Laser-Induced Breakdown Spectroscopy is a promising spectroscopic technique with a vast spectrum of applications in fields concerned with identification and detection of elements. But it faces some limitations due to self-absorption, noise due to matrix effect and line broadening resulting in low emission signal. This research proposes LIBS signal enhancement by incorporation of metal nanoparticles (Cu, Mg, Au) on Al surface and compares their effect. The successful optical emissions enhancement is achieved as the emission intensities of Al-and Nalines of three coated samples are compared with those of uncoated Al. The Electron Temperature has been evaluated by Boltzmann plot and an increase in Electron Temperature has been observed with the incorporation of nanoparticles to the aluminum surface as compared to the untreated aluminum, due to more plasma emissions. The Electron Number Density of the aluminum plasma did not have much effect with the incorporation of Nanoparticles. The Local Thermal Equilibrium condition has been satisfied and checked by Mc Whirter's Criterion. The incorporation of metalnanoparticles can be declared as an effective method not only for LIBS signal enhancement but also better detection of trace elements which were not observed without the use of Nanoparticles.
Laser-Induced Breakdown Spectroscopy is a promising spectroscopic technique with a vast spectrum of applications in fields concerned with identification and detection of elements. But it faces some limitations due to self-absorption, noise due to matrix effect and line broadening resulting in low emission signal. This research proposes LIBS signal enhancement by incorporation of metal nanoparticles (Cu, Mg, Au) on Al surface and compares their effect. The successful optical emissions enhancement is achieved as the emission intensities of Al- and Na- lines of three coated samples are compared with those of uncoated Al. The Electron Temperature has been evaluated by Boltzmann plot and an increase in Electron Temperature has been observed with the incorporation of nanoparticles to the aluminum surface as compared to the untreated aluminum, due to more plasma emissions. The Electron Number Density of the aluminum plasma did not have much effect with the incorporation of Nanoparticles. The Local Thermal Equilibrium condition has been satisfied and checked by Mc Whirter’s Criterion. The incorporation of metal nanoparticles can be declared as an effective method not only for LIBS signal enhancement but also better detection of trace elements which were not observed without the use of Nanoparticles.
Cascabela thevetia (Thevetia peruviana) giant milkweed, is known for its pharmacological importance for centuries. The chemical constituents of Thevetia peruviana leaves are amyrin, amyrin acetate, ?-sitosterol, urosolic acid, cardenolides, calotropin. The anti-arthritic activity of Thevetia peruviana leaves in comparison with Diclofenac was evaluated through in-vitro studies. In-vitro studies revealed anti-arthritic effects (p< 0.05) of crude extracts of aqueous, methanolic, ethanolic and chloroform of Thevetia peruviana leaves on bovine serum albumin as evident for % inhibition protein denaturation. Different extracts of Thevetia peruviana leaves were found to possess in-vitro antiarthritic activity against BSA, using diclofenac as the reference standard which are Dose-dependent (100µg/ml, 250µg/ml, 500µg/ml). Chloroform extract has shown better activity comparing the other extracts.
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