Application of infrared vision system for potato thermal control

The article proposes a solution to the problem of determining the values of potato tubers tissue thermophysical characteristics. The solution of this problem makes it possible to calculate the optimal regime parameters of potato quality active thermal control, which can be used for automatic sorting. In order to solve this problem, we propose a non-contact non-destructive control method based on a pulsed laser heating of a potato tuber flat surface area and subsequent use of time integral characteristics of temperature and heat flow, as well as a measuring device developed on the basis of physical and mathematical models of the method. The method was used by the authors to determine the thermal conductivity, heat capacity and coefficient of thermal diffusivity of different quality potato tissues: both healthy and affected by phyto-diseases. The studies have shown that the thermal conductivity of plant tissues depends on the presence of structural disturbances in them as a result of phyto-diseases. This fact confirms the possibility of using thermal non-destructive control of potatoes tissues provided the correct choice of power and the duration of the thermal effect on the object of control

Discrete solitons in coupled active lasing cavities

We examine the existence and stability of discrete spatial solitons in coupled nonlinear lasing cavities (waveguide resonators), addressing the case of active defocusing media, where the gain exceeds damping in the low-amplitude limit. A new family of stable localized structures is found: these are bright and grey cavity solitons representing the connections between homogeneous and inhomogeneous states. Solitons of this type can be controlled by the discrete diffraction and are stable when the bistability of homogenous states is absent.Comment: 3 pages, 3 figures, accepted to Optics Letters (October 2012

Sterically stabilized lock and key colloids: A self-consistent field theory study

A self-consistent field theory study of lock and key type interactions between sterically stabilized colloids in polymer solution is performed. Both the key particle and the lock cavity are assumed to have cylindrical shape, and their surfaces are uniformly grafted with polymer chains. The lock-key potential of mean force is computed for various model parameters, such as length of free and grafted chains, lock and key size matching, free chain volume fraction, grafting density, and various enthalpic interactions present in the system. The lock-key interaction is found to be highly tunable, which is important in the rapidly developing field of particle self-assembly

The challenges of creating a universal influenza vaccine

The lack of population immunity to the periodically emerging pandemic influenza strains makes influenza infection especially dangerous. The fragmented nature of the influenza virus genome contributes to the formation of influenza virus reassortants containing genomic fragments from different strains. This mechanism is the main reason for the natural influenza virus antigenic diversity as well as for the occurrence of influenza pandemics. Vaccination is the best measure to prevent the spread of influenza infection, but the efficacy of existing vaccines is not sufficient, especially for the elderly and small children. Specific immunity, developed after disease or immunization, poorly protects against infection by influenza viruses of another subtype. In this regard, there is an urgent need for a more effective universal influenza vaccine that provides a long-lasting broad cross-protective immunity, and is able to protect against influenza A and B viruses of all known subtypes. The basic approaches to as well as challenges of creating such a vaccine are discussed in this review.The lack of population immunity to the periodically emerging pandemic influenza strains makes influenza infection especially dangerous. The fragmented nature of the influenza virus genome contributes to the formation of influenza virus reassortants containing genomic fragments from different strains. This mechanism is the main reason for the natural influenza virus antigenic diversity as well as for the occurrence of influenza pandemics. Vaccination is the best measure to prevent the spread of influenza infection, but the efficacy of existing vaccines is not sufficient, especially for the elderly and small children. Specific immunity, developed after disease or immunization, poorly protects against infection by influenza viruses of another subtype. In this regard, there is an urgent need for a more effective universal influenza vaccine that provides a long-lasting broad cross-protective immunity, and is able to protect against influenza A and B viruses of all known subtypes. The basic approaches to as well as challenges of creating such a vaccine are discussed in this review

Star Polymers Confined in a Nanoslit: A Simulation Test of Scaling and Self-Consistent Field Theories

The free energy cost of confining a star polymer where $f$ flexible polymer chains containing $N$ monomeric units are tethered to a central unit in a slit with two parallel repulsive walls a distance $D$ apart is considered, for good solvent conditions. Also the parallel and perpendicular components of the gyration radius of the star polymer, and the monomer density profile across the slit are obtained. Theoretical descriptions via Flory theory and scaling treatments are outlined, and compared to numerical self-consistent field calculations (applying the Scheutjens-Fleer lattice theory) and to Molecular Dynamics results for a bead-spring model. It is shown that Flory theory and self-consistent field (SCF) theory yield the correct scaling of the parallel linear dimension of the star with $N$, $f$ and $D$, but cannot be used for estimating the free energy cost reliably. We demonstrate that the same problem occurs already for the confinement of chains in cylindrical tubes. We also briefly discuss the problem of a free or grafted star polymer interacting with a single wall, and show that the dependence of confining force on the functionality of the star is different for a star confined in a nanoslit and a star interacting with a single wall, which is due to the absence of a symmetry plane in the latter case.Comment: 15 pages, 9 figures, LaTeX, to appear in Soft Matte

Effect of Matter Motion and Polarization in Neutrino Flavour Oscillations

The Lorentz invariant formalism for description of neutrino flavor oscillation in moving and polarized matter is developed. It is shown that the neutrino effective potential, which determines the effective mass difference between neutrinos in matter can be sufficiently changed by relativistic motion of matter. In the case of matter motion parallel to neutrino propagation, matter effects in neutrino flavor oscillations are suppressed. In the case of relativistic motion of matter in the opposite direction sufficient increase of effects of matter in neutrino oscillations is predicted. The dependence of the matter term in neutrino effective potential on the values and correlations of the three vectors, the neutrino and matter speeds and matter polarization, is discussed in details