5 research outputs found
Herzfeld instability versus Mott transition in metal-ammonia solutions
Although most metal-insulator transitions in doped insulators are generally
viewed as Mott transitions, some systems seem to deviate from this scenario.
Alkali metal-ammonia solutions are a brilliant example of that. They reveal a
phase separation in the range of metal concentrations where a metal-insulator
transition occurs. Using a mean spherical approximation for quantum polarizable
fluids, we argue that the origin of the metal-insulator transition in such a
system is likely similar to that proposed by Herzfeld a long time ago, namely,
due to fluctuations of solvated electrons. We also show how the phase
separation may appear: the Herzfeld instability of the insulator occurs at a
concentration for which the metallic phase is also unstable. As a consequence,
the Mott transition cannot occur at low temperatures. The proposed scenario may
provide a new insight into the metal-insulator transition in condensed-matter
physics.Comment: 9 pages, 4 figure
Immobilization Techniques and Integrated Signal Enhancement for POC Nanocolor Microfluidic Devices
Resonance enhanced absorption (REA) nanocolor microfluidic devices are new promising bioassay platforms, which employ nanoparticle- (NP-) protein conjugates for the immunodetection of medically relevant markers in biologic samples such as blood, urine, and saliva. The core component of a REA test device is a PET chip coated with aluminum and SiO2 thin layers, onto which biorecognitive molecules are immobilized. Upon addition of a sample containing the analyte of interest, a NP-protein-analyte complex is formed in the test device that is captured on the REA chip, for example, via streptavidin-biotin interaction. Thereby, a colored symbol is generated, which allows optical readout. Silver enhancement of the bound nanoparticles may be used to increase the sensitivity of the assay. Herein, we demonstrate that adsorptive immobilization via a cationic polymeric interlayer is a competitive and fast technique for the binding of the capture protein streptavidin onto planar SiO2 surfaces such as REA biochips. Moreover, we report the development of a silver enhancement technology that operates even in the presence of high chloride concentrations as may be encountered in biologic samples. The silver enhancement reagents may be integrated into the microfluidic assay platform to be released upon sample addition. Hereby, a highly sensitive one-step assay can be realized