Impact of non-uniform heat source/sink and elastic deformation on entropy generation analysis for Cu − Fe₃O₄/ethylene glycol hybrid nanofluid flow past a stretching sheet with an inclined magnetic field, partial slip, and thermal radiations are investigated. Appropriate conversions are utilized for PDE's into ODE's. The dimensionless form is then analytically solved with the help of a hypergeometric function. Performance of significant variables on the hybrid nanofluid flow, heat distribution, skin friction coefficient, Nusselt number, and entropy generation are obtained and discussed with the help of different graphs. Some main results reported in this article reveals that the presents of hybrid nanoparticle, partial slip, inclined magnetic field, and Eckert number improve the more heat conduction in Cu − Fe₃O₄/ethylene glycol hybrid nanofluid and Partial slip, non-uniform heat source, and Eckert numbers are minimized the entropy production. Skin friction coefficient improves through higher values of Cupper nanoparticles and suction parameter. Heat transfer rate is more for higher values of Cupper nanoparticles, non-uniform heat source, partial slip, thermal radiation, and Eckert number.

非均匀热源/汇和弹性变形对Cu - Fe ₃ O ₄熵产生分析的影响研究了具有倾斜磁场、部分滑移和热辐射的/乙二醇混合纳米流体流过拉伸片的情况。对 PDE 到 ODE 进行了适当的转换。然后借助超几何函数解析求解无量纲形式。借助不同的图表，获得并讨论了混合纳米流体流动、热分布、皮肤摩擦系数、努塞尔数和熵产生的重要变量的性能。本文报道的一些主要结果表明，杂化纳米粒子、部分滑移、倾斜磁场和埃克特数的存在改善了Cu - Fe ₃ O _{4 中}的更多热传导/乙二醇混合纳米流体和部分滑移、非均匀热源和埃克特数最小化熵产生。皮肤摩擦系数通过提高铜纳米粒子和吸力参数的值而提高。铜纳米粒子、非均匀热源、部分滑移、热辐射和埃克特数的值越高，传热率越高。