In this paper, we have studied the effect of Born-Infeld electrodynamics in holographic p-wave superconductors with massive vector condensation. We have analysed this model in the probe limit using a variational method known as the Stürm-Liouville eigenvalue approach. For this p-wave holographic superconductor model, we have calculated the critical temperature T c as well as the value of the condensation operator for two different choices of m 2 . We have also pointed out the similarties and dissimilarities between this model for m 2 = 0 and p-wave holographic superconductor model constructed out of Einstein-Yang-Mills theory. We have then computed the conductivity of these holographic superconductor models using a self-consistent approach and have shown that the DC conductivity diverges.
In this paper we have investigated, in the probe limit, s-wave holographic superconductors in rotating AdS 3+1 spacetime using the matching method as well as the Stürm-Liouville eigenvalue approach. We have calculated the critical temperature using the matching technique in such a setting and our results are in agreement with previously reported results obtained using the Stürm-Liouville approach. We have then obtained the condensation operators using both analytical methods. The results obtained by both these techniques share the same features as found numerically. We observe that the rotation parameter of the black hole affects the critical temperature and the condensation operator in a non-trivial way.
In this work, we have analytically computed the holographic transport coefficients for $$(2+1)$$
(
2
+
1
)
-dimensional strongly coupled field theories, placed in a spatially modulated chemical potential along the x-direction, in the presence of Born–Infeld electrodynamics. We have obtained these coefficients in terms of the black hole horizon data only. We have observed that the Born–Infeld parameter affects these coefficients in a non-trivial way. We have, then, used these results to further study a holographic model for ultra-clean graphene near Dirac point. This is a two current model with an inhomogeneous holographic lattice.
Background: Cervical cancer is third most common cancer in women worldwide and fourth leading cause of cancer deaths in women.in India it’s a leading cancer in women responsible for more than 74,000 deaths per year. To assess knowledge, attitude towards HPV infection and HPV vaccination. Methods: Cross sectional study which was conducted at Mayo institute of medical sciences, Barabanki in January 2022. 150 medical students aged between 18-23 years were included in study. Results: The survey sample consisted of 150 medical students aged between 18-23 years with a mean age of 20.56±1.67 years. Around 22 (14.66%) of responders achieved a total knowledge score of 15 or higher, meaning that they correctly answered more than 15 out of 20 knowledge questions on HPV.Conclusions: There is an urgent need for educational Intervention both formal and informal, not only for girls and boys but also for parents to change their attitude towards HPV vaccination.
In this work, we have analytically computed the holographic transport coefficients for (2 + 1)dimensional strongly coupled field theories, placed in a spatially modulated chemical potential along the x-direction, in the presence of Born-Infeld electrodynamics. We have obtained these coefficients in terms of the black hole horizon data only. We have observed that the Born-Infeld parameter affects these coefficients in a non-trivial way. We have, then, used these results to further study a holographic model for ultra-clean graphene near Dirac point. This is a two current model with an inhomogeneous holographic lattice.
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