Ieva Baleviciute

Study of antibody/antigen binding kinetics by total internal reflection ellipsometry

Total internal reflection ellipsometry (TIRE) has been applied for the investigation of (i) kinetics of biosensing layer formation, which was based on the immobilization of fragmented and intact antibodies, and (ii) kinetics of antigen interaction with the immobilized antibodies. It has been demonstrated that ellipsometric parameter Δ(t) showed much higher sensitivity at the initial phase of Au-protein and protein-protein interaction, while the parameter Ψ(t) was more sensitive when the steady-state conditions were established. A new method, which taking into consideration this feature and nonlinear change of Δ(t) and Ψ(t) parameters during various stages of biological layer formation process, was used for the calculation of antibody and antigen adsorption/interaction kinetics. The obtained results were analyzed using a model, which took into account partial reversibility during the formation of both antibody and antigen based monolayers. It was shown that the immobilization rate of antibody during the preparation of the sensing layer was similar for the formation of both intact and fragmented antibody based layers; however, the residence time was 25 times longer for intact antibody based layer formation in comparison to that of fragmented antibody based layer formation. On the contrary, residence time of antigen interaction with immobilized antibodies was about 8 times longer for the sensor based on fragmented antibodies. Moreover, it has been determined that the structural differences of immobilized antibodies (fragmented or intact) significantly influence antibody-antigen interaction rate, the major difference being in the residence time of antigen interaction with both types of immobilized antibodies.

The influence of localized plasmons on the optical properties of Au/ZnO nanostructures

Optical and structural experiments have been carried out on Si/ZnO thin films modified with ultra-thin gold layers of different thicknesses. ZnO was produced via Atomic Layer Deposition (ALD) and Au via Physical Vapor Deposition (sputtering). The structural properties of nanostructures were studied by XRD and AFM. Optical characterization was performed by absorbance, photoluminescence (PL) and spectroscopic ellipsometry (SE). A transition from cluster-to-thin films with the increase of Au thickness has been revealed from an analysis of optical and structural parameters. The analysis of optical features of the system has shown that slight changes of the localized plasmon absorption peaks in spectra make a significant contribution to complex refractive index of gold film and, as a result, leads to a strong enhancement of UV PL peak in the ZnO layer. The mechanism of the tailoring of ZnO optical features changes by varying the Au layer thickness was discussed. Our studies have shown that through the changes of structural properties of thin gold layer between the Si substrate and the ZnO film, we can tune the optical dispersion of each layer and hence the control of ZnO PL spectra enhancement and quenching in UV-Vis wavelengths region is possible. In order to apply the hybrid structure under consideration in various optical applications, such as LED, the dispersion of the complex refractive index of the components should be optimized taking into account a particular target.

Tunable Bloch surface waves in anisotropic photonic crystals based on lithium niobate thin films

We present an original type of one-dimensional photonic crystal that includes one anisotropic layer made of a lithium niobate thin film. We demonstrate the versatility of such a device sustaining different Bloch surface waves (BSWs), depending on the orientation of the incident wave. By varying the orientation of the illumination of the multilayer, we measured an angle variation of 7° between the BSWs corresponding to the extraordinary and the ordinary index of the lithium niobate thin film. The potential of such a platform opens the way to novel tunable and active planar optics based on the electro- and thermo-optical properties of lithium niobate.