4 research outputs found
Stopping of relativistic projectiles in two-component plasmas
Relativistic and correlation contributions to the polarizational energy losses of heavy
projectiles moving in dense two-component plasmas are analyzed within the method of moments
that allows one to reconstruct the Lindhard loss function from its three independently known power
frequency moments. The techniques employed result in a thorough separation of the relativistic
and correlation corrections to the classical asymptotic form for the polarizational losses obtained
by Bethe and Larkin. The above corrections are studied numerically at different values of plasma
parameters to show that the relativistic contribution enhances only slightly the corresponding
value of the stopping power.This research was financially supported by the Spanish Ministerio de Educacion y Ciencia Project No. ENE2010-21116-C02-02 and by the Science Committee of the Ministry of Education and Sciences of the Republic of Kazakhstan under Grants No. 1128/GF, 1129/GF and 1099/GF. IMT acknowledges the hospitality of the al-Farabi Kazakh National University.Arkhipov, YV.; Ashikbayeva, AB.; Askaruly, A.; Davletov, AE.; Tkachenko Gorski, IM. (2013). Stopping of relativistic projectiles in two-component plasmas. EPL. 104(3):35003-p1-35003-p6. https://doi.org/10.1209/0295-5075/104/35003S35003-p135003-p6104
Distributed 2D temperature sensing during nanoparticles assisted laser ablation by means of high-scattering fiber sensors
The high demand in effective and minimally invasive cancer treatments, namely thermal ablation, leads to the demand for real-time multi-dimensional thermometry to evaluate the treatment effectiveness, which can be also assisted by the use of nanoparticles. We report the results of 20-nm gold and magnetic iron oxide nanoparticles-assisted laser ablation on a porcine liver phantom. The experimental set-up consisting of high-scattering nanoparticle-doped fibers was operated by means of a scattering–level multiplexing arrangement and interrogated via optical backscattered reflectometry, together with a solid-state laser diode operating at 980 nm. The multiplexed 2-dimensional fiber arrangement based on nanoparticle-doped fibers allowed an accurate superficial thermal map detected in real-time
Development of an optical biosensor for diagnosis of tuberculosis
Tuberculosis (TB) is an airborne disease caused by Mycobacterium tuberculosis. TB is the leading cause of morbidity and mortality in the developing world. Early and accurate diagnosis of TB would greatly enhance the treatment and prevention of the disease. Current methods of TB detection suffer from various limitations such as low specificity and sensitivity, being too complex and expensive. In the present work, we aim to develop an optical biosensor based on DNA aptamers, quantum dot (QD) crystals and magnetic nanoparticles (MNP) for detection of MPT64 protein, specific to M.tuberculosis. Aptamer-MNP conjugate is used for separation of MPT64 from solution, while aptamer-QD is used to detect its presence afterwards using fluorometer