Reliability Computation of Kinetic Energy Based Shannon Entropy for Tritium Plasma Graphene Interactions

Yıl 2025, Cilt: 38 Sayı: 1, 5 - 12, 29.06.2025

Alper Pahsa

Öz

When selecting reactor building elements, it is important to consider the structural reliability of Tokamak fusion reactors. Fusion reactions generate substantial heat and energy, which can alter the structure of reactor walls, thereby diminishing the efficiency of energy production in reactors. The primary materials employed for walls in fusion reactors include tungsten, beryllium, and graphene, owing to their high melting points. This study looks at how tritium plasma ions, which have energies between 5 and 35 keV, affect graphene wall surfaces using molecular dynamics simulations, and also assesses the system's Kinetic Energy using Shannon entropy modeling. We use this information to compute the Weibull distribution's reliability prediction for graphene structures.

Anahtar Kelimeler

Material Reliability of Graphene with Kinetic Energy , PMI with Tritium with Graphene , Tokamak reactor graphene material reliability , Tritium based fusion reactor material reliability , Fusion reactor kinetic energy based reliability

Trityum Plazma Grafen Etkileşimleri için Kinetik Enerji Tabanlı Shannon Entropisinin Güvenilirlik Hesaplaması

Öz

Reaktör yapı elemanlarını seçerken, Tokamak füzyon reaktörlerinin yapısal güvenilirliğini göz önünde bulundurmak önemlidir. Füzyon reaksiyonları, reaktör duvarlarının yapısını değiştirebilen ve böylece reaktörlerdeki enerji üretiminin verimliliğini azaltabilen önemli miktarda ısı ve enerji üretir. Füzyon reaktörlerinde duvarlar için kullanılan birincil malzemeler arasında yüksek erime noktaları nedeniyle tungsten, berilyum ve grafen bulunur. Bu çalışma, 5 ila 35 keV arasında enerjilere sahip olan trityum plazma iyonlarının moleküler dinamik simülasyonları kullanarak grafen duvar yüzeylerini nasıl etkilediğini inceler ve ayrıca Shannon entropi modellemesini kullanarak sistemin Kinetik Enerjisini değerlendirir. Bu bilgileri, grafen yapıları için Weibull dağılımının güvenilirlik tahminini hesaplamak için kullanırız.

Anahtar Kelimeler

Kinetik Enerjili Grafenin Malzeme Güvenilirliği , Grafenli Trityumlu PMI , Tokamak reaktör grafen malzeme güvenilirliği , Trityum bazlı füzyon reaktörü malzeme güvenilirliği , Füzyon reaktörü kinetik enerji bazlı güvenilirlik

Kaynakça

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