Paving the way for future advancements in superconductivity research through gold ormus studies

IF 2.5 Q2 MULTIDISCIPLINARY SCIENCES Beni-Suef University Journal of Basic and Applied Sciences Pub Date : 2024-11-12 DOI:10.1186/s43088-024-00550-5
Mohamad Hasson, Mohamad Asem Alkourdi, Marwan Al-Raeei
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Abstract

Background

Gold ormus is a type of superconductor that can exhibit superconductivity at temperatures below 1 Kelvin, allowing it to conduct electricity without resistance. While not as widely used as other materials like niobium or lead, gold ormus is valuable for research in superconductivity. Limited studies have been conducted on gold ormus. Numerical simulations of the Ginzburg–Landau theory have yielded important results for both gold ormus.

Results

Class-I and class-II superconducting gold ormus, have been successfully simulated using the Runge–Kutta fourth-order method. Our analysis shows the convergence of our simulation outcomes and emphasizes the importance of considering truncation error and selecting appropriate step sizes for accurate results. The periodic factor of penetration (PFP) for each superconductor has been determined, with class-I superconducting gold ormus having a PFP of 250 nm, class-II superconducting gold ormus having a PFP of 566.2 nm. The relationship between the PFP and the length of the penetration depth has also been revealed.

Conclusions

Our study confirms the accuracy of the Runge–Kutta fourth-order method in simulating superconductors. By analyzing the PFP for different superconducting materials, we have identified trends in penetration depth that contribute to understanding superconductivity. Our simulations provide valuable insights for further research in the field of superconductivity. Adjusting parameters carefully ensures reliable simulations and advances progress in superconductivity research.

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通过金奥姆斯研究为超导研究的未来发展铺平道路
背景金奥尔莫斯是一种超导体,能在低于 1 开尔文的温度下表现出超导性,使其能够无电阻导电。虽然金奥尔莫斯的应用不如铌或铅等其他材料广泛,但它在超导研究方面却很有价值。有关金奥尔莫斯的研究十分有限。结果使用 Runge-Kutta 四阶方法成功模拟了 I 类和 II 类超导金奥姆斯。我们的分析表明了模拟结果的收敛性,并强调了考虑截断误差和选择适当步长以获得准确结果的重要性。我们确定了每种超导体的周期穿透因子(PFP),I 级超导金奥姆斯的 PFP 为 250 nm,II 级超导金奥姆斯的 PFP 为 566.2 nm。我们的研究证实了 Runge-Kutta 四阶方法在模拟超导体方面的准确性。通过分析不同超导材料的 PFP,我们发现了穿透深度的趋势,这有助于理解超导性。我们的模拟为超导领域的进一步研究提供了宝贵的见解。仔细调整参数可确保模拟的可靠性,并推动超导研究的进展。
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期刊介绍: Beni-Suef University Journal of Basic and Applied Sciences (BJBAS) is a peer-reviewed, open-access journal. This journal welcomes submissions of original research, literature reviews, and editorials in its respected fields of fundamental science, applied science (with a particular focus on the fields of applied nanotechnology and biotechnology), medical sciences, pharmaceutical sciences, and engineering. The multidisciplinary aspects of the journal encourage global collaboration between researchers in multiple fields and provide cross-disciplinary dissemination of findings.
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