Kambiz Vafai Explained

Kambiz Vafai
Occupation:Mechanical engineer, inventor, academic and author
Education:BS., Mechanical Engineering
MS., Mechanical Engineering
PhD., Mechanical Engineering
Alma Mater:University of Minnesota, Minneapolis
University of California, Berkeley
Workplaces:University of California, Riverside

Kambiz Vafai is a mechanical engineer, inventor, academic and author. He has taken on the roles of Distinguished Professor of Mechanical Engineering and the Director of Bourns College of Engineering Online Master-of-Science in Engineering Program at the University of California, Riverside.[1]

Vafai is most known for his pioneering work in phenomenological description, modeling and analysis for single and multiphase transport through porous media.[2] He is a highly ranked scholar on Research.com[3] and ScholarGPS[4] and has been named in Elsevier/Stanford's list of World's Top 2% Scientists multiple times.[5] His publications include journal articles and books such as Porous Media: Applications in Biological Systems and Biotechnology and the Handbook of Porous Media. Additionally, he is the recipient of the 75th Anniversary Medal of American Society of Mechanical Engineers (ASME) Heat Transfer Division in 2013, the 2006 ASME Memorial Award,[6] and the 2011 International Society of Porous Media (InterPore) Honorary Lifetime Membership Award.[7]

Vafai is a Fellow of the American Society of Mechanical Engineers (ASME),[8] the American Association for Advancement of Science (AAAS),[9] the World Innovation Foundation, and Associate Fellow of American Institute of Aeronautics and Astronautics (AIAA).[10] He has taken on the roles of Editor-in-Chief of the Journal of Porous Media and Special Topics and Reviews in Porous Media,[11] Editor of International Journal of Heat and Mass Transfer[12] and has held positions on the Editorial Advisory Board of the International Journal of Heat and Mass Transfer,[13] International Communications in Heat and Mass Transfer,[14] Numerical Heat Transfer Journal,[15] International Journal of Numerical Methods for Heat and Fluid Flow,[16] Experimental Heat Transfer Journal,[17] and editorial board of the International Journal of Heat and Fluid Flow.[18]

Education

Vafai graduated with a Bachelor of Science in Mechanical Engineering from the University of Minnesota, Minneapolis in 1972, and went on to earn a Master of Science in 1977 and a PhD in 1980 from the University of California, Berkeley. Following this, he became a Postdoctoral Fellow in Mechanical Engineering at Harvard University from 1980 to 1981.[1]

Career

Vafai began his academic career as an assistant professor at The Ohio State University in 1981, later becoming associate professor in 1986 and Professor in 1991. In 2000, he joined the University of California, Riverside as a Presidential Chair Professor, and was appointed Distinguished Professor in the Department of Mechanical Engineering in 2014.[1]

Vafai took on the position of Director of Bourns College of Engineering Online Master-of-Science in Engineering Program at the University of California, Riverside in 2015.[19]

Vafai provided consulting services to various companies and laboratories and engaged in research collaborations with several countries. He also served as a Principal or Co-principal Investigator and led research projects funded by organizations such as the National Science Foundation (NSF)[20] Aircraft Brake Systems Corporation (ABSC), BFGoodrich, Bell Labs and the Department of Energy (DOE).[21]

Research

Vafai has contributed to the field of mechanical engineering by studying heat and mass transfer and fluid mechanics, particularly focusing on porous media transport, natural convection, condensation, multiphase transport, aircraft brake housing heat transfer, electronic cooling and biomedical applications.[2]

Works

Vafai has published works on the use of porous media and heat transfer, along with many book chapters and symposium volumes across different subjects. He edited the first, second and third editions of the Handbook of Porous Media, which compiled research on heat and mass transfer in porous media, covering topics like applied models, forced convection, and advancements in fundamental and applied research. In related research, his book, Porous Media: Applications in Biological Systems and Biotechnology, explored the applications of biomedical fields, showcasing collaborations among scientists and engineers to address challenges and potential advancements in biological systems.[22]

Porous media

Vafai's research on porous media focused on fluid flow, heat transfer and mass transfer. He pioneered the analysis of fundamental aspects in the study of fluid flow and heat transfer through a saturated porous medium.[23] He also lent to the understanding of non-equilibrium heat and mass transfer in porous media and the thermal interactions between solid and fluid phases. His works included a comprehensive review and simulation of multiphase transport through porous media, where key principles regarding local thermal equilibrium, dimensionality effects, and phase change effects were established.[24]

In a paper that introduced the Vafai number in Physics of Fluids, the Darcy–Bénard convection in a porous medium was examined incorporating phase-lag effects to derive an extended model to gain insights into the transition from local thermal non-equilibrium to equilibrium.[25]

Biomedical applications

Vafai has been engaged in biomedical applications, including the simulation of macromolecule transport through arteries, the study of biofilms, and the utilization of magnetic resonance imaging for early brain stroke detection.[26] He contributed to developing biosensors for biological detection and modeling tissues and organs and introduced a four-layer model for LDL transport in arterial walls, discussing its effectiveness in checking atherosclerosis initiation under different conditions.[27] [28] Additionally, he holds patents for research in initiating control over flow, heat, and mass transfer inside thin film fluidic cells to mitigate flow and thermal disturbances on sensor surfaces.[29] [30] [31] He devised a Rapid Microfluidic Thermal Cycler for Nucleic Acid amplification using a microfluidic heat exchanger and porous medium,[32] alongside a method and system for noninvasive treatment of neurodegenerative disorders through magnetothermal stimulation of neuron cells in the brain.[33]

Vafai led the establishment of a thorough simulation of biofilms incorporating the involved physical issues, investigating biofilm resistance to biocide treatment, considering physical attributes and providing correlations to predict microbial survival.[34] He examined how biofilm formation alters porosity and permeability in porous matrices using multispecies biofilm models and a modified Kozeny-Carman framework, focusing on Pseudomonas aeruginosa,[35] and developed a multidimensional, multispecies, heterogeneous biofilm model using balance equations, exploring the effects of changing biofilm surface geometries and porous media conditions.[36] In a paper with Sara Abdelsalam that received an honorable mention for the Bellman Prize-Elsevier (2020–2021),[37] he pointed out the influence of Womersley number and occlusion on flow characteristics in small blood arteries, providing insights into the Segré–Silberberg effect.[38]

Flat-shaped heat pipes and microchannels

Vafai studied heat pipes and microchannels to assess their heat transfer capabilities. His research group has found that flat-shaped heat pipes outperform cylindrical ones, especially in adapting to various geometries, ideal for asymmetrical heating/cooling in electronics and spacecraft where cylindrical pipes struggle with limited heat sources and sink use.[39] He analyzed multichannel heat pipes for the first time and established that flat-shaped heat pipes substantially improve heat dissipation, offer higher heat transfer capabilities, and provide multiple condensate return paths, thus overcoming prospect of a dry out condition crucial for managing high heat transfer applications.[40] Furthermore, he demonstrated that flat-shaped heat pipes create surfaces with minimal temperature variations, eliminating hot spots and ensuring uniform component temperatures, making them valuable for maintaining consistent operating conditions for electronic components. He also came up for the first time with the concept and detailed evaluation of disk-shaped heat pipes which have an even higher heat removal capability.[41] [42] [43]

In a joint study with Lu Zhu, Vafai proposed for the first time, the design and implementation of double and multi-layer microchannels, aiming to alleviate two primary drawbacks of these devices which are high-temperature gradients and the amount of required pumping power.[44] [45] [46]

Buoyancy induced flows

Vafai has conducted research on the interrelationship between Nusselt number oscillations, temperature distribution, fluid flow patterns, and vortex dynamics.[47] He has identified various cell structures within moderate and narrow gap annuli, including the existence of an odd number of cells for the first time,[48] [49] and distinct flow structures and heat transfer characteristics, including spiral vortex secondary flow and transverse vortices, which provide quantitative descriptions of three-dimensional convection patterns and unicellular flow development in buoyancy-induced convection.[50] Looking into buoyancy-driven convection in an open-ended cavity, he underscored the importance of irregular vortex behavior and the limitations of two-dimensional assumptions in transient flow and temperature fields.[51] [52]

Vafai provided a detailed and thorough review of free surface flows with and without the presence of a porous medium through modeling, experimentation, and finite difference and finite element simulations.[53] He collaborated with S.C. Chen to research various aspects of free surface transport phenomena in porous media, including the effects of surface tension,[54] comparative analysis of numerical methods,[55] experimental investigation of transport within hollow glass ampules,[56] and momentum and energy transport.[57] They proposed novel analytical and numerical methods, giving insights for applications such as glass processing and optical fiber production.[58]

Electronic cooling

Vafai and his students and his research scholars have conducted research on the 3D integrated circuit, introducing optimized thermal performance through integrated double-layer microchannels (DLMC) and multi-layer microchannels (MLMC).[59] He assessed key attributes of a 3D integrated chip structure, including critical features such as substrate size, heat sink, device layer, through silicon vias (TSVs), thermal interface material (TIM), and the arrangement of core processors and TSVs.[60] In addition, he conducted in-depth study of the variation of thermal conductivity, total heat dissipation, and power distribution within the device layers and core processors and showed the effects of varying features of the 3D Integrated Circuit (IC) structure on thermal hotspots, along with an optimization route for hotspot reduction.[61]

Vafai has been granted US patents related to the innovative 3D chip cooling,[62] [63] the configuration of a thin film microchannel to result in less coolant flow,[64] and enhanced thin film cooling through flexible complex seals in response to temperature or thermal load increases and electronic cooling.[65] Furthermore, his inventions encompass devices with multi-compartment fluidic cells,[66] flexible seals, and complex seals with closed cavities, aimed at controlling fluid flow rates,[67] enhancing insulation properties,[68] and regulating thermal conditions.[69]

Awards and honors

Bibliography

Selected books

Selected articles

Notes and References

  1. Web site: UCR Profiles - Search & Browse. profiles.ucr.edu.
  2. Web site: Kambiz Vafai. scholar.google.com.
  3. Web site: Kambiz Vafai: Mechanical and Aerospace Engineering H-index & Awards - Academic Profile | Research.com.
  4. Web site: Kambiz Vafai.
  5. Web site: Editorial Board Members from Applied Sciences Featured in Stanford’s List of the World’s Top 2% Scientists. www.mdpi.com.
  6. Web site: Heat Transfer Memorial Award.
  7. Web site: Honorary Lifetime Membership Awardees – InterPore.
  8. Web site: List of all ASME Fellows.
  9. Web site: Historic Fellows | American Association for the Advancement of Science (AAAS).
  10. Web site: AIAA Associate Fellows.
  11. Web site: Begell House - Special Topics & Reviews in Porous Media: An International Journal. www.begellhouse.com.
  12. Web site: International Journal of Heat and Mass Transfer - Editorial Board.
  13. Web site: Editorial board - International Journal of Heat and Mass Transfer | ScienceDirect.com by Elsevier.
  14. Web site: Editorial board - International Communications in Heat and Mass Transfer | ScienceDirect.com by Elsevier.
  15. Web site: Numerical Heat Transfer, Part A: Applications–Editorial board.
  16. Web site: International Journal of Numerical Methods for Heat & Fluid Flow | Emerald Publishing. www.emeraldgrouppublishing.com.
  17. Web site: Experimental Heat Transfer–Editorial board.
  18. Web site: Editorial board - International Journal of Heat and Fluid Flow | ScienceDirect.com by Elsevier.
  19. Web site: Message from the Director | Masters of Engineering Online. msol.ucr.edu.
  20. Web site: NSF Award Search: Award # 1153500 - Fourth International Conference on Porous Media and its Applications in Science, Engineering and Industry. www.nsf.gov.
  21. Web site: New Design Will Help Cool Microelectronics More Efficiently. New Design Will Help Cool Microelectronics More Efficiently.
  22. Web site: Porous media : applications in biological systems and biotechnology | WorldCat.org. search.worldcat.org.
  23. DOUBLE-DIFFUSIVE MIXED CONVECTION IN A LID-DRIVEN ENCLOSURE FILLED WITH A FLUID-SATURATED POROUS MEDIUM. K.. Khanafer. K.. Vafai. October 22, 2002. Numerical Heat Transfer, Part A: Applications. 42. 5. 465–486. CrossRef. 10.1080/10407780290059657.
  24. Web site: Transient applications of heat flux bifurcation in porous media.
  25. Web site: A study of Darcy–Bénard regular and chaotic convection using a new local thermal non-equilibrium formulation.
  26. Web site: Pressure based arterial failure predictor.
  27. Modeling of low-density lipoprotein (LDL) transport in the artery—effects of hypertension. Ning. Yang. Kambiz. Vafai. March 22, 2006. International Journal of Heat and Mass Transfer. 49. 5-6. 850–867. 10.1016/j.ijheatmasstransfer.2005.09.019.
  28. A coupling model for macromolecule transport in a stenosed arterial wall. L.. Ai. K.. Vafai. May 22, 2006. International Journal of Heat and Mass Transfer. 49. 9-10. 1568–1591. 10.1016/j.ijheatmasstransfer.2005.10.041.
  29. Web site: Innovative biosensors for chemical and biological assays.
  30. Web site: Thin film based microfluidic devices.
  31. Web site: Microcantilevers for biological and chemical assays and methods of making and using thereof.
  32. Web site: Rapid microfluidic thermal cycler for nucleic acid amplification.
  33. Web site: Method and system for thermal stimulation of targeted neural circuits for neurodegenerative disorders.
  34. Synthesis of biofilm resistance characteristics against antibiotics. Maryam. Shafahi. Kambiz. Vafai. July 22, 2010. International Journal of Heat and Mass Transfer. 53. 15-16. 2943–2950. 10.1016/j.ijheatmasstransfer.2010.04.004.
  35. Biofilm affected characteristics of porous structures. Maryam. Shafahi. Kambiz. Vafai. January 22, 2009. International Journal of Heat and Mass Transfer. 52. 3-4. 574–581. 10.1016/j.ijheatmasstransfer.2008.07.013.
  36. Analysis of the multidimensional effects in biofilms. Michael. Hauser. Kambiz. Vafai. January 22, 2013. International Journal of Heat and Mass Transfer. 56. 1-2. 340–349. 10.1016/j.ijheatmasstransfer.2012.09.034.
  37. Web site: 2 ASU mathematicians win Bellman Prize for malaria transmission article | ASU News. news.asu.edu.
  38. Particulate suspension effect on peristaltically induced unsteady pulsatile flow in a narrow artery: Blood flow model. Sara I.. Abdelsalam. Kambiz. Vafai. January 22, 2017. Mathematical Biosciences. 283. 91–105. 10.1016/j.mbs.2016.11.012.
  39. An experimental investigation of the thermal performance of an asymmetrical flat plate heat pipe. Y. Wang. K. Vafai. August 22, 2000. International Journal of Heat and Mass Transfer. 43. 15. 2657–2668. 10.1016/s0017-9310(99)00300-2.
  40. Analysis of flow and heat transfer characteristics of an asymmetrical flat plate heat pipe. K.. Vafai. W.. Wang. September 22, 1992. International Journal of Heat and Mass Transfer. 35. 9. 2087–2099. 10.1016/0017-9310(92)90054-v.
  41. Web site: Analysis of Asymmetric Disk-Shaped and Flat-Plate Heat Pipes.
  42. Optimization analysis of a disk-shaped heat pipe. N.. Zhu. K.. Vafai. January 22, 1996. Journal of Thermophysics and Heat Transfer. 10. 1. 179–182. CrossRef. 10.2514/3.770.
  43. Web site: High heat flux electronic cooling apparatus, devices and systems incorporating same.
  44. Analysis of two-layered micro-channel heat sink concept in electronic cooling. Kambiz. Vafai. Lu. Zhu. June 22, 1999. International Journal of Heat and Mass Transfer. 42. 12. 2287–2297. 10.1016/s0017-9310(98)00017-9.
  45. Web site: Two-layered micro channel heat sink, devices and systems incorporating same.
  46. Web site: Multi-layered micro-channel heat sink, devices and systems incorporating same.
  47. A numerical and experimental investigation of stability of natural convective flows within a horizontal annulus. Mark P.. Dyko. Kambiz. Vafai. A. Kader. Mojtabi. February 22, 1999. Journal of Fluid Mechanics. 381. 27–61. Cambridge University Press. 10.1017/S0022112098002948.
  48. Web site: On the presence of odd transverse convective rolls in narrow-gap horizontal annuli.
  49. Effects of gravity modulation on convection in a horizontal annulus. Mark P.. Dyko. Kambiz. Vafai. January 22, 2007. International Journal of Heat and Mass Transfer. 50. 1-2. 348–360. 10.1016/j.ijheatmasstransfer.2006.06.033.
  50. Web site: Erratum: “Buoyancy-Induced Convection in a Narrow Open-Ended Annulus” (ASME J. Heat Transfer, 1997, 119, pp. 483–494) .
  51. Thermal and fluid flow instabilities in buoyancy-driven flows in open-ended cavities. Kambiz. Vafai. Javad. Ettefagh. October 22, 1990. International Journal of Heat and Mass Transfer. 33. 10. 2329–2344. 10.1016/0017-9310(90)90130-m.
  52. Web site: Axial Transport Effects on Natural Convection Inside of an Open-Ended Annulus.
  53. Web site: Fundamental Issues and Recent Advancements in Analysis of Aircraft Brake Natural Convective Cooling.
  54. NON-DARCIAN SURFACE TENSION EFFECTS ON FREE SURFACE TRANSPORT IN POROUS MEDIA. S.C.. Chen. K.. Vafai. February 22, 1997. Numerical Heat Transfer, Part A: Applications. 31. 3. 235–254. CrossRef. 10.1080/10407789708914035.
  55. A Comparative Analysis of Finite Element and Finite Difference Methods for Free Surface Transport. S. C.. Chen. K.. Vafai. September 22, 1993. Numerical Heat Transfer, Part A: Applications. 24. 2. 229–247. CrossRef. 10.1080/10407789308902616.
  56. ANALYSIS OF FREE SURFACE TRANSPORT WITHIN A HOLLOW GLASS AMPULE. K.. Vafai. S. C.. Chen. July 22, 1992. Numerical Heat Transfer, Part A: Applications. 22. 1. 21–49. CrossRef. 10.1080/10407789208944757.
  57. ANALYSIS OF FREE SURFACE MOMENTUM AND ENERGY TRANSPORT IN POROUS MEDIA. S. C.. Chen. K.. Vafai. February 22, 1996. Numerical Heat Transfer, Part A: Applications. 29. 3. 281–296. CrossRef. 10.1080/10407789608913793.
  58. Web site: An Experimental Investigation of Free Surface Transport, Bifurcation, and Adhesion Phenomena as Related to a Hollow Glass Ampule and a Metallic Conductor.
  59. Web site: Optimization of the thermal performance of the 3d ics utilizing the integrated chip-size double-layer or multi-layer microchannels.
  60. Web site: Heat transfer enhancement for 3D chip thermal simulation and prediction.
  61. Thermophysical and Geometrical Effects on the Thermal Performance and Optimization of a Three-Dimensional Integrated Circuit. Fatemeh. Tavakkoli. Siavash. Ebrahimi. Shujuan. Wang. Kambiz. Vafai. May 3, 2016. Journal of Heat Transfer. 138. 8. 10.1115/1.4033138.
  62. Analysis of critical thermal issues in 3D integrated circuits. Fatemeh. Tavakkoli. Siavash. Ebrahimi. Shujuan. Wang. Kambiz. Vafai. June 22, 2016. International Journal of Heat and Mass Transfer. 97. 337–352. 10.1016/j.ijheatmasstransfer.2016.02.010.
  63. Web site: Thermal management of three-dimensional integrated circuits.
  64. Web site: Smart passive thermal devices and methods.
  65. Web site: Cooling enhancements in thin films using flexible complex seal due to temperature increase or thermal load increase.
  66. Web site: Minimizing flow disturbances in fluidic cells utilizing soft seals.
  67. Web site: Methods and devices comprising flexible seals, flexible microchannels, or both for modulating or controlling flow and heat.
  68. Web site: Enhancing insulating properties at higher temperature utilizing soft seals.
  69. Web site: Control of flow rate and thermal conditions using two-layered thin films separated by flexible seals and rotatable pivot.

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