In current years, storage of energy is a challenging task for the scientists and researchers. So, they are interested to develop some extra ordinary techniques of energy storage. Thus, our main theme here is to focus on the latent heat energy (melting heat) which is more economical and sustainable. Transportation of melting heat in quadratic stratified Jeffrey fluid flow in the vicinity of stagnation point is scrutinized. The flow is deformed by linear stretchable sheet. Characteristics of heat transportation are scrutinized through viscous dissipation and heat generation or absorption. Constant magnetic field is implemented to electrically conducting fluid in vertical direction. The arising governing equations are converted in the non-dimensional state through suitable transformations. Homotopic technique is utilized for simulation of solutions. Graphical behavior of velocity and temperature fields is investigated corresponding to relevant parameters. As a conclusion, higher amount of energy can be achieved as melting phenomenon enhances, and also results in low temperature. Further, dominant stratification decays the temperature field. Current study will play key role in industrial liquids like polymer solutions to make high quality fiberglass, paints, silicone heat valves etc. This study will also deliberate efficiently for the storage of energy through phase change procedure i.e., melting phenomenon.

中文翻译：

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分层杰弗里流体流中的熔化热量在生热和磁场中的传输

近年来，能量储存对于科学家和研究人员来说是一项具有挑战性的任务。因此，他们有兴趣开发一些非常普通的能量存储技术。因此，我们这里的主题是关注更经济和可持续的潜热能（熔化热）。研究了驻点附近二次分层 Jeffrey 流体流中熔化热的传输。通过线性可拉伸片材使流动变形。通过粘性耗散和热量产生或吸收来仔细检查热传输的特性。对垂直方向的导电流体施加恒定磁场。通过适当的变换将产生的控制方程转换为无量纲状态。同伦技术用于解决方案的模拟。根据相关参数研究速度场和温度场的图形行为。综上所述，随着熔化现象的增强，可以获得更高的能量，并且也会导致低温。此外，主要分层会衰减温度场。目前的研究将在工业液体中发挥关键作用，例如用于制造高质量玻璃纤维、油漆、硅树脂热阀等的聚合物溶液。这项研究还将有效地探讨通过相变过程（即熔化现象）储存能量。