Quantifying the optical and thermoplasmonic properties of some bimetallic alloy nanospheres

Abstract

The bimetallic alloy NPs are ideal objects for a variety of applications like catalysis, nanofluidics, thermo-voltaic and bio-imaging due to their peculiar and adaptable optical response in UV–visible-NIR region of optical spectra. The heating effect of bimetallic alloys involves surface plasmon resonance (SPR) and takes place when the material is illuminated by light. Instead of pure and alloy NPs of Au & Ag, the opto-thermal properties of Au-Cu, Au-Al, Ag-Cu and Ag-Al bimetallic alloy nanospheres for their different compositions with a size radius of 10 nm to 50 nm immersed in water (n = 1.33) using the Mie theory approach are investigated theoretically. In order to determine the heat generation and the temperature distribution by plasmonic nanoparticles in the host medium (water in this study) we have solved the heat transfer equation analytically for steady-state conditions. The great utility of these bimetallic alloy nanoparticles for thermoplasmonic investigation is accompanied with a large extent of SPR tunability which is rarely found in their pure monometallic counterpart. The SPR of Aux-Cu1-x (214 nm to 548 nm), Aux-Al1-x (213 nm to 493 nm), Agx-Cu1-x (214 nm to 539 nm), and Agx-Al1-x (214 nm to 381 nm) bimetallic alloys with compositions of x = 0.25,0.50 and 0.75 have been observed for different size of the nanospheres. Thus, we anticipate that the results of this work will evoke the curiosity of researchers towards the use of bimetallic alloys in thermoplasmonic applications.