Exploring convective transport in conducting fluids under potent magnetic influences yields essential insights into numerous natural and designed systems. Such insights aid researchers and engineers in making enlightened progressions in their domains. This paper delves into the convective motion in a reactive fluid moving past a vertically perforated plate, governed by intense magnetic forces, the induced magnetic field (IMF) and Hall current. The model integrates factors like thermal radiation and thermo-diffusion (Soret effect). Formative equations for this model, which encapsulate the effects of distinct physical phenomena, are solved analytically. Graphical representations illuminate the influence of vital flow parameters on velocity, temperature, concentration fields, shear stresses and the rates of heat and mass transfer. From the graphs, it’s evident that Hall currents hinder the primary flow but enhance the secondary flow. A rise in radiation and suction parameters leads to a temperature drop. A heightened Soret number appears to magnify concentration distribution throughout the boundary layer. Intensifying suction at the plate diminishes the boundary layer’s thickness, which in turn elevates the heat and mass transfer rate. This physical model finds extensive applicability across sectors, encompassing metallurgy, magnetic fusion, plasma physics, materials fabrication, geothermal phenomena, geochemistry and ionospheric activities.

探索强磁力影响下传导流体的对流传输，可以深入了解许多自然和设计的系统。这些见解有助于研究人员和工程师在各自的领域取得开明的进展。本文深入研究了反应流体流过垂直穿孔板时的对流运动，该运动受强磁力、感应磁场 (IMF) 和霍尔电流的控制。该模型集成了热辐射和热扩散（索雷效应）等因素。该模型的形成方程封装了不同物理现象的影响，并通过解析求解。图形表示阐明了重要流动参数对速度、温度、浓度场、剪切应力以及传热传质速率的影响。从图中可以明显看出，霍尔电流阻碍初级电流，但增强次级电流。辐射和吸力参数的升高导致温度下降。索雷特数的增加似乎会放大整个边界层的浓度分布。加强板处的吸力会减小边界层的厚度，从而提高传热和传质速率。该物理模型在各个领域具有广泛的适用性，包括冶金、磁聚变、等离子体物理学、材料制造、地热现象、地球化学和电离层活动。