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All Journal Journal of Physics: Theories and Applications Spektra: Jurnal Fisika dan Aplikasinya Makara Journal of Science
Yadav, Kishori
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Aerospace Engineering Education Electrical & Electronics Engineering Energy Materials Science & Nanotechnology Physics

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Temperature Influence on the Optical Properties, Attenuation Coefficient, and Total Molecular Cross Section of Dhunge Dhara Drinking Water Dhobi, Saddam Husain; Koirala, Bibek; Yadav, Kishori; Nakarmi, Jeevan Jyoti; Gupta, Suresh Prasad; Das, Santosh Kumar; Shah, Arun Kumar; Paudel, Kuldip; Dahal, Kushal; Sah, Ram Lal
Makara Journal of Science Vol. 26, No. 4
Publisher : UI Scholars Hub

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Abstract

This work aims to measure the different parameters of Dhunge Dhara water (DDW) such as absorbance, transmittance, mass attenuation coefficient (MAC), and molecular cross section (MCS) and experimentally compare the obtained values with those of pure water (PW) at various temperatures (5 °C to 90 °C) using a theremino spectrometer. Observation shows that the parameters vary with temperature and wavelength. The transmittance of DDW ranges from 18% to 85% and absorbance of the same ranges from 0.09 Au to 0.7 Au. Meanwhile, the transmittance of PW ranges from 40% to 98% and the absorbance of the same ranges from 0.09 Au to 0.39 Au. The MAC of PW ranges from 0.02 cm2g−1 to 0.6 cm2g−1, and that for DDW ranges from 0.2 cm2g−1 to 1.1 cm2g−1 at 30 °C. The MCS of PW ranges from to , and that of DDW ranges from to at 30 °C. In conclusion, DDW has an extremely high amount of impurities and total dissolved solids and is recommended to be filtered prior to use (drinking and cooking)
Pair Correlation Influence on Superconductors Josephson Penetration Depth Poudel, Yadhav; Gupta, Suresh Prasad; Shrestha, Narayan Babu; Yadav, Kishori; Dhobi, Saddam Husain
Spektra: Jurnal Fisika dan Aplikasinya Vol. 9 No. 1 (2024): SPEKTRA: Jurnal Fisika dan Aplikasinya, Volume 9 Issue 1, April 2024
Publisher : Program Studi Fisika Universitas Negeri Jakarta

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.21009/SPEKTRA.091.02

Abstract

The Josephson penetration depth is an essential characteristic of Josephson junctions, serving a role akin to the London penetration depth in bulk superconductors. It originates from the substantial self-magnetic field generated by a strong Josephson supercurrent, influencing the distribution of the gauge invariant phase difference across the junction. This study delves into the intricate relationship between cooper pair correlation and critical temperature in superconductors. To study relationships authors develop theoretical method and observed that critical temperature exhibits a noteworthy decrease with an increase in cooper pair correlation. Specifically, as the level of coherence among electron pairs rises, the material's capacity to maintain the superconducting state at elevated temperatures is enhanced, resulting in an elevated critical temperature. Conversely, regions characterized by lower pair correlation demonstrate a sharp reduction in critical temperature, indicating their heightened susceptibility to changes in correlation levels. This sensitivity is particularly pronounced across junction and penetration depth where cooper pair correlation is diminished. Furthermore, the study reveals an exponential decay trend in critical temperature concerning cooper pair correlation, underscoring the pivotal role played by pair correlation in the superconducting state. Even slight alterations in pair correlation have a substantial impact on the material's ability to exhibit superconductivity. These findings provide valuable insights for the tailored design and optimization of superconducting materials for specific applications. By leveraging the understanding gained from this research, it becomes possible to engineer materials with enhanced superconducting properties. This study not only advances our fundamental comprehension of superconductivity but also offers practical implications for a diverse range of technological applications.
Phase Dynamics in 3D Superconductors: Analysis Using the Sine-Gordon Khadka, Kiran; Dhobi, Saddam Husain; Yadav, Kishori
Spektra: Jurnal Fisika dan Aplikasinya Vol. 9 No. 3 (2024): SPEKTRA: Jurnal Fisika dan Aplikasinya, Volume 9 Issue 3, December 2024
Publisher : Program Studi Fisika Universitas Negeri Jakarta

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.21009/SPEKTRA.093.02

Abstract

This study investigates the phase dynamics of superconducting states in 3D superconductors using the sine-Gordon equation, with a focus on the interplay between the London penetration depth (LPD) and coherence length ( ). The research employs a combination of analytical modeling and simulation techniques to explore how variations in LPD influence phase behavior across different coherence lengths in the developed model. At a critical coherence length of  = 2 Å, the LPD decreases from 150 nm to 120 nm as the nanoparticle spacing increases from 5 nm to 10 nm, attributed to reduced interactions between superconducting states. Conversely, at  = 1 Å, quantum confinement effects lead to non-linear LPD behavior, with an initial decrease from 180 nm to 160 nm followed by an increase to 200 nm as nanoparticle spacing changes. In 3D superconductors, phase evolution is characterized by distinct waveforms—square, rectangular, and mixed—corresponding to LPD values between 100 nm and 200 nm, with phase shifts ranging from 1° to 20°. Smaller phase shifts (1°) produce higher-frequency oscillations with amplitudes up to 0.2, while larger shifts (20°) generate broader, less intense waveforms. These findings underscore the critical role of LPD in determining superconducting properties, offering valuable insights for the design and optimization of superconducting devices to enhance performance and efficiency.
Thermal and nonthermal behaviors of electron–H2O in presence of laser field Bohara, Harish; Dhobi, Saddam Husain; Yadav, Kishori; Das, Santosh Kumar
Journal of Physics: Theories and Applications Vol 9, No 2 (2025): Journal of Physics: Theories and Applications
Publisher : Universitas Sebelas Maret

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.20961/jphystheor-appl.v9i2.108563

Abstract

Electron–water (H2O) molecule scattering under the influence of laser and thermal fields is a fundamental process in atomic and molecular physics, with significant implications for radiation chemistry, photonics, and quantum control. The interaction of electrons with H2O in the presence of an external laser field modifies the scattering dynamics by introducing additional energy and momentum channels, while thermal effects influence electron oscillations and resonance behavior. Understanding these combined effects is essential for accurately predicting differential cross-sections (DCS) and controlling scattering probabilities in experimental and applied settings, including laser-assisted spectroscopy, nanostructure interactions, and thermally tunable quantum devices. The aim of this work is to study the nature of electron-H2O in presence of laser and heat using scattering technique. For this we desing a theorical model which include thermal wave function, potential of water molecules, S-matrix, Besel function and Kroll-Watson approximation for DCS. The developed model was computed used temperature (293–300 K), scattering angles (0.057°–57°), momentum transfer (0.3–1 eV), distance separation (1–1.5 Å), field strength (0.3–5 a.u.), relative field strength (0.5–2.5 a.u.), electron conductivity (0.1–15 a.u.), polarization (linear, circular, elliptical), and Bessel function order. The computed result shows thermal effects enhance DCS compared to non-thermal conditions (0 K), with resonances observed at specific energies (0.25–1 eV). Higher scattering angles produce larger DCS, while lower angles generate sharper resonances with damping-like behavior. Elliptical polarization yields the highest DCS, followed by circular and linear. Distance separation and electron conductivity modulate constructive and destructive interference patterns, whereas higher-order Bessel functions stabilize DCS, indicating equilibrium between electrostatic interaction and particle rest energy. These findings suggest that controlled temperature and field parameters can manipulate scattering probability in thermal systems.
Co-Authors Bohara, Harish Dahal, Kushal Das, Santosh Kumar Dhobi, Saddam Husain Gupta, Suresh Prasad Khadka, Kiran Koirala, Bibek Nakarmi, Jeevan Jyoti Paudel, Kuldip Poudel, Yadhav Sah, Ram Lal Shah, Arun Kumar Shrestha, Narayan Babu