On entropy generation effectiveness in flow of power law fluid with cubic autocatalytic chemical reaction

被引:0
作者
M. Faisal Javed
M. Waqas
Niaz Bahadur Khan
Riaz Muhammad
Muftooh Ur Rehman
M. Ijaz Khan
Sajjad Wali Khan
M. Tahir Hassan
机构
[1] Sarhad University of Science and Information Technology,Department of Civil Engineering
[2] National University of Sciences and Technology,Department of Basic Sciences and Humanities, College of Electrical and Mechanical Engineering
[3] National University of Science and Technology,School of Mechanical and Manufacturing Engineering
[4] CECOS University of IT and Emerging Sciences,Department of Mechanical Engineering
[5] Quaid-I-Azam University 45320,Department of Mathematics
[6] UET Peshawar,Civil Engineering Department
[7] Bahauddin Zakariya University,Mechanical Engineering Department
来源
Applied Nanoscience | 2019年 / 9卷
关键词
Homogeneous–heterogeneous reactions; Viscous dissipation; Power law nanofluid; Entropy generation; Nonlinear radiation; Heat generation/absorption;
D O I
暂无
中图分类号
学科分类号
摘要
Here, cubic autocatalysis in radiative flow of power law fluid is addressed. Flow is examined by a stretched surface. Heat generation/absorption, nonlinear radiation and dissipation effect are utilized in modeling of energy equation. Through implementation of second thermodynamics law, the entropy rate is calculated. Further entropy generation is explored with respect to homogeneous and heterogeneous mass concentrations. Nonlinear system is tackled via NDSolve of MATHEMATICA. Impacts of pertinent variables associated with flow are physically discussed for the velocity, entropy generation, temperature and concentration fields. Clearly, entropy augmentation rate is controlled through Brinkman number. Main key points are presented.
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页码:1205 / 1214
页数:9
相关论文
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