for predicting the short-range-order of Au-Cu alloys system according to Gibbs free energy. While the optical properties of Au-Cu alloys can be computed by the quasi-chemical model based on the energy potential between the electric field and induced dipole, few works have attempted to do this. In this study, we thus simulate the optical
properties of Au and Cu using a quasi-chemical model, based on the energy potential between the electric field and induced dipole. We then used this quasi-chemical SPTLC1 method to modify the statistics for the short-range-order of Au-Cu alloy system. Then the optical properties are simulated by combining the Gibbs free energy and electric potential energy. The light extinction of nanoparticles is calculated by using Mie theory. The results show that the model is suitable for predicting the position of surface plasmon resonance peaks. Methods Model Regular solution Au-Cu alloy system refers to a solid solution. Properties of a regular solution are best examined based on the concept of excess function [16].