The International Thermonuclear Experimental Reactor (ITER) tokamak can generate fusion energy in an acceptable method. In this study, the particle and energy equations were developed for \({\text{T}}\left( {{\text{D}},n} \right){}^{4}{\text{He}}\), \({\text{D}}\left( {{\text{D}},n} \right){}^{3}{\text{He}}\), \({\text{D}}\left( {{\text{D}},p} \right){\text{T}}\), and \({}^{3}{\text{He}}\left( {{\text{D}},p} \right){}^{4}{\text{He}}\) fusion reactions and optimum conditions were determined to achieve the maximum gain using differing mixtures of fuel. Also, the particle and energy equations were solved using the zero-dimensional model, and the ITER90H-P plasma parameters were calculated by the numerical methods. The possibility regarding the presence of impurities was ignored in all our calculations.

国际热核实验堆（ITER）托卡马克可以通过一种可接受的方法产生聚变能。在这项研究中，为\（{\ text {T}} \ left（{{\ text {D}}，n} \ right）{} ^ {4} {\ text {He} } \），  \（{\ text {D}} \ left（{{\ text {D}}，n} \ right）{} ^ {3} {\ text {He}} \\），  \（{ text {D}} \ left（{{\ text {D}}，p} \ right）{\ text {T}} \）和\（{} ^ {3} {\ text {He}} \ left （{{\ text {D}}，p} \ right）{} ^ {4} {\ text {He}} \）确定了融合反应和最佳条件，以使用不同的燃料混合物获得最大增益。此外，使用零维模型求解了粒子和能量方程，并通过数值方法计算了ITER90H-P等离子体参数。在我们所有的计算中，都忽略了存在杂质的可能性。