Coupled Flow and Heat or Mass Transfer

About three years ago we invited contributions for a Fluids Special Issue on “Flow and Heat or Mass Transfer for the Chemical Process Industry [...]

errors in thermal simulations. Molecular dynamics (MD) was used as the research tool to investigate the role of microemulsion on the recovery of hydrocarbons under confinement (nanoscale pore size) in the contribution of Bui et al. [4]. The behavior of oil, water, and surfactant molecules in tight pores that are common in shale rocks was probed to determine the effect of viscous forces on oil mobilization. While Theodorakis et al. [2], Yamada et al. [3], and Bui et al. [4] utilized molecular level numerical techniques, such as MD and DPD, Vlachomitrou & Pelekasis [5] and Dobri & Papathanasiou [6] employed numerical techniques that are appropriate for larger scales. Vlachomitrou & Pelekasis [5] investigated the unsteady flow of a liquid metal inside a single pore in the presence of magnetic forces with a numerical approach. They identified the critical magnetic Bond number at which the liquid metal flow arrives at a steady state, and the critical number beyond which a Rayleigh-Taylor instability develops. They further investigated the dynamic response of different fluids, and the stabilizing effects of electrical conductivity and surface tension. A multi-scale numerical approach, based on hybrid numerical methods, for the multi-scale investigation for reactive flows in the space between fibers is presented in Dobri & Papathanasiou [6].
In bio-applications, Ray and Heys [7] reviewed recent developments in our understanding of the mechanism that the brain uses to remove waste chemicals, toxic proteins, and biological debris. While the brain lacks lymph vessels to assist in removal of interstitial waste, it is efficient in doing so. Dysfunction of the brain's waste-removal system is correlated to disease, like Alzheimer's disease, traumatic brain injury, diabetes, and stroke. The review was focused on transport processes, especially the role that diffusion and advective flow play in the brain waste-removal process. Hard tissue in bone was the theme of Felder et al. [8]. Tissue engineered bone grafts are used to alleviate immunological response in allogenic grafts. Bone-tissue-engineered constructs are a logical approach to combat the issues commonly encountered with these bone grafting techniques. Felder et al. [8] examined oxygen uptake rates of mesenchymal stem cells seeded on poly(L-lactic acid) scaffolds cultured in a flow perfusion bioreactor to expand on current predictive metrics for the determination of bone construct characteristics, such as cellularity and cell type.
Multiphase flow phenomena were the theme of the next group of papers. Barkai et al. [9] examined the gas holdup, the superficial gas velocity, and the bubble size for the gas-liquid flow in large scale experiments in a vacuum airlift column. Mohagheghian et al. [10] investigated two-phase flow phenomena in another type of bench-scale column; a sparged bubble column. The goal was to explore the enhancement of mixing in the column by tracking the distribution of a passive scalar within a sparged swarm of bubbles. Experiments were used to compare mixing in static and vertically vibrating columns, indicating that in lower vibration amplitudes, vibration decelerated the mixing due to bubble retardation. Dimensional analysis showed that the non-dimensional mixing time is correlated to the transient buoyancy number. In the same area of bubble columns, Rek [11] presented a numerical simulation of the rising bubble in a stagnant liquid column. Open source Computational Fluid Dynamics software available through OpenFOAM was used to demonstrate that dynamic numerical meshes are more appropriate for predicting bubble trajectories. Moving to particle-fluid flows, Zaw et al. [12] employed Eulerian-Lagrangian simulation techniques to study particle deposition on the wall of a ribbed channel. The interplay between shear forces acting on the particles and the geometric configuration of the ribs, expressed as pitch to height ratio for the ribs, was investigated to find that the surface topography is important for mitigating particulate fouling of surfaces. Bratsun & Vyatkin [13] analyzed theoretically selected problems in chemo-and thermo-vibrational convection. They derived exact non-steady, particular solutions to the Navier-Stokes equations. The novelty was in examining cases where the presence of a scalar field (temperature or concentration) made the hydrodynamic system spatially inhomogeneous.
In technological applications with industrial interest, Wei et al. [14] carried out a comparison between experiments and simulations for microjet cooling systems. The flow effects coupled with heat transfer are important for heat removal from electronic devices with liquid microjet impingement. Different numerical models for the turbulent flow environment were examined, and the Shear Stress Transport (SST) model and k-ω SST models showed the best ability to predict the thermal and flow field. In the same area of thermal fluids, Zhen et al. [15] presented the process of designing eco-friendly cellulose fibers from recycled paper waste. The waste is used to produce aerogels for thermal insulation, delivering a practical, engineering solution to enhance the heat insulation performance of water bottles, while not adding significant weight to the bottle. The effects of the static and dynamic conditions on heat flux were experimentally quantified. The paper that closes the volume deals with the evolution of organic fouling layers during operation of spiral wound desalination-membrane modules. Kostoglou & Karabelas [16] presented a new approach to model fouling layer thickness evolution considering two types of non-uniform fouling; topological (induced by trans-membrane pressure variation) and non-topological (induced by membrane permeability variation). They proposed a methodology for the dynamic simulation of fouling at the membrane sheet scale. The paper is instrumental in developing general models and reliable simulators for membrane-desalination processes.
Finally, we thank the contributors to this volume for sharing their research, we thank the reviewers for generously donating their time to select and improve the manuscripts, and we thank the MDPI publishing and editorial staff for working with us to make this volume a success.

Conflicts of Interest:
The authors declare no conflict of interest.