آہ پی پی پی
کہتا ہے کون ختم ہوئی کربلا کی جنگ
ہم لڑ رہے ہیں آج بھی فوجِ یزید سے
آہ! پی پی پی
زخموں ،کوڑوں ،جیلوں ،پھانسیوں ،ڈنڈوں ،برچھیوں اور بھالوں کے وار سہنے کا ایک لامتناہی سلسلہ قیادت سے لے کر ایک ورکر ایک جیالے تک قربانیوں کی نہ ختم ہو نے والی داستان ۔
Medical journals are a credible source of disseminating research and innovations, and Launching a medical journal is a challenging task. Many medical science journals are establishing a platform to publish quality research but still the task is tough and requires perseverance and hard work. Shalamar Medical and Dental College (SMDC) Lahore, strives to promote a culture of research. As part of this initiative, SMDC had launched ‘Medical Journal of Sakina Begum Institute’, but publication of the second volume was delayed due to the pandemic. Moreover, the name of the journal had to be changed due to some administrative issues. However, the committed editorial team was successful in bringing efforts for the latest issue to fruition.
Trace rare gas optical emission spectroscopy (TRG-OES) is carried out to investigate the excitation temperature, relative densities of active species (N, N2+) and nitrogen dissociation in inductively coupled helium admixed nitrogen plasma for different rf power (50, 100, 150 W), pressure (0.2 – 0.5 mbar) and helium percentage (10-90 %) using Ar as an actinometer (4 %). The excitation temperature is obtained from Boltzmann plot method using emission intensity of several argon lines. The dissociation of nitrogen has been investigated by both the actinometry method and the ratio of the atomic nitrogen line emission intensity at (746.83 nm) to the vibrational band (0-0) of the N2 second positive system at 337.1 nm. The excitation temperature increases with the increase in power and helium percentage and decreases with increase in fill pressure. The nitrogen dissociation as well as the relative densities of [ ] and [ ] increases with the increase in helium percentage. Optical emission spectroscopy and Langmuir probe are used to diagnose the low pressure inductively coupled Ar-N2 plasmas for different discharge parameters such as rf power (10-100W), filling pressure (0.02-0.4 mbar) and argon content (5-95%) in nitrogen discharge. Both diagnostic tools are used to obtain the plasma parameters including the excitation temperature, the density of active species in ground electronic state, dissociation fraction, electron temperature, electron number density and electron energy probability functions (EEPFs) in Ar-N2 plasmas. It is noticed that the actinometry is an efficient and reliable technique to calculate the densities of nitrogen species. It is also observed that the active species generation, dissociation fraction and electron temperature significantly depend on discharge parameters and may be used to optimize the plasma reactor. Mixture of single walled carbon nanotubes (SWCNTs) and multi walled carbon nanotubes (MWCNTs) are treated for different treatment time (0-120min) at optimum discharge conditions. Changes induced in the elemental composition, surface morphology, crystallographic structure, and structural disorder in the plasma irradiated CNTs are analyzed by EDX, FTIR, SEM, XRD and Raman spectroscopy, respectively. Ar-N2 mixture plasma treatment of CNTs leads to significantly increase the electrical conductivity, modify the microstructure and induce structural disorder and a transition of crystalline phase from well crystalline to an amorphous structure.